Calculators Created by Anshika Arya

National Institute Of Technology (NIT), Hamirpur
1351
Formulas Created
728
Formulas Verified
198
Across Categories

List of Calculators by Anshika Arya

Following is a combined list of all the calculators that have been created and verified by Anshika Arya. Anshika Arya has created 1351 and verified 728 calculators across 198 different categories till date.
Created Value of load for Cantilever beam with a point load at the free end
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Created Value of load for Cantilever beam with a uniformly distributed load
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Created Value of load for fixed beam with a central point load
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Created Value of load for fixed beam with a uniformly distributed load
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Created Value of load for fixed beam with an eccentric point load
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Created Value of load for simply supported beam with a central point load
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Created Value of load for simply supported beam with a uniformly distributed load
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Created Value of load for simply supported beam with an eccentric point load
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Verified Area of lower end of bar
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Verified Area of upper end of bar
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Verified Axial Load For Bearings Mounted Singly or Paired in Tandem When (Fa/Fr)> 1.14
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Verified Axial Load For Bearings Pairs Arranged Back-To-Back or Face-To-Face When Fa/fr<=1.14
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Verified Axial Load For Bearings Pairs Arranged Back-To-Back or Face-To-Face When Fa/fr>1.14
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Verified Equivalent Dynamic Load For Bearings Mounted Singly or Paired in Tandem When (Fa/Fr)> 1.14
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Verified Equivalent Dynamic Load For Bearings Pairs Arranged Back-To-Back or Face-To-Face When Fa/fr<=1.14
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Verified Equivalent Dynamic Load For Bearings Pairs Arranged Back-To-Back or Face-To-Face When Fa/fr>1.14
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Verified Radial Load For Bearings Mounted Singly or Paired in Tandem When (Fa/Fr)> 1.14
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Verified Radial Load For Bearings Pairs Arranged Back-To-Back or Face-To-Face When Fa/fr<=1.14
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Verified Radial Load For Bearings Pairs Arranged Back-To-Back or Face-To-Face When Fa/fr>1.14
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Atom (3)
Created Angle Between Incident Ray and Scattering Planes in X-ray Diffraction
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Created Spacing Between the Atomic Lattice Planes in X-ray Diffraction
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Created Wavelength in X-ray Diffraction
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7 More Atom Calculators
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Verified Average energy delivered per spark
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Verified Resistance of charging circuit from avg. power per spark
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Verified Voltage of power supply from avg. power per spark
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Created Angle made by resultant force with horizontal
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Created Resultant centrifugal force
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Verified Input resistance
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Verified Input resistance of the amplifier
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Verified Input resistance when Re is given
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Verified Input Voltage in terms of the signal voltage
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Verified Output voltage gain in terms of transconductance
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Verified Overall voltage gain
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Verified Overall voltage gain in terms of resistance
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Verified Overall voltage gain in terms of the signal source
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Verified Overall voltage gain in terms of transconductance
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Verified Voltage gain from gate to drain
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Verified Voltage gain of the amplifier in terms of resistance
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Verified Voltage gain of the amplifier proper
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14 More Basic Configurations Calculators
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Verified Input resistance of the active-loaded CE amplifier
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Verified Output voltage gain of the active-loaded CE amplifier
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Verified Output voltage gain of the active-loaded CS Amplifier
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Verified Output voltage gain of the IC Amplifier
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Verified Output voltage gain of the IC Amplifier in terms of drain current
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Verified Output voltage gain of the IC Amplifier in terms of length of the channel
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5 More Basic gain cell in an IC amplifier Calculators
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Created Angle made by belt with vertical axis for cross belt drive
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Created Angle made by belt with vertical axis for open belt drive
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Created angle of contact for cross belt drive
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Created angle of contact for open belt drive
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Created Centrifugal Tension in belt
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Created Frictional force in V belt drive
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Created Initial tension in the belt
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Created Length of a cross belt drive
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Created Length of an open belt drive
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Created Maximum tension for transmission of maximum power by a belt
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Created Maximum tension of belt
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Created Normal reaction between the belt and the sides of the groove
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Created Power transmittted by a belt
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Created Relation between pitch and pitch circle diameter of a chain drive
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Created Tension in the tight side for transmission of maximum power by a belt
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Created Tension in the tight side of belt
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Created Tension in the tight side of rope drive
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Created Tension in the tight side of V-belt drive
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Created Tension on slack side when centrifugal tension is taken in account
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Created Tension on tight side when centrifugal tension is taken in account
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Created Tension on tight side when centrifugal tension is taken in account
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Created Torque exerted on the driven pulley
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Created Torque exerted on the driving pulley
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Created Total percentage slip in a belt
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Created Velocity for transmission of maximum power by a belt
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Created Velocity ratio
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Created Velocity ratio of belt drive
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Created Velocity ratio of belt in terms of creep of belt
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Created Velocity ratio of belt when there's total percentage slip is given
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Created Velocity ratio of compound belt drive
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Created Velocity ratio of compound belt drive
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Created Velocity ratio of simple belt drive when thickness considered
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Created Velocity ratio of simple belt drive when thickness not considered
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Verified Core Diameter When Shear Area is Given
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Verified Core Diameter When the Strength of the Bolt in Shear is Given
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Verified Height of Nut When Shear Area is Given
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Verified Height of Nut When Strength of Bolt in Shear is Given
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Verified Height of Standard Nut
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Verified Nominal Diameter of Bolt When Height of Standard Nut is Given
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Verified Shear Area of a bolted joint
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Verified Strength of the Bolt in Shear
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Verified Yield Strength in Shear When Strength of Bolt in Shear is Given
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Verified Yield Strength in Tension When the strength of the Bolt in Shear is Given
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7 More Bolted Joints Calculators
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Created Brake power of the engine for belt transmission dynamometer
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Created Brake power of the engine for prony brake dynamometer
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Created Brake power of the engine for prony brake dynamometer
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Created Brake power of the engine for prony brake dynamometer
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Created Brake power of the engine for rope brake dynamometer
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Created Brake power of the engine if diameter of rope is neglected for rope brake dynamometer
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Created Braking force on the drum for simple band brake
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Created Braking torque for a double block or shoe brake
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Created Braking torque for a pivoted block or shoe brake
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Created Braking torque for band and block brake(considering thickness of band)
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Created Braking torque for band and block brake(Neglecting thickness of band)
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Created Braking torque for shoe brake if line of action of tangential force passes above fulcrum(anti clock)
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Created Braking torque for shoe brake when force applied at the end of lever is known
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Created Braking torque for the shoe brake
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Created Braking torque of shoe brake if line of action of tangential force passes above fulcrum(clockwise)
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Created Braking torque of shoe brake if line of action of tangential force passes below fulcrum(anti clock)
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Created Braking torque of shoe brake if line of action of tangential force passes below fulcrum(clockwise)
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Created Braking torque on the drum for simple band brake(considering thickness of band)
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Created Braking torque on the drum for simple band brake(neglecting thickness of band)
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Created Constant for a particular shaft for torsion dynamometer
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Created Distance moved in one revolution by rope brake dynamometer
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Created Effective radius of the drum for the simple band brake
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Created Force on the lever of simple band brake for anticlockwise rotation of the drum
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Created Force on the lever of simple band brake for clockwise rotation of the drum
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Created Maximum braking force acting at the front wheels(when brakes are applied to front wheels only)
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Created Maximum value of total braking force acting at the rear wheels(brake applied to rear wheels only)
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Created Netload on the brake for rope brake dynamometer
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Created Normal force for shoe brake if line of action of tangential force passes above fulcrum(anti clock)
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Created Normal force for shoe brake if line of action of tangential force passes above fulcrum(clockwise)
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Created Normal force for shoe brake if line of action of tangential force passes below fulcrum(anticlock)
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Created Normal force for shoe brake if line of action of tangential force passes below fulcrum(clockwise)
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Created Normal force pressing the brake block on the wheel(shoe brake)
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Created Polar moment of inertia of the shaft for a hollow shaft for torsion dynamometer
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Created Polar moment of inertia of the shaft for a solid shaft for torsion dynamometer
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Created Polar moment of inertia of the shaft for torsion dynamometer
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Created Power transmitted for epicyclic-train dynamometer
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Created Power transmitted for the torsion dynamometer
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Created Power transmitted if tangential effort is known for epicyclic-train dynamometer
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Created Retardation of the vehicle if the vehicle moves down the plane(brake applied to all four wheels)
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Created Retardation of the vehicle if the vehicle moves down the plane(brake applied to front wheels only)
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Created Retardation of the vehicle if the vehicle moves down the plane(brake applied to rear wheels only)
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Created Retardation of the vehicle when vehicle moves on a level track(brake applied to all four wheels)
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Created Retardation of the vehicle when vehicle moves on a level track(brake applied to front wheels only)
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Created Retardation of the vehicle when vehicle moves on a level track(brake applied to rear wheels)
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Created Retardation of the vehicle(brake applied to all four wheels)
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Created Retardation of the vehicle(brake applied to front wheels only)
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Created Retardation of the vehicle(brake applied to rear wheels only)
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Created Tangential braking force acting at the contact surface of the block and the wheel for shoe brake
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Created Tangential braking force if normal force pressing the brake block on the wheel is known
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Created Tangential effort for epicyclic-train dynamometer
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Created Tension in the band between the first and second block for band and block brake
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Created Tension in the slack side of the belt for belt transmission dynamometer
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Created Tension in the tight side for band and block brake
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Created Tension in the tight side of the band for simple band brake if permissible tensile stress is given
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Created Tension in the tight side of the belt for belt transmission dynamometer
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Created Tension in tight side of the band for simple band brake
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Created torque acting on the shaft for torsion dynamometer
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Created Torque on the shaft of prony brake dynamometer
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Created Torque on the shaft of prony brake dynamometer if the radius of the pulley is known
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Created Torque transmitted for epicyclic-train dynamometer
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Created Torque transmitted if power is known for epicyclic-train dynamometer
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Created Torsion equation for torsion dynamometer
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Created Torsion equation for torsion dynamometer
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Created Total braking force (in newtons) acting at the rear wheels(brake applied to rear wheels only)
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Created Total braking force acting at the front wheels(when brakes are applied to front wheels only)
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Created Total normal reaction b/w ground and front wheels(when α=0)(brake applied to all four wheels)
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Created Total normal reaction b/w ground and front wheels(when α=0)(brake applied to front wheels only)
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Created Total normal reaction b/w ground and front wheels(when α=0)(brake applied to rear wheels only)
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Created Total normal reaction b/w ground and rear wheels(when α=0)(brake applied to all four wheels)
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Created Total normal reaction b/w ground and rear wheels(when α=0)(brake applied to front wheels only)
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Created Total normal reaction b/w ground and rear wheels(when α=0)(brake applied to rear wheels only)
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Created Total normal reaction between the ground and the front wheels(brake applied to all four wheels)
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Created Total normal reaction between the ground and the front wheels(brake applied to front wheels only)
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Created Total normal reaction between the ground and the front wheels(brake applied to rear wheels only)
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Created Total normal reaction between the ground and the rear wheels(brake applied to all four wheels)
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Created Total normal reaction between the ground and the rear wheels(brake applied to front wheels only)
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Created Total normal reaction between the ground and the rear wheels(brake applied to rear wheels only)
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Created Work done in one revolution for belt transmission dynamometer
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Created Work done in one revolution for prony brake dynamometer
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Created Work done per minute for prony brake dynamometer
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Created Work done per minute for rope brake dynamometer
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Created Work done per minute for the belt transmission dynamometer
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Created Work done per revolution for rope brake dynamometer
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Verified Current transfer ratio of IC Amplifier
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Verified Current transfer ratio of the mirror with base-current compensation
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Verified Finite input resistance of small-signal operation of the current Mirrors
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Verified Finite output resistance of IC Amplifier
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Verified Finite output resistance of the IC Amplifier in terms of output resistance
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Verified Finite output resistance of the IC Amplifier in terms of the output resistance
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Verified Input resistance in small-signal operation of current mirrors
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Verified Output current in terms of the reference current
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Verified Output current of a BJT mirror
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Verified Output current of IC Amplifier when Io = Ic
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Verified Output resistance of the BJT Mirror
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Verified Output resistance of the simple current BJT
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Verified Output resistance of the simple current BJT in terms of early voltage
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Verified Reference current in a current steering
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Verified Reference current of the BJT current mirror
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Verified Voltage gain of small-signal operation of current mirrors
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Verified Voltage gain of small-signal operation of current mirrors in terms of aspect ratio
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9 More Building Blocks of Integrated-Circuit Amplifiers Calculators
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Cams (50)
Created Acceleration of the follower after time t (Cycloidal motion)
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Created Acceleration of the follower for circular arc cam(contact on the circular flank)
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Created Acceleration of the follower for tangent cam with roller follower(contact with straight flanks)
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Created Acceleration of the follower of tangent cam with roller follower(contact with nose)
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Created Centripetal acceleration of the point P on circumference
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Created Centripetal acceleration of the point P on circumference when the follower moves with SHM
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Created Condition for contact of roller if straight flank merges into nose(tangent cam with roller follower)
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Created condition for maximum velocity of follower (Cycloidal motion)
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Created Condition for the maximum acceleration of follower (Cycloidal motion)
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Created Displacement of roller for tangent cam with roller follower(contact with straight flanks)
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Created Displacement of the follower after time t (Cycloidal motion)
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Created Displacement of the follower for circular arc cam(contact on the circular flank)
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Created Displacement of the roller of tangent cam with roller follower(contact with nose)
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Created Distance b/w roller center and nose center of tangent cam with roller follower(contact with nose)
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Created Max acceleration of follower during outstroke if outstroke velocity is known(uniform acceleration)
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Created Max acceleration of follower during outstroke if stroke of follower is known(uniform acceleration)
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Created Max acceleration of follower during return stroke if follower speed is known(uniform acceleration)
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Created Max acceleration of follower during return stroke if follower stroke is known(uniform acceleration)
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Created Max acceleration of follower for tangent cam with roller follower(contact with straight flanks)
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Created Max velocity of the follower for tangent cam with roller follower(contact with straight flanks)
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Created Maximum acceleration of the follower during outstroke (Cycloidal motion)
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Created Maximum acceleration of the follower during outstroke(uniform acceleration)
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Created Maximum acceleration of the follower during return stroke (Cycloidal motion)
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Created Maximum acceleration of the follower during return stroke(uniform acceleration)
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Created Maximum acceleration of the follower for circular arc cam(contact on the circular flank)
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Created Maximum acceleration of the follower on the outstroke when the follower moves with SHM
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Created Maximum acceleration of the follower on the return stroke when the follower moves with SHM
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Created Maximum velocity of the follower during outstroke (Cycloidal motion)
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Created Maximum velocity of the follower during outstroke(uniform acceleration)
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Created Maximum velocity of the follower during outstroke(uniform acceleration)
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Created Maximum velocity of the follower during return stroke (Cycloidal motion)
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Created Maximum velocity of the follower during return stroke(uniform acceleration)
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Created Maximum velocity of the follower during return stroke(uniform acceleration)
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Created Maximum velocity of the follower for circular arc cam(contact on the circular flank)
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Created Maximum velocity of the follower on the outstroke when the follower moves with SHM
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Created Maximum velocity of the follower on the outstroke when the follower moves with SHM
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Created Maximum velocity of the follower on the return stroke when the follower moves with SHM
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Created Mean velocity of the follower during outstroke(uniform acceleration)
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Created Mean velocity of the follower during the return stroke(uniform acceleration)
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Created Min acceleration of follower for tangent cam with roller follower(contact with straight flanks)
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Created Minimum acceleration of the follower for circular arc cam(contact on the circular flank)
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Created Peripheral speed of projection of point P'(which is projection of point P on dia)for SHM of follower
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Created Peripheral speed of projection of point P′(which is projection of point P on dia)for SHM of follower
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Created Time required for a follower during outstroke(uniform acceleration)
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Created Time required for the follower during return stroke(uniform acceleration)
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Created Time required for the out stroke of the follower when the follower moves with SHM
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Created Velocity of the follower after time t (Cycloidal motion)
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Created Velocity of the follower for circular arc cam(contact on the circular flank)
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Created Velocity of the follower for tangent cam with roller follower(contact with straight flanks)
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Created Velocity of the follower of tangent cam with roller follower(contact with nose)
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Verified Least diameter of impeller
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Verified Manometric head given outlet impeller diameter, impeller speed and speed ratio
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Verified Outlet diameter of impeller in terms of speed ratio, manometric head and impeller speed
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Verified Static head
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Verified Work done per second if the flow at inlet is not radial
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Verified Work done per second per unit weight of liquid if the flow at inlet is not radial
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42 More Centrifugal pumps Calculators
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Created Change in diameter of thin spherical shell
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Created Diameter of spherical shell in terms of change in diameter of thin spherical shells
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Created Diameter of thin spherical shell in terms of strain in any one direction
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Created Hoop stress induced in thin spherical shell in terms of strain in any one direction
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Created Hoop stress induced in thin spherical shell in terms of strain in any one direction
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Created Internal fluid pressure in terms of change in diameter of thin spherical shells
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Created Internal fluid pressure in thin spherical shell in terms of strain in any one direction
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Created Modulus of elasticity for thin spherical shell in terms of strain and internal fluid pressure
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Created Modulus of elasticity in terms of change in diameter of thin spherical shells
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Created Modulus of elasticity of thin spherical shell in terms of strain in any one direction
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Created Poisson's ratio for thin spherical shell in terms of strain and internal fluid pressure
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Created Poisson's ratio for thin spherical shell in terms of strain in any one direction
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Created Poisson's ratio in terms of change in diameter of thin spherical shells
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Created Strain in any one direction of thin spherical shell
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Created Strain in thin spherical shell in terms of internal fluid pressure
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Created Thickness of spherical shell in terms of change in diameter of thin spherical shells
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Created Thickness of thin spherical shell in terms of strain in any one direction
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Verified Capacitance of circuit from charging time
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Verified Charging time
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Verified Charging time from minimum resistance
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Verified Inductance of circuit from charging time
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Verified Minimum resistance from charging time
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Verified Charging voltage for maximum power of spark
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Verified Power supply for maximum power of spark
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6 More Charging voltage Calculators
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Created Diameter of circular section if distance of the outermost layer from neutral layer is known
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Created Diameter of circular section if moment of inertia about neutral axis is given
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Created Diameter of circular section if section modulus is given
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Created Distance of the outermost layer from neutral layer in circular sections
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Created Moment of inertia about neutral axis for circular section
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Created Section modulus for circular section
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Created Average shear force for circular section
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Created Average shear stress for circular section
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Created Average Shear stress for circular section in terms of Maximum shear stress
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Created Maximum shear force if only maximum shear stress and radius of circular section are known
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Created Maximum shear stress for circular section
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Created Maximum Shear stress for circular section in terms of average shear stress
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Created Maximum shear stress if only shear force and radius of circular section is known
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Created Moment of inertia of circular section if shear stress is known
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Created Moment of inertia of the circular section
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Created Moment of inertia of the circular section if maximum shear stress is known
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Created Moment of the shaded area (area above considered layer) about neutral axis
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Created Radius of circular section if width of beam at considered level is known
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Created Radius of circular section in terms of average shear stress and shear force
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Created Radius of circular section in terms of maximum shear stress and shear force
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Created Shear force distribution for circular section
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Created Shear force if maximum shear stress is known
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Created Shear stress distribution for circular section
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Created Width of the beam at the considered level if radius of circular section is known
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Created Width of the beam at the considered level if shear stress is known(circular section)
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Created Base Length of parabolic section that can be cut from a cone for maximum area of parabolic section
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Created Distance from the minor arc of cone of parabolic section that can be cut from a cone for maximum area of parabolic section
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Created Height of Cone circumscribing a sphere such that volume of cone is minimum
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Created Height of parabolic section that can be cut from a cone for maximum area of parabolic section
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Created Maximum Area of Parabolic Segment that can be Cut from a Cone
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Created Radius of Cone circumscribing a sphere such that volume of cone is minimum
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Created Volume of Cone circumscribing a sphere such that volume of cone is minimum
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Created Surface Area of Cylinder circumscribing a sphere when radius of sphere is known
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Created Volume of cylinder circumscribing a sphere when radius of sphere is known
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Created Diameter of circumscribing sphere when diameter and height of circumscribed cylinder is known
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Created Surface Area of Sphere circumscribing a cylinder
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Created The Radius (R) of a sphere that circumscribes a cube with side length S
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Created Volume of a circumscribed sphere in terms of cube Side length
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Created Volume of Sphere circumscribing a cylinder
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Verified Output voltage in terms of the transconductance
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14 More Common-Gate (CG) and the Common-Base (CB) Amplifiers Calculators
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Verified Input resistance of the common-source amplifier
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Verified Output resistance of the common-source amplifier
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1 More Common-source amplifier Calculators
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Verified Axial Force Transmitted by the Inner Spring
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10 More Concentric Springs Calculators
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Verified Average sherwood number of a flat plate combined laminar and turbulent flow
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Verified Average Sherwood number of a internal turbulent flow
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Verified Average Sherwood number of flat plate turbulent flow
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Verified Convective mass transfer coefficient given drag coefficient
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Verified Convective mass transfer coefficient of a flat plate laminar flow given Reynolds number
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Verified Convective mass transfer through Liquid gas interface
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Verified Density of the material given convective heat and mass transfer coefficient
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Verified Drag coefficient of flat plate in combined laminar turbulent flow
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Verified Free stream velocity of the flat plate having combined flow given darg coefficient
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Verified Free stream velocity of the flat plate having combined laminar-turbulent flow
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Verified Free stream velocity of the flat plate in internal turbulent flow
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Verified Free stream velocity of the flat plate laminar flow given drag coefficient
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Verified Free stream velocity of the flat plate laminar flow given friction factor
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Verified Heat transfer coefficient given mass transfer and Lewis number
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Verified Local Sherwood number
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Verified Mass transfer boundary layer thickness of a flat plate in laminar flow
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Verified Mass transfer Stanton number
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Verified Partial pressure of component A in mixture 1
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Verified Specific heat given convective heat and mass transfer
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14 More Convective mass transfer Calculators
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Verified Cooling load from lighting
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Verified Latent Heat Gain from people
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Verified Sensible Heat Gain from people
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17 More Cooling Loads Calculators
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Verified Maximum spark current to be maintained indefinitely
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Verified Power supply for maintaining max. sparking current
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Verified Resistance of circuit using arcing criteria
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Verified Spark discharge voltage at maximum spark current
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Created Additional deflection of centre of gravity of the rotor in terms of natural circular frequency
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Created Additional deflection of centre of gravity of the rotor in terms of whirling speed
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Created Additional deflection of centre of gravity of the rotor when the shaft starts rotating
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Created Centrifugal force acting radially outwards, causing the shaft to deflect
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Created Critical or Whirling speed in r.p.s
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Created Critical or Whirling speed in terms of static deflection
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Created Critical or whirling speed in terms of stiffness of shaft
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Created Force resisting the additional deflection of centre of gravity of the rotor
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Created Mass of the rotor in terms of centrifugal force
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Created Natural circular frequency of the shaft
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Created Static deflection of the shaft
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Created Stiffness of the shaft for equilibrium position
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Cube (1)
Created Lateral surface area of cube
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1 More Cube Calculators
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Cuboid (2)
Created Lateral Surface Area of Cuboid
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Created Surface Area of Cuboid
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Verified Emitter resistance of the Widlar Current Source
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Verified Output current of Wilson current mirror
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Verified Output resistance of the Cascode MOS Mirrors
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Verified Output resistance of the Widlar Current Source
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Verified Output resistance of the Wilson current mirror
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3 More Current-Mirror Circuits with Improved Performance Calculators
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Verified Signal current in the collector
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Verified Signal current in the collector in terms of input signal
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Verified Total power dissipated in BJT
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Verified Total power supplied in BJT
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Verified Total power supplied in MOSFET
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17 More Dc Machine Calculators
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Verified Input bias current of the differential amplifier
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Verified Input bias current of the differential amplifier in terms of common-emitter current gain
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Verified Input offset current of the differential amplifier
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Verified Input offset current of the differential amplifier in terms of common-emitter current gain
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Verified Input Offset Voltage of the MOS Differential Amplifier
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Verified Input Offset Voltage of the MOS Differential Amplifier in terms of threshold voltage
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Verified Input Offset Voltage of the MOS Differential Amplifier in terms of transconductance
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Verified Input Offset Voltage of the MOS Differential Amplifier when aspect ratio mismatches
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Verified Total Input Offset Voltage of the MOS Differential Amplifier
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3 More DC Offset Calculators
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Verified Endurance limit
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Verified Endurance limit for axial loading
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Verified Endurance limit in terms of endurance limit for axial loading
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Verified Endurance limit of rotating-beam specimen
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Verified Fatigue stress concentration factor in terms of Modifying factor to account for stress concentration
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Verified Modifying factor to account for stress concentration
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Verified Modifying factor to account for stress concentration in terms of Fatigue stress concentration factor
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Verified Reliability Factor
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Verified Size Factor
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29 More Design against fluctuating load Calculators
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Verified Moment of inertia of rectangular cross-section along centroidal axis parallel to breadth
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Verified Moment of inertia of rectangular cross-section along centroidal axis parallel to length
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Verified Polar moment of inertia from shear stress and torsional moment
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Verified Surface finish factor
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Verified Torsional moment from shear stress
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19 More Design Against Static Load Calculators
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Verified Moment of inertia of flywheel
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19 More Design of flywheel Calculators
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Verified Addendum circle diameter of large-size gear
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Verified Dedendum circle diameter of large-size gear
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Verified Diameter of holes in web of medium size diameter
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Verified Module in terms of tolerance factor
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Verified Outer diameter of hub of large-size gear
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Verified Pitch circle diameter of holes of medium size gear
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Verified Tolerance factor
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53 More Design of gear Calculators
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Verified Bending Moment When Bending Stress in Hollow Shaft is Given
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Verified Bending Stress in Hollow Shaft
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Verified Outer Diameter of Hollow Shaft When Bending Stress of Hollow Shaft is Given
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Verified Torsional Shear Stress When a Shaft is Subjected to Pure Torsional Moment
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19 More Design of Hollow Shaft Calculators
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Verified Bearing Load
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Verified Bore Diameter of Bearing
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Verified Coefficient of Friction
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Verified Dynamic Load Capacity (N)
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Verified Dynamic Load Capacity (N) for Ball Bearings
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Verified Dynamic Load Capacity for Roller Bearing
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Verified Equivalent Dynamic Load
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Verified Equivalent Dynamic Load for Ball Bearing
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Verified Equivalent Dynamic Load for Roller Bearing
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Verified Frictional Moment
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Verified Median Life
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Verified Nominal Life (millions of kilometres)
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Verified Number of Bearings in Terms of Bearing
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Verified Rated bearing life (hours)
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Verified Rated bearing life (in million revolutions)
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Verified Rated Bearing Life (in million revolutions)
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Verified Rated Bearing Life (in million revolutions) for Ball Bearings
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Verified Rated bearing life (in million revolutions) for roller bearing
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Verified Rated Bearing Life (in million revolutions) in Terms of Nominal Life
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Verified Rated Bearing Life in terms of Median Life
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Verified Reliability (in fraction)
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Verified Reliability of Each Bearing
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Verified Reliability of the Complete System
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Verified Speed of Rotation (r.p.m.)
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Verified Wheel Diameter
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11 More Design of Rolling Contact Bearing Calculators
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Verified Absolute Viscosity Of Oil in Terms Of Tangential Force
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Verified Area of the Moving Plate of A Sliding Contact Bearing in Terms of Absolute Viscosity
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Verified Film Thickness in Terms of Absolute Viscosity and Tangential Force
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Verified Tangential Force in Sliding Contact Bearing
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Verified Velocity of the Moving Plate in Terms of Absolute Viscosity
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6 More Design of Sliding Contact Bearing Calculators
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Verified Tensile force acting on the bolt
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56 More Design of threaded fasteners Calculators
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Created Angle of twist if shear strain at outer surface of shaft is known
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Created Angle of twist if shear stress induced at radius 'r' from center of shaft is given
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Created Angle of twist if shear stress induced at surface of shaft is known
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Created Length of shaft if shear strain at outer surface of shaft is known
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Created Length of shaft if shear stress induced at radius 'r' from center of shaft is given
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Created Length of shaft if shear stress induced at surface of shaft is known
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Created Modulus of rigidity of material of shaft if shear stress induced at surface of shaft is known
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Created Modulus of rigidity of shaft if shear stress induced at radius 'r' from center of shaft is given
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Created Radius of shaft if shear strain at outer surface of shaft is known
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Created Radius of shaft if shear stress induced at radius 'r' from center of shaft is given
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Created Radius of shaft if shear stress-induced at surface of shaft is known
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Created Shear strain at the outer surface of circular shaft
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Created Shear stress at surface of shaft if shear stress induced at radius 'r' from center of shaft is given
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Created Shear stress induced at radius 'r' from center of shaft if modulus of rigidity is known
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Created Shear stress induced at radius 'r' from center of the shaft
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Created Shear stress induced at the surface of the shaft
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Created Value of radius 'r' if shear stress induced at radius 'r' from center of shaft is given
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Created Length of leading diagonal of cuboid
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Created The maximum face diagonal length for cubes with a side length S
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3 More Diagonal Formula Calculators
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Verified Buoyant force given grashof number
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Verified Graetz number
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Verified Grashof number
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Verified Heat diffusivity given Lewis number
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Verified Heat transfer by conduction given Graetz number
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Verified Heat transfer by convection given graetz number
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Verified Inertia force given grashof number
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Verified Lewis number
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Verified Mass diffusivity given Lewis number
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Verified Molecular diffusivity of heat given Prandtl number
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Verified Molecular diffusivity of mass given Schmidt number
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Verified Molecular diffusivity of momentum given Prandtl number
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Verified Molecular diffusivity of momentum given Schmidt number
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Verified Prandtl number
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Verified Schmidt number
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Verified Viscous force given grashofs number
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28 More Dimensionless groups Calculators
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Verified Modulus of rigidity in terms of young's modulus and poisson's ratio
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Verified Poisson's ratio if tensile strain due to compressive stress in diagonal BD is known
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Verified Poisson's ratio in terms of modulus of rigidity and Young's modulus
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Verified Shear strain in diagonal in terms of tensile strain for square block
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Verified Tensile strain in diagonal in terms of shear strain for square block.
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Verified Tensile strain in the diagonal BD of square block ABCD due to compressive stress
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Verified Tensile strain in the diagonal BD of square block ABCD due to tensile stress
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Verified Total compressive strain in the diagonal AC of square block ABCD
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Verified Total tensile strain in diagonal BD of square block ABCD in terms of modulus of rigidity
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Verified Total tensile strain in the diagonal BD of square block ABCD
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Verified Young's modulus in terms of modulus of rigidity and poisson's ratio
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Verified Discharge current
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Verified Discharge voltage
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Verified Resistance of discharging circuit
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Verified Capacitance of circuit
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Verified Discharging voltage
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Verified Resistance of discharging circuit
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Verified Time elapsed
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Verified Voltage of charging circuit
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Verified Distortion energy theorem
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Verified Strain Energy corresponding to distortion with no change in volume
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Verified Strain Energy corresponding to distortion with no change in volume in terms of yield strength
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Verified Yield strength from distortion energy theorem
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Verified Yield strength from distortion energy theorem considering factor of safety
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Verified Yield strength from distortion energy theorem considering factor of safety for biaxial stresses
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6 More Distortion Energy Theory Calculators
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Created Dunkerley’s empirical formula, for the natural frequency of the whole system
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Created Natural frequency of transverse vibration due to point load
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Created Natural frequency of transverse vibration due to uniformly distributed load
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Verified Imaginary Force at Center of Gravity When Primary Shear Force is Given
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Verified Number of Bolts When Primary Shear Force is Given
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Verified Primary Shear Force of Eccentrically Loaded Bolted Connection
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Created Angular velocity of free end if kinetic energy of constraint is known
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Created Angular velocity of the element
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Created Kinetic energy possessed by the element
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Created Mass moment of inertia of the element
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Created Natural frequency of torsional vibration due to effect of inertia of constraint
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Created Torsional stiffness of shaft due to effect of constraint on torsional vibrations
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Created Total kinetic energy of the constraint
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Created Total mass moment of inertia of constraint if kinetic energy of constraint is known
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Created Change in circumference of vessel due to pressure in terms of circumferential strain
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Created Change in diameter in thin cylindrical strain in terms of volumetric strain
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Created Change in diameter of cylindrical shell in terms of change in volume of cylindrical shell
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Created Change in diameter of thin cylindrical vessel in terms of circumferential strain
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Created Change in diameter of vessel in terms of internal fluid pressure
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Created Change in length in thin cylindrical strain in terms of volumetric strain
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Created Change in length of cylindrical shell in terms of change in volume of cylindrical shell
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Created Change in length of thin cylindrical shell in terms of internal fluid pressure
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Created Change in length of thin cylindrical vessel in terms of longitudinal strain
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Created Change in volume in terms of circumferential strain and longitudinal strain
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Created Change in volume of cylindrical shell in terms of volumetric strain
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Created Change in volume of thin cylindrical shell
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Created Circumferential strain in terms of circumference
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Created Circumferential strain in terms of hoop stress
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Created Circumferential strain in terms of internal fluid pressure
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Created Circumferential strain in terms of volume of thin cylindrical shell
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Created Circumferential strain in terms of volumetric strain for thin cylindrical shell
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Created Circumferential strain of vessel in terms of diameter
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Created Diameter of cylindrical shell in terms of change in length of cylindrical shell
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Created Diameter of thin cylindrical shell in terms of volumetric strain
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Created Diameter of thin cylindrical strain in terms of volumetric strain
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Created Hoop stress in terms of circumferential strain
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Created Hoop stress in thin cylindrical vessel in terms of Longitudinal strain
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Created Internal diameter of thin cylindrical vessel in terms of circumferential strain
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Created Internal diameter of thin cylindrical vessel in terms of longitudinal strain
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Created Internal fluid pressure in shell in terms of volumetric strain
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Created Internal fluid pressure in terms of change in length of cylindrical shell
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Created Internal fluid pressure in terms of circumferential strain
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Created Internal fluid pressure in thin cylindrical vessel in terms of longitudinal strain
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Created Internal fluid pressure in vessel in terms of change in diameter
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Created Length of cylindrical shell in terms of change in length of cylindrical shell
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Created Length of cylindrical shell in terms of change in volume of cylindrical shell
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Created Length of thin cylindrical strain in terms of volumetric strain
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Created Longitudinal strain for vessel in terms of change in length
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Created Longitudinal strain in terms of hoop and longitudinal stress
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Created Longitudinal strain in terms of volume of thin cylindrical shell
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Created Longitudinal strain in terms of volumetric strain for thin cylindrical shell
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Created Longitudinal strain in thin cylindrical vessel in terms of internal fluid pressure
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Created Longitudinal stress in terms of circumferential strain
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Created Longitudinal stress in thin cylindrical vessel in terms of Longitudinal strain
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Created Modulus of elasticity in terms of circumferential strain
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Created Modulus of elasticity of shell material in terms of change in length of cylindrical shell
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Created Modulus of elasticity of thin cylindrical shell in terms of volumetric strain
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Created Modulus of elasticity of vessel in terms of circumferential strain
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Created Modulus of elasticity of vessel material in terms of change in diameter
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Created Modulus of elasticity of vessel material in terms of longitudinal strain
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Created Modulus of elasticity of vessel material in terms of Longitudinal strain
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Created Original circumference of thin cylindrical vessel in terms of circumferential strain
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Created Original diameter of thin cylindrical vessel in terms of circumferential strain
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Created Original diameter of vessel in terms of change in diameter
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Created Original length of vessel in terms of longitudinal strain
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Created Original volume of cylindrical shell in terms of volumetric strain
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Created Poisson's ratio for thin cylindrical vessel in terms of change in diameter
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Created Poisson's ratio in terms of change in length of cylindrical shell
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Created Poisson's ratio in terms of circumferential strain
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Created Poisson's ratio in terms of circumferential strain
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Created Poisson's ratio in terms of Longitudinal strain
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Created Poisson's ratio in terms of longitudinal strain and internal fluid pressure in vessel
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Created Poisson's ratio in terms of volumetric strain of thin cylindrical shell
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Created Thickness of cylindrical shell in terms of change in length of cylindrical shell
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Created Thickness of thin cylindrical shell in terms of volumetric strain
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Created Thickness of thin cylindrical vessel in terms of circumferential strain
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Created Thickness of thin cylindrical vessel in terms of longitudinal strain
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Created Thickness of vessel in terms of change in diameter
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Created Volume of thin cylindrical shell in terms of circumferential and longitudinal strain
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Created Volumetric strain in terms of circumferential strain and longitudinal strain
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Created Volumetric strain in terms of internal fluid pressure
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Created Volumetric strain of thin cylindrical shell
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Created Volumetric strain of thin cylindrical shell
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Verified Effectiveness of a double pipe counter flow heat exchanger given (C=1)
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Verified Effectiveness when mccc is the minimum value
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Verified Effectiveness when mhch is the minimum value
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9 More Effectiveness Calculators
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Created Efficiency of circumferential joint in terms of longitudinal stress
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Created Efficiency of longitudinal joint in terms of hoop stress
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Created Hoop stress if efficiency of longitudinal joint is known
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Created Internal diameter of vessel in terms of hoop stress and efficiency of longitudinal joint
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Created Internal diameter of vessel in terms of longitudinal stress and efficiency of circumferential joint
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Created Internal fluid pressure in terms of longitudinal stress & efficiency of circumferential joint
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Created Internal fluid pressure in vessel in terms of hoop stress and efficiency of longitudinal joint
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Created Longitudinal stress if efficiency of circumferential joint is known
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Created Thickness of vessel in terms of hoop stress and efficiency of longitudinal joint
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Created Thickness of vessel in terms of longitudinal stress and efficiency of circumferential joint
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Verified Efficiency of the machine if mechanical advantage and velocity ratio is known
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7 More efficiency of machines Calculators
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Verified Accelaration( K and x given)
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Verified Acceleration in SHM (when angular frequency is given)
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Verified Angular frequency ( when constant K and mass is given)
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Verified Angular frequency of shm
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Verified Angular frequency(when velocity and distance A given)
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Verified Area of the body ( when stress is given )
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Verified Change in length when longitudinal stress is given
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Verified Change in volume of the body when volume strain is given.
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Verified Constant A (when position is given)
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Verified Constant K ( when restoring force is given )
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Verified constant k (when angular frequency is given)
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Verified Displacement of upper surface
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Verified Distance from start(when restoring force and k is given)
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Verified Distance traveled ( when velocity is given )
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Verified Distance traveled by a particle in shm when velocity becomes zero
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Verified Distance travelled in shm ( when angular frequency is given )
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Verified Frequency of SHM
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Verified Longitudinal strain
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Verified Mass of body( when distance traveled and k is given)
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Verified Mass of particle (relating angular frequency w)
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Verified Normal stress or longitudinal stress
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Verified Original length when longitudinal stress is given
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Verified Original volume of body when strain is given
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Verified Perpendicular distance between the two surfaces
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Verified Phase in SHM
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Verified Ratio of shear
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Verified Restoring force in shm
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Verified restoring force( when stress is given)
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Verified Square of different distance traveled in shm
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Verified Time Period of SHM
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Verified Total distance traveled( when velocity and angular frequency is given) square of distances traveled
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Verified Velocity of particle in shm
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Verified Volume strain
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Verified Young's modulus of elasticity
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1 More Elasticity & Simple Harmonic Motion(SHM) Calculators
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Verified Total Flux in Self Inductance
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25 More Electromagnetic Induction Calculators
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Verified Elongation of the element
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Verified Length of bar if total elongation and weight per unit volume of bar is given
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Verified Length of the bar if total elongation of bar is known
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Verified Modulus of elasticity if total elongation of bar is known
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Verified Strain in the element
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Verified Stress on the element
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Verified Total elongation of the bar
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Verified Total elongation of the bar if weight per unit volume of bar is known
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Verified Weight of the bar for a length x
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Verified Weight of the bar if total elongation of bar is known
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Verified Depth of crater
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Verified Energy per spark from depth of crater
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3 More Energy delivered per spark Calculators
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Created Potential Energy
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Created Acceleration of body in terms of stiffness of the constraint
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Created Angular velocity of free longitudinal vibrations
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Created Displacement of the body in terms of stiffness of the constraint
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Created Gravitational pull balanced by the spring force
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Created Length of the constraint
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Created Load attached to the free end of constraint
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Created Natural frequency of free longitudinal vibrations if static deflection is known
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Created Natural frequency of free longitudinal vibrations if static deflection is known
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Created Natural frequency of free longitudinal vibrations if stiffness of constraint is known
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Created Natural frequency of free longitudinal vibrations if the time period is known
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Created Restoring force
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Created Restoring force if weight of the body in newtons is known
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Created Static deflection
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Created Static deflection if natural frequency is known
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Created Time period of free longitudinal vibrations
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1 More Equilibrium Method Calculators
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Created Inner diameter of shaft if total strain energy in the hollow shaft is given
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Created Length of shaft in terms of shear strain energy in ring of radius 'r'
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Created Length of shaft in terms of total strain energy stored in the shaft
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Created Modulus of rigidity in terms of shear strain energy
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Created Modulus of rigidity of shaft if total strain energy in the hollow shaft is given
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Created Modulus of rigidity of shaft in terms of shear strain energy in ring of radius 'r'
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Created Modulus of rigidity of shaft in terms of total strain energy in shaft due to torsion
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Created Modulus of rigidity of shaft in terms of total strain energy stored in the shaft
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Created Polar moment of inertia of shaft in terms of total strain energy stored in the shaft
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Created Radius of shaft in terms of shear strain energy in ring of radius 'r'
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Created Radius of shaft in terms of shear stress at radius 'r' from center
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Created Radius of shaft in terms of total strain energy stored in the shaft
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Created Shear strain energy
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Created Shear strain energy in ring of radius 'r'
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Created Shear stress at surface of shaft in terms of shear strain energy in ring of radius 'r'
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Created Shear stress at surface of shaft in terms of shear stress at radius 'r' from center
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Created Shear stress at surface of shaft in terms of total strain energy in shaft due to torsion
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Created Shear stress at surface of shaft in terms of total strain energy stored in the shaft
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Created Shear stress due to torsion at radius 'r' from center
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Created Shear stress in terms of shear strain energy
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Created Shear stress on the surface of shaft if total strain energy in the hollow shaft is given
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Created Total strain energy in shaft due to torsion
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Created Total strain energy in the hollow shaft due to torsion
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Created Total strain energy stored in the shaft
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Created Value of radius 'r' in terms of shear strain energy in ring of radius 'r'
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Created Value of radius 'r' in terms of shear stress at radius 'r' from center
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Created Volume in terms of shear strain energy
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Created Volume of shaft if total strain energy in the hollow shaft is given
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Created Volume of shaft in terms of total strain energy in shaft due to torsion
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Created Angle of twist for shaft in terms of polar moment of inertia and modulus of rigidity
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Created Diameter of shaft in terms of polar moment of inertia of the shaft
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Created Length of shaft in terms of polar moment of inertia and modulus of rigidity
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Created Maximum shear stress in shaft in terms of polar moment of inertia
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Created Modulus of rigidity of shaft in terms of Torque transmitted and Polar moment of inertia
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Created Polar moment of inertia of shaft in terms of Torque transmitted and modulus of rigidity
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Created Polar moment of inertia of shaft in terms of torque transmitted by the shaft
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Created Polar moment of inertia of the shaft
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Created Radius of shaft in terms of polar moment of inertia
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Created Torque transmitted by shaft in terms of polar moment of inertia
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Created Torque transmitted by shaft in terms of polar moment of inertia and modulus of rigidity
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Created Diameter of bolt in terms of maximum load that can be resisted by one bolt
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Created Diameter of bolt in terms of torque resisted by n bolts
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Created Diameter of bolt in terms of torque resisted by one bolt
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Created Diameter of bolt pitch circle in terms of torque resisted by n bolts
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Created Diameter of bolt pitch circle in terms of torque resisted by one bolt
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Created Diameter of the shaft in terms of torque transmitted by the shaft
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Created Maximum load that can be resisted by one bolt
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Created Number of bolts in terms of torque resisted by n bolts
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Created Shear stress in the bolt in terms of maximum load that can be resisted by one bolt
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Created Shear stress in the bolt in terms of torque resisted by n bolts
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Created Shear stress in the bolt in terms of torque resisted by one bolt
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Created Shear stress in the shaft in terms of torque transmitted by the shaft
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Created Torque resisted by one bolt in terms of load resisted by one bolt
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Created Torque resisted by one bolt in terms of shear stress in the bolt
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Created Torque transmitted by the shaft
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Created Total torque resisted by n bolts
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Verified Area at choke section of sprue
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Verified Area at top section of sprue
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Verified Buoyant force on cores
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Verified Casting yield
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Verified Composition factor for gray cast iron
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Verified Grain Fineness Number (GFN)
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Verified Volume of core
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26 More Foundry (casting) Calculators
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Verified Average Nusselt number for constant wall temperature
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Verified Boundary layer thickness on vertical surfaces
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Verified Convective mass transfer coefficient at distance X from the leading edge
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Verified Effective thermal conductivity
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Verified Heat transfer per unit length for annular space between concentric cylinders
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Verified Length of the annular space between two concentric cylinders
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Verified Local Nusselt number
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Verified Local Nusselt number for constant heat flux
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Verified Local Nusselt number for constant heat flux
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Verified Local Nusselt number given Grashof number
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Verified Nusselt number for higher value of GrPr
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Verified Nusselt number for all the value of GrPr and constant heat flux
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Verified Nusselt number for all the value of GrPr and constant wall temperature
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Verified Nusselt number for both constant wall temperature and heat flux
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Verified Nusselt number for turbulent flow
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Verified Nusselt number for turbulent flow 10^9 < GrPr < 10^13
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Verified Nusselt number with large aspect ratio and lower RL
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Verified Rayleigh number based on length for annular space between two concentric cylinders
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Verified Rayleigh number based on turbulence for annular space between concentric cylinders
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50 More Free convection Calculators
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Created Modulus of rigidity of shaft for free torsional vibration of a single rotor system
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Created Natural frequency of free torsional vibration of a single rotor system
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Created Distance of node from rotor A, for torsional vibration of a two rotor system
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Created Distance of node from rotor B, for torsional vibration of a two rotor system
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Created Mass moment of inertia of rotor A, for torsional vibration of a two rotor system
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Created Mass moment of inertia of rotor B, for torsional vibration of a two rotor system
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Created Natural frequency of free torsional vibration for rotor A of a two rotor system
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Created Natural frequency of free torsional vibration for rotor B of a two rotor system
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Verified Capacitance of circuit
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Verified Frequency of discharge oscillation
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Verified Inductance of circuit
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Created Amplitude reduction factor
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Created Circular damped frequency (underdamping)
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Created Circular damped frequency in terms of natural frequency (underdamping)
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Created Condition for critical damping
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Created Critical damping coefficient
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Created Damping factor
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Created Damping factor(in terms of natural frequency)
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Created Displacement of the mass from the mean position (underdamping)
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Created Frequency constant for damped vibrations (underdamping)
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Created Frequency constant for damped vibrations if circular frequency is known(underdamping)
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Created Frequency of damped vibration (underdamping)
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Created Frequency of damped vibration in terms of natural frequency (underdamping)
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Created frequency of the undamped vibration (underdamping)
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Created Logarithmic decrement
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Created Logarithmic decrement in terms of circular damped frequency
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Created Logarithmic decrement in terms of circular damping coefficient
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Created Logarithmic decrement in terms of natural frequency
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Created Periodic time of vibration (underdamping)
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Created Periodic time of vibration in terms of natural frequency (underdamping)
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Created Complementary function
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Created Damping coefficient
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Created Deflection of the system under the static force
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Created External periodic disturbing force
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Created Maximum displacement or the amplitude of forced vibration
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Created Maximum displacement or the amplitude of forced vibration at resonance
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Created Maximum displacement or the amplitude of forced vibration in terms of natural frequency
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Created Maximum displacement or the amplitude of forced vibration when damping is negligible
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Created Particular integral
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Created Phase constant
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Created Static force
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Created Static force when damping is negligible
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Created Static force when maximum displacement or the amplitude of forced vibration is known
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Created Total displacement of forced vibration in terms of particular integral and complementary function
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Created Total displacement of the forced vibrations
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Created Angle of repose
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Created Efficiency of inclined plane when effort applied horizontally to move the body in downward direction on inclined plane
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Created Efficiency of inclined plane when effort applied horizontally to move the body in upward direction on inclined plane
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Created Efficiency of inclined plane when effort applied parallel to move the body in downward direction on inclined plane
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Created Efficiency of inclined plane when effort applied parallel to move the body in upward direction on inclined plane
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Created Efficiency of inclined plane when effort applied to move the body in downward direction on inclined plane
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Created Efficiency of inclined plane when effort applied to move the body in upward direction on inclined plane
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Created Effort applied parallel to inclined plane to move the body in downward direction considering friction
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Created Effort applied parallel to inclined plane to move the body in upward direction considering friction
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Created Effort applied parallel to inclined plane to move the body in upward/downward direction neglecting friction
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Created Effort applied perpendicular to inclined plane to move the body in downward direction considering friction
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Created Effort applied perpendicular to inclined plane to move the body in upward direction considering friction
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Created Effort applied perpendicular to inclined plane to move the body in upward/downward direction neglecting friction
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Created Effort applied to move the body in downward direction on inclined plane considering friction
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Created Effort applied to move the body in upward direction on inclined plane considering friction
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Created Effort required to move the body down the plane neglecting friction
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Created Effort required to move the body up the plane neglecting friction
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Created Limiting angle of friction
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Created Minimum force required to slide a body on rough horizontal plane
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Created Total torque required to overcome friction in rotating a screw
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3 More Friction Calculators
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Created Efficiency of screw jack when screw friction as well as collar friction considered
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Created Efficiency of screw jack when only screw friction considered
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Created Force at circumference of the screw when weight of load, helix angle and coefficient of friction is known
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Created Force at circumference of the screw when weight of load, helix angle and limiting angle is known
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Created Force required to lower the load by a screw jack when weight of load, helix angle and coefficient of friction is known
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Created Force required to lower the load by a screw jack when weight of load, helix angle and limiting angle is known
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Created Helix Angle
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Created Helix Angle for multi-threaded screw
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Created Helix Angle for single threaded screw
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Created Ideal effort to raise the load by screw jack
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Created Lead of Screw
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Created Maximum efficiency of screw a jack
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Created Mean radius of the collar
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Created Pressure over bearing area of flat pivot bearing
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Created Torque required to overcome friction at collar
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Created Torque required to overcome friction between screw and nut
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Created Torque required to overcome friction between screw and nut(lowering load)
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Created Torque required to overcome friction between screw and nut(lowering load)
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Created Total frictional torque on conical pivot bearing considering uniform pressure
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Created Total frictional torque on conical pivot bearing considering uniform pressure when slant height of cone is given
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Created Total frictional torque on conical pivot bearing considering uniform wear
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Created Total frictional torque on conical pivot bearing considering uniform wear when slant height of cone
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Created Total frictional torque on flat pivot bearing considering uniform pressure
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Created Total frictional torque on flat pivot bearing considering uniform wear
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Created Total frictional torque on truncated conical pivot bearing considering uniform pressure
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Created Total frictional torque on truncated conical pivot bearing considering uniform wear
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Created Total vertical load transmitted to conical pivot bearing (uniform pressure)
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Verified Degree of reaction for compressor
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Verified Degree of reaction for turbine
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Verified Tip velocity of impeller if mean diameter is known
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Verified Tip velocity of impeller in terms of hub diameter and inlet diameter
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5 More Fundamentals of rotating machines Calculators
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Created Holding or braking or fixing torque on the fixed member
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Created Holding or braking or fixing torque on the fixed member
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Created Holding or braking or fixing torque on the fixed member
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Created Output torque or resisting or load torque on the driven member
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Created Output torque or resisting or load torque on the driven member
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Created Speed ratio of compound gear train
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Created Train value
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Created Train value
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Created Train value of compound gear train
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Created Train value of compound gear train
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3 More Gear Trains Calculators
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Verified Energy transfer due to centrifugal effect
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Verified Energy transfer due to change of absolute kinetic energy of the fluid
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Verified Energy transfer due to the change of the relative kinetic energy of the fluid
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Verified Peripheral velocity of the blade at the entry corresponding to diameter
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Verified Peripheral velocity of the blade at the exit corresponding to diameter
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Verified Torque produced
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2 More General fluid dynamics Calculators
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Created Slant Height of cone
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Created Slant Height of Frustum
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104 More Geometry Calculators
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Verified Feed force
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Verified Radial force
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Verified Side cutting edge angle for orthogonal cutting
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Verified Side rake angle for orthogonal cutting
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6 More Geometry of Turning Process Calculators
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Verified Degree of freedom
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Verified Number of Components
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Verified Number of Phases
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Verified Total Number of Variables in a System
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Created Angle b/w the axis of radius of rotation and line joining a point on the curve to the origin O
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Created Angle b/w the axis of radius of rotation and line joining a point on the curve to the origin O
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Created Angle of inclination of the arm to the vertical (porter governor)
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Created Centrifugal force at maximum equilibrium speed on each ball for wilson-hartnell governor
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Created Centrifugal force at maximum radius of rotation
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Created Centrifugal force at minimum equilibrium speed on each ball for wilson-hartnell governor
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Created Centrifugal force at minimum radius of rotation
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Created Centrifugal force for Hartung governor
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Created Centrifugal force for pickering governor
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Created Centrifugal force on each ball for wilson-hartnell governor
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Created Coefficient of insensitiveness
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Created Coefficient of insensitiveness
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Created Coefficient of insensitiveness for porter governor(if angle made by upper & lower arm aren't equal)
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Created Coefficient of insensitiveness for porter governor(if angle made by upper and lower arm are equal)
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Created Coefficient of insensitiveness for the Hartnell governor
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Created Coefficient of insensitiveness when all the arms of porter governor are attached to governor axis
Go
Created Coefficient of insensitiveness when lower arm is not attached on the governor axis(Porter governor)
Go
Created Controlling force for porter governor
Go
Created Controlling force for porter governor
Go
Created Corresponding radial force required at each ball for spring loaded governors
Go
Created Corresponding radial force required at each ball for the porter governor
Go
Created Deflection of the center of the leaf spring in pickering governor
Go
Created Deflection of the center of the leaf spring in pickering governor
Go
Created Effort of a porter governor(if angle made by upper and lower arms are equal)
Go
Created Effort of a porter governor(if angle made by upper and lower arms are not equal)
Go
Created Force in the arm (porter governor) when centrifugal force on ball is given
Go
Created Force in the arm (porter governor) when force in the link is known
Go
Created Force in the arm (porter governor) when mass of central load and ball are given
Go
Created Force in the arm (porter governor) when weight of central load and ball are given
Go
Created Force in the link (porter governor) when mass of central load is known
Go
Created Force in the link (porter governor) when weight of central load is known
Go
Created Governor power
Go
Created Height of the governor (porter governor)
Go
Created Height of the governor (porter governor, q=1)
Go
Created Height of the watt governor
Go
Created Increased speed
Go
Created Lift of the sleeve at maximum radius of rotation(Hartnell governor)
Go
Created Lift of the sleeve at minimum radius of rotation(Hartnell governor)
Go
Created Lift of the sleeve corresponding to the deflection
Go
Created Lift of the sleeve for porter governor (if angle made by upper and lower arms are equal)
Go
Created Lift of the sleeve for porter governor (if angle made by upper and lower arms are not equal)
Go
Created Mean equilibrium angular speed
Go
Created Mean equilibrium speed in r.p.m
Go
Created Moment of inertia of pickering governor cross-section about the neutral axis
Go
Created Net increase in speed of porter governor
Go
Created Power of a porter governor(if angle made by upper and lower arms are equal)
Go
Created Power of a porter governor(if angle made by upper and lower arms are not equal)
Go
Created Ratio of length of arm to the length of link
Go
Created Sensitiveness of the governor when angular speed in r.p.m is given
Go
Created Sensitiveness of the governor when angular speed in r.p.m is given
Go
Created Sensitiveness of the governor when angular speed is given
Go
Created Sensitiveness of the governor when angular speed is given
Go
Created Sleeve load for decrease in speed value (taking friction into account)
Go
Created Sleeve load for increase in speed value (taking friction into account)
Go
Created Speed of the ball in rpm (porter governor) when the length of arms are equal to the length of links
Go
Created Speed of the rotation in rpm
Go
Created Stiffness of each ball spring
Go
Created Stiffness of the spring (Hartnell governor) when the total lift is given
Go
Created Stiffness of the spring or the force required to compress the spring by one mm(Hartnell governor)
Go
Created Stiffness of the spring when centrifugal force at maximum radius is known(Hartnell governor)
Go
Created Stiffness of the spring when centrifugal force at minimum radius is known(Hartnell governor)
Go
Created Stiffness of the spring when centrifugal force when min and max radius is known(Hartnell governor)
Go
Created The centrifugal force for any intermediate position (Hartnell governor)
Go
Created The centrifugal force for any intermediate position (Hartnell governor)
Go
Created The relation b/w controlling force and radius of rotation for stability of governor
Go
Created The relation b/w controlling force and radius of rotation for the unstability of governor
Go
Created The relation between the controlling force and the radius of rotation for isochronous governors
Go
Created Total downward force on the sleeve in wilson-hartnell governor
Go
Created Total lift of the sleeve(Hartnell governor)
Go
Created Total lift of the sleeve(Hartnell governor) when maximum and the minimum lift is known
Go
Created Value of Controlling force for decrease in speed
Go
Created Value of Controlling force for increase in speed
Go
Verified Area of the heat exchanger
Go
Verified Convective heat transfer coefficient of storage type heat exchanger given time factor
Go
Verified Correction factor in heat exchanger
Go
Verified Heat exchanged
Go
Verified Heat transfer surface area for unit length given time factor
Go
Verified Logarithmic mean temperature difference for single pass counter flow
Go
Verified Mass flow rate of hot fluid
Go
Verified Overall heat transfer coefficient
Go
Verified Specific heat of hot water
Go
Verified Specific heat of matrix material
Go
Verified Time factor of a storage type heat exchanger
Go
Verified Time taken for the heat transfer
Go
12 More Heat exchanger Calculators
Go
Created Diameter of a Rod Circular Fin when area of cross-section is Given
Go
14 More Heat Transfer Calculators
Go
Created Average load on spring
Go
Created Axial load of spring in if deflection and stiffness of spring is given
Go
Created Axial load on spring in terms of deflection of spring
Go
Created Axial load on spring in terms of strain energy stored by spring
Go
Created Axial load on spring in terms of work done on spring
Go
Created Axial loading on spring
Go
Created Axial loading on spring in terms of maximum shear stress induced in the wire
Go
Created Deflection in terms of average load on spring
Go
Created Deflection of spring
Go
Created Deflection of spring in terms of stiffness of spring
Go
Created Deflection of spring in terms of work done on spring
Go
Created Diameter of spring wire in terms of deflection of spring
Go
Created Diameter of spring wire in terms of maximum shear stress induced in the wire
Go
Created Diameter of spring wire in terms of stiffness of helical spring
Go
Created Diameter of spring wire in terms of strain energy stored by spring
Go
Created Diameter of spring wire in terms of twisting moment
Go
Created Maximum shear stress induced in the wire
Go
Created Maximum shear stress induced in the wire in terms of twisting moment
Go
Created Mean radius of spring coil
Go
Created Mean radius of spring coil in terms of maximum shear stress induced in the wire
Go
Created Mean radius of spring coil of helical spring in terms of stiffness of spring
Go
Created Mean radius of spring roll in terms of deflection of spring
Go
Created Mean radius of spring rolls in terms of strain energy stored by spring
Go
Created Mean radius of spring rolls in terms of total length of wire of spring
Go
Created Modulus of rigidity in terms of deflection of spring
Go
Created Modulus of rigidity in terms of stiffness of helical spring
Go
Created Modulus of rigidity in terms of strain energy stored by spring
Go
Created Number of coils in terms of deflection of spring
Go
Created Number of coils in terms of strain energy stored by spring
Go
Created Number of coils in terms of total length of wire of spring
Go
Created Number of coils of helical spring in terms of stiffness of spring
Go
Created Stiffness of helical spring
Go
Created Stiffness of spring in terms of deflection of spring
Go
Created Strain energy stored by the spring
Go
Created Total length of wire of helical spring
Go
Created Total length of wire of helical spring in terms of mean radius of spring roll
Go
Created Twisting moment in terms of maximum shear stress induced in the wire
Go
Created Twisting moment on the wire of helical spring
Go
Created Work done on the spring in terms of average load
Go
Created Work done on the spring in terms of axial load on spring
Go
Created Lateral surface area of hemisphere
Go
3 More Hemisphere Calculators
Go
Created Distance of the outermost layer from neutral axis in hollow circular section
Go
Created Inner diameter of hollow circular section in terms of section modulus
Go
Created Moment of inertia of hollow circular section
Go
Created Outer diameter of hollow circular section
Go
Created Section modulus of hollow circular section
Go
Created Lateral surface area of hollow cylinder
Go
Created Total Surface Area of Hollow Cylinder
Go
Created Distance of the outermost layer from neutral axis for hollow rectangular section
Go
Created Moment of inertia for hollow rectangular section
Go
Created Outer breadth of hollow rectangular section in terms of section modulus
Go
Created Outer length of hollow rectangular section
Go
Created Section modulus for hollow rectangular section
Go
Created Force due to circumferential stress in thin cylindrical vessel
Go
Created Force due to fluid pressure in thin cylindrical vessel
Go
Created Hoop stress
Go
Created Hoop stress in terms of force due to circumferential stress in thin cylindrical vessel
Go
Created Internal diameter of vessel in terms of Force due to fluid pressure in thin cylindrical vessel
Go
Created Internal diameter of vessel in terms of hoop stress
Go
Created Internal pressure of fluid in terms of Force due to fluid pressure in thin cylindrical vessel
Go
Created Internal pressure of fluid in vessel in terms of hoop stress
Go
Created Length of vessel in terms of force due to circumferential stress in thin cylindrical vessel
Go
Created Length of vessel in terms of Force due to fluid pressure in thin cylindrical vessel
Go
Created Thickness of vessel in terms of hoop stress
Go
Created Vessel thickness in terms of force due to circumferential stress in thin cylindrical vessel
Go
Verified Absolute humidity at inside temperature in dehumidification
Go
Verified Enthalpy of evaporation for water in humidification
Go
Verified Enthalpy of evaporation in dehumidification
Go
Verified Enthalpy of evaporation of water in humidification
Go
Verified Gas constant of water vapor
Go
Verified Gas phase mass transfer coefficient
Go
Verified Heat transfer coefficient in humidification
Go
Verified Height of tower in abiotic humidification
Go
Verified Liquid phase heat transfer coefficient in dehumidification
Go
Verified Mass velocity of air per unit area
Go
Verified Specific heat of air given gas constant
Go
Verified Temperature of air during humidification
Go
Verified Wet bulb temperature of humidification
Go
11 More Humidification Calculators
Go
Created Height of Cone inscribed in a sphere for maximum volume of cone in terms of radius of sphere
Go
Created Radius of cone inscribed in a sphere for maximum volume of cone in terms of radius of sphere
Go
Created Volume of Cone inscribed in a sphere for maximum volume of cone in terms of radius of sphere
Go
Created Volume of Cone inscribed in a sphere when radius of sphere and cone are given
Go
Created Lateral Surface Area of Largest Cube that can be inscribed within a right circular cylinder when height of cylinder is given
Go
Created Side of Largest Cube that can be inscribed within a right circular cylinder of height h
Go
Created Total Surface Area of Largest Cube that can be inscribed within a right circular cylinder when height of cylinder is given
Go
Created Volume of Largest cube that can be inscribed within a right circular cylinder when height of cylinder is given
Go
Created Convex Surface Area of a circular cylinder of maximum convex surface area in a given circular cone
Go
Created Curved Surface Area of Largest right circular cylinder that can be inscribed within a cone
Go
Created Curved Surface Area of Largest right circular cylinder within a cube when side of cube is given
Go
Created Diameter of a circular cylinder of maximum convex surface area in a given circular cone
Go
Created Height of a circular cylinder of maximum convex surface area in a given circular cone
Go
Created Height of Largest right circular cylinder that can be inscribed within a cone
Go
Created Height of Largest right circular cylinder within a cube
Go
Created Radius of largest right circular cylinder that can be inscribed within a cone when radius of cone is given
Go
Created Radius of Largest right circular cylinder within a cube when side of cube given
Go
Created Total Surface Area of Largest right circular cylinder that can be inscribed within a cone
Go
Created Total Surface Area of largest right circular cylinder within a cube
Go
Created Volume of Largest right circular cylinder that can be inscribed within a cone
Go
Created Volume of Largest right circular cylinder within a cube when side of cube is given
Go
Created Altitude of the largest right pyramid with a square base that can be inscribed in a sphere of radius a
Go
Created Base length of the largest right pyramid with a square base that can be inscribed in a sphere of radius a
Go
Created Volume of the largest right pyramid with a square base that can be inscribed in a sphere of radius a
Go
Created Radius of inscribed sphere in a cone when radius and height of cone are known
Go
Created The Radius R of the inscribed sphere for cube with a side length S
Go
Verified Interference of waves of two intensities
Go
2 More Interference of waves of two intensities Calculators
Go
Created Bending stress for a hollow circular section in terms of diameter
Go
Created Bending stress for a hollow circular section in terms of eccentric load and eccentricity
Go
Created Bending stress for hollow circular section
Go
Created Diameter of kernel for hollow circular section
Go
Created Eccentric Load in terms of bending stress on hollow circular section
Go
Created Eccentricity in terms of bending stress on hollow circular section
Go
Created Inner diameter of hollow circular section if diameter of kernel is given
Go
Created Internal diameter in terms of maximum eccentricity of load for hollow circular section
Go
Created Maximum value of eccentricity of load for hollow circular section
Go
Created Moment due to eccentric load in terms of bending stress on hollow circular section
Go
Created Section modulus hollow circular section
Go
Created Section modulus in terms of bending stress and eccentric load on hollow circular section
Go
Created Section modulus in terms of bending stress on hollow circular section
Go
Created Distance of outermost layer from neutral axis for hollow rectangular section
Go
Created External length of hollow rectangular section if section modulus about yy axis is known
Go
Created External width of hollow rectangular section if section modulus about xx axis is known
Go
Created Internal length of hollow rectangular section if section modulus about xx axis is known
Go
Created Internal length of hollow rectangular section if section modulus about yy axis is known
Go
Created Internal width of hollow rectangular section if section modulus about xx axis is known
Go
Created Maximum eccentricity of load about x axis for hollow rectangular section
Go
Created Maximum eccentricity of load about y axis for hollow rectangular section
Go
Created Moment of inertia about xx axis for hollow rectangular section
Go
Created Section modulus about xx axis for hollow rectangular section in terms length and width of section
Go
Created Section modulus about xx axis for hollow rectangular section in terms of moment of inertia
Go
Created Section modulus about yy axis for hollow rectangular section in terms length and width of section
Go
Created Section modulus about yy axis for hollow rectangular section in terms of moment of inertia
Go
Verified The velocity of the fluid particle
Go
1 More Kinematic Properties Calculators
Go
Created Angle of Inclination of resultant acceleration with tangential acceleration
Go
Created Angle Traced in nth Second (accelerated rotatory motion)
Go
Created Angular Displacement if initial angular velocity, angular acceleration and time are given
Go
Created Angular Displacement if initial angular velocity, final angular velocity and time are given
Go
Created Angular Displacement of body when initial and final angular velocity and angular acceleration are given
Go
Created Angular Velocity
Go
Created Average Velocity of body when initial and final velocity are given
Go
Created Displacement of Body when initial velocity, final velocity and acceleration are given
Go
Created Displacement of Body when initial velocity, final velocity and time are given
Go
Created Displacement of Body when initial velocity, time and acceleration are given
Go
Created Distance travelled in nth second( accelerated translatory motion)
Go
Created Final Angular Velocity if initial angular velocity, angular acceleration and time is given
Go
Created Final Velocity of body
Go
Created Final Velocity of freely falling body from height h, when it reaches ground
Go
Created Normal Acceleration
Go
Created Resultant Acceleration
Go
Created Tangential Acceleration
Go
Created Angular acceleration of shaft B if gear ratio and angular acceleration of shaft A is known
Go
Created Angular Velocity when speed in R.P.M is given
Go
Created Centripetal Force or Centrifugal Force when angular velocity, mass and radius of curvature are given
Go
Created Coefficient of Restitution
Go
Created Efficiency of Machine
Go
Created Equivalent Mass Moment of Inertia of geared system with shaft A and shaft B
Go
Created Final Velocity of body A and B after inelastic collision
Go
Created Gear Ratio when two shafts A and B are geared together
Go
Created Impulse
Go
Created Impulsive Force
Go
Created Impulsive Torque
Go
Created Kinetic Energy of system after inelastic collision
Go
Created Loss of Kinetic Energy during imperfect elastic impact
Go
Created Loss of Kinetic Energy during perfectly inelastic collision
Go
Created Overall Efficiency from shaft A to X
Go
Created Power Loss
Go
Created Speed of Guide Pulley
Go
Created Torque required on shaft A to accelerate itself if M.I of A and angular acceleration of shaft A are given
Go
Created Total Kinetic Energy of the geared system
Go
Created Total Torque applied to accelerate the geared system if Ta and Tab are known
Go
Created Total Torque applied to shaft A to accelerate the geared system
Go
4 More Kinetics of Motion Calculators
Go
Verified Average temperature difference between plate and fluid
Go
Verified Density given local friction coefficient
Go
Verified Film temperature
Go
Verified Free stream fluid temperature
Go
Verified Free stream velocity given local friction coefficient
Go
Verified Local friction coefficient
Go
Verified Nusselt number for constant heat flux
Go
Verified Nusselt number for constant wall temperature
Go
Verified Nusselt number for liquid metals and for silicones
Go
Verified Nusselt number for liquid metals only
Go
Verified Nusselt number if heating starts from a distance Xo from leading edge
Go
Verified Plate surface temperature
Go
Verified Wall shear stress
Go
11 More Laminar flow Calculators
Go
Verified Darcy friction factor
Go
Verified Diameter of hydrodynamic entry tube
Go
Verified Diameter of thermal entry tube
Go
Verified Hydrodynamic entry length
Go
Verified Nusselt number for hydrodynamic length fully developed and thermal length still developing
Go
Verified Nusselt number for liquids
Go
Verified Nusselt number for short lengths
Go
Verified Nusselt number for simultaneous development of hydrodynamic and thermal layers
Go
Verified Reynolds number based on diameter
Go
Verified Thermal entry length
Go
3 More Laminar flow Calculators
Go
Created Bending moment at center in terms of point load acting at the center of spring load
Go
Created Bending moment at the center of the leaf spring
Go
Created Bending moment on each plate in terms of total resisting moment by n plates
Go
Created Bending moment on single plate
Go
Created Central deflection of leaf spring
Go
Created Central deflection of the leaf spring if modulus of elasticity is given
Go
Created Load at one end in terms of bending moment at the center of the leaf spring
Go
Created Maximum bending moment developed in the plate in terms of bending moment on single plate
Go
Created Maximum bending moment developed in the plate in terms of total resisting moment by n plates
Go
Created Maximum bending stress developed in plates in terms of point load at center
Go
Created Maximum bending stress developed in terms of central deflection of the leaf spring
Go
Created Maximum bending stress developed in terms of radius of the plate to which they are bent
Go
Created Modulus of elasticity in terms of central deflection of the leaf spring
Go
Created Modulus of elasticity in terms of radius of the plate to which they are bent
Go
Created Moment of inertia of each plate
Go
Created No. of plates in leaf spring in terms of total resisting moment by n plates
Go
Created Number of plates in terms of maximum bending stress developed in plates
Go
Created Point load acting at center of spring in terms of maximum bending stress developed in plates
Go
Created Point load at center of spring load in terms of bending moment at the center of leaf spring
Go
Created Radius of plate to which they are bent in terms of central deflection of leaf spring
Go
Created Radius of the plate to which they are bent
Go
Created Span of spring in terms of bending moment at the center of leaf spring
Go
Created Span of spring in terms of bending moment at the center of leaf spring and point load at center
Go
Created Span of spring in terms of central deflection of leaf spring
Go
Created Span of spring in terms of central deflection of the leaf spring
Go
Created Span of spring in terms of central deflection of the leaf spring
Go
Created Span of spring in terms of maximum bending stress developed in plates
Go
Created Thickness of each plate in terms of bending moment on single plate
Go
Created Thickness of each plate in terms of Moment of inertia of each plate
Go
Created Thickness of each plate in terms of total resisting moment by n plates
Go
Created Thickness of plates in terms of central deflection of the leaf spring
Go
Created Thickness of plates in terms of maximum bending stress developed in plates
Go
Created Thickness of plates in terms of radius of the plate to which they are bent
Go
Created Total resisting moment by n plates
Go
Created Total resisting moment by n plates in terms of bending moment on each plate
Go
Created Width of each plate in terms of bending moment on single plate
Go
Created Width of each plate in terms of Moment of inertia of each plate
Go
Created Width of each plate in terms of total resisting moment by n plates
Go
Created Width of plates in terms of maximum bending stress developed in plates
Go
Verified Effort required by machine to overcome resistance to get work done
Go
Verified Ideal effort if load and velocity ratio is known
Go
Verified Ideal load if velocity ratio and effort is known
Go
Verified Load lifted if effort and mechanical advantage is known
Go
Verified Mechanical advantage if load and effort is known
Go
Verified Torque required while load is ascending in screw jack
Go
Verified Torque required while load is descending in screw jack
Go
Verified Useful work output of the machine
Go
Verified Work done by effort
Go
3 More Lifting machines Calculators
Go
Created Hoop stress in thin cylindrical vessel in terms of longitudinal stress
Go
Created Internal diameter of vessel in terms of Longitudinal stress in the cylindrical vessel material
Go
Created Internal diameter of vessel in terms of resisting force on thin cylindrical vessel
Go
Created Internal pressure of fluid in terms of Longitudinal stress in the cylindrical vessel material
Go
Created Longitudinal stress in the cylindrical vessel material
Go
Created Longitudinal stress in the material in terms of resisting force on thin cylindrical vessel
Go
Created Longitudinal stress in thin cylindrical vessel in terms of hoop stress
Go
Created Resisting force on thin cylindrical vessel
Go
Created Thickness of cylindrical vessel in terms of resisting force on thin cylindrical vessel
Go
Created Thickness of vessel in terms of Longitudinal stress in the cylindrical vessel material
Go
Created Length of the constraint for longitudinal vibration
Go
Created Longitudinal velocity of the free end for longitudinal vibration
Go
Created Natural frequency of longitudinal vibration
Go
Created Total kinetic energy possessed by the constraint for longitudinal vibration
Go
Created Total mass of the constraint for longitudinal vibration
Go
Created Velocity of the small element for longitudinal vibration
Go
Created Magnification factor
Go
Created Magnification factor at resonance
Go
Created Magnification factor if there is no damping
Go
Created Magnification factor in terms of displacement of vibrations
Go
Created Maximum displacement in terms of magnification factor
Go
Created Natural circular frequency in terms of magnification factor
Go
Created Coefficient of Friction
Go
41 More Manufacturing Calculators
Go
Verified Frequency of charging
Go
Verified Input power supply to achieve given MRR
Go
Verified Material removal rate, MRR
Go
Verified Metal removal rate from volume of crater
Go
Verified Proportionality constant for MRR
Go
Verified Resistance of the circuit
Go
Verified Volume of crater from MRR
Go
Verified Capacitance of circuit
Go
Verified Inductance of circuit
Go
Verified Maximum spark current
Go
Verified Voltage of charging circuit
Go
Verified Cutting force for frictional force along the tool rake face, thrust force and normal rake angle
Go
Verified Cutting force for given force along the shear force, thrust force, and shear angle
Go
Verified Force along shear force for given force normal to shear force, shear, friction & normal rake angles
Go
Verified Force along the shear force for given cutting force, thrust force, and shear angle
Go
Verified Force normal to shear force for given cutting force, thrust force, and shear angle
Go
Verified Frictional force along tool rake face for given cutting & thrust forces and normal rake angle
Go
Verified Thrust force for given cutting force, shear angle & force along the shear force
Go
Verified Thrust force for given cutting force, shear angle & force normal to shear force
Go
30 More Merchant Force Circle (Mechanics of Orthogonal metal cutting) Calculators
Go
Created Condition for maximum bending stress
Go
Created Condition for maximum bending stress in terms of diameter
Go
Created Diameter of a Circular Section if Direct Stress for the Circular Section is Given
Go
Created Diameter of circular section if maximum value of eccentricity is known(for no tensile stress case)
Go
Created Diameter of circular section in terms of maximum bending stress
Go
Created Direct stress for circular section
Go
Created Eccentric load if direct stress for a circular section is given
Go
Created Eccentric load in terms of maximum bending stress
Go
Created Eccentric load in terms of minimum bending stress
Go
Created Eccentricity of load in terms of maximum bending stress
Go
Created Eccentricity of load in terms of minimum bending stress
Go
Created Maximum bending stress for circular section if moment of load is known
Go
Created Maximum bending stress in terms of eccentric load
Go
Created Maximum value of eccentricity for no tensile stress
Go
Created Minimum bending stress if direct and bending stress are known
Go
Created Minimum bending stress in terms of eccentric load
Go
Created Moment of inertia of circular section if maximum bending stress for circular section is known
Go
Created Moment of load if maximum bending stress for circular section is known
Go
Verified Capacitance of the circuit
Go
Verified Inductance of the circuit
Go
Verified Minimum resistance in the circuit
Go
Verified Condition for maximum value of normal stress
Go
Verified Condition for minimum value of normal stress
Go
Verified Maximum value of normal stress
Go
Verified Minimum value of normal stress
Go
Verified Normal stress on the oblique plane(two mutually perpendicular unequal stresses)
Go
Verified Shear stress on the oblique plane(two mutually perpendicular and unequal stress)
Go
2 More Mohr's Circle When A Body Is Subjected To Two Mutual Perpendicular And A Simple Shear Stress Calculators
Go
Verified Maximum shear stress
Go
Verified Normal stress on oblique plane( two mutually perpendicular force and one shear force)
Go
Verified Radius of mohr's circle(two mutually perpendicular stresses of unequal intensities)
Go
Verified Tangential stress on oblique plane(two mutually perpendicular forces and one shear force)
Go
Verified Normal stress on oblique plane(two mutually perpendicular unequal and unlike stress)
Go
Verified Radius of mohr's circle(Unequal and unlike mutually perpendicular stresses)
Go
Verified Shear stress on oblique plane(two mutually perpendicular unequal and unlike stress)
Go
1 More Mohr's Circle When A Body Is Subjected To Two Mutual Perpendicular Tensile Stress Which Are Unequal And Unlike Calculators
Go
Verified Convective mass transfer coefficient
Go
Verified Equimolal diffusion of gases (mass flux)
Go
Verified Steady state equimolal counter diffusion between liquids (mass flux)
Go
14 More Molar diffusion Calculators
Go
Created Accelerating force
Go
Created Angular displacement of the shaft from mean position
Go
Created Angular velocity of the shaft
Go
Created Moment of inertia of the disc in terms of angular velocity
Go
Created Moment of Inertia of the disc in terms of natural frequency of vibration
Go
Created Moment of inertia of the disc in terms of time period of vibration
Go
Created Natural frequency of vibration
Go
Created Restoring force for free torsional vibrations
Go
Created Time period for the vibrations
Go
Created Torsional stiffness of the shaft
Go
Created Torsional stiffness of the shaft in terms of angular velocity
Go
Created Torsional stiffness of the shaft in terms of natural frequency of vibration
Go
Created Torsional stiffness of the shaft in terms of time period of vibration
Go
Created Acceleration of body in terms of stiffness of shaft
Go
Created Length of the shaft
Go
Created Load at the free end
Go
Created Moment of inertia of shaft in terms of static deflection
Go
Created Natural Frequency of free transverse vibrations
Go
Created Restoring force
Go
Created Static deflection
Go
Created Time period of free transverse vibrations
Go
Created Circular frequency due to uniformly distributed load
Go
Created Circular frequency in terms of static deflection
Go
Created Length of the shaft in terms of circular frequency
Go
Created Length of the shaft in terms of natural frequency
Go
Created Length of the shaft in terms of static deflection
Go
Created Maximum bending moment at a distance x from end A
Go
Created Moment of Inertia of shaft in terms of circular frequency
Go
Created Moment of Inertia of shaft in terms of natural frequency
Go
Created Moment of Inertia of shaft in terms of static deflection
Go
Created Natural frequency due to uniformly distributed load
Go
Created Natural frequency in terms of static deflection
Go
Created Static deflection at a distance x from end A
Go
Created Static deflection in terms of natural frequency
Go
Created Static deflection of a simply supported shaft due to uniformly distributed load
Go
Created Uniformly distributed load unit length in terms of circular frequency
Go
Created Uniformly distributed load unit length in terms of natural frequency
Go
Created Uniformly distributed load unit length in terms of static deflection
Go
Created Bending moment at a distance x from end A
Go
Created Circular frequency in terms of static deflection(Shaft fixed, uniformly distributed load)
Go
Created Length of shaft in terms of natural circular frequency(Shaft fixed, uniformly distributed load)
Go
Created Length of shaft in terms of natural frequency(Shaft fixed, uniformly distributed load)
Go
Created Length of shaft in terms of static deflection(Shaft fixed, uniformly distributed load)
Go
Created Load in terms of natural circular frequency(Shaft fixed, uniformly distributed load)
Go
Created Load in terms of natural frequency(Shaft fixed, uniformly distributed load)
Go
Created load in terms of static deflection(Shaft fixed, uniformly distributed load)
Go
Created M.I of shaft in terms of natural circular frequency(Shaft fixed, uniformly distributed load)
Go
Created M.I of shaft in terms of natural frequency(Shaft fixed, uniformly distributed load)
Go
Created M.I of shaft in terms of static deflection(Shaft fixed, uniformly distributed load)
Go
Created Natural circular frequency of shaft fixed at both ends and carrying a uniformly distributed load
Go
Created Natural frequency in terms of static deflection(Shaft fixed, uniformly distributed load)
Go
Created Natural frequency of shaft fixed at both ends and carrying a uniformly distributed load
Go
Created Static deflection at a distance x from end A
Go
Created Static deflection in terms of natural frequency(Shaft fixed, uniformly distributed load)
Go
Created Static deflection of a simply supported shaft due to uniformly distributed load
Go
Verified NTU relation of a heat exchanger given all exchanger C=0
Go
Verified NTU relation of a heat exchanger with one shell pass and 2, 4, 6 tube pass
Go
Verified NTU relation of double pipe counter flow heat exchanger
Go
Verified NTU relation of double pipe counter flow heat exchanger given C=1
Go
Verified NTU relation of double pipe counter flow heat exchanger with Cmax mixed and Cmin unmixed
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Verified NTU relation of double pipe counter flow heat exchanger with Cmax unmixed and Cmin mixed
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2 More NTU relations Calculators
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Nucleus (11)
Created Average Life
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Created Binding Energy
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Created Change in Mass in Nuclear Reaction
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Created Decay Rate
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Created Energy Released in Nuclear Reaction
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Created Half Life for nuclear decay
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Created Mass Defect
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Created Nuclear Radius
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Created Population After n Half Lives
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Created Population at Time t
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Created Q-Value
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Verified Closed-loop gain of the noninverting amplifier circuit
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Verified Output voltage of difference amplifiers
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Verified Output voltage of the noninverting circuit
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Verified Percentage gain error of noninverting amplifier
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13 More Operational Amplifiers Calculators
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Verified Absolute Velocity of the Pelton jet
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Verified Bucket velocity of the Pelton turbine
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Verified Coefficient of Velocity for the Pelton wheel
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Verified Energy per unit mass of the Pelton
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Verified Energy per unit mass of the Pelton turbine
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Verified Inlet relative velocity of the Pelton
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Verified Outlet relative velocity of the Pelton
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Verified Pelton Head
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Verified Power of the Pelton turbine
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Verified Power of the Pelton turbine when velocity is given
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Verified The tangential component of Pelton inlet velocity
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Verified The tangential component of Pelton outlet velocity
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Verified Wheel efficiency of a Pelton turbine
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Verified Wheel efficiency of Pelton turbine when power is given
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Verified De Broglie Wavelength
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Verified Max KE of Ejected Photo-Electron
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6 More Photoelectric Effect Calculators
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Created Surface Area of Dodecahedron
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Created Surface Area of Icosahedron
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Created Surface Area of Regular Octahedron
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Created Surface Area of Regular Tetrahedron
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Created Diameter of solid shaft in terms of polar modulus
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Created Inner diameter of hollow shaft in terms of polar modulus
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Created Polar modulus
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Created Polar modulus of hollow shaft
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Created Polar modulus of solid shaft
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Created Polar moment of inertia in terms of polar modulus
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Created Polar moment of inertia of of hollow shaft
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Created Polar moment of inertia of of solid shaft
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Created Radius of shaft in terms of polar modulus
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Verified MRR for given surface unevenness
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Verified Surface unevenness
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Verified Volume of crater made by an electric spark
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12 More Possible surface defects in EDM Calculators
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Verified Energy delivered per spark
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Verified Power supply required for given spark power
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Verified Resistance of charging circuit
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Verified Efficiency of Square Threaded Screw
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Verified Mean diameter of Screw When Helix Angle is Given
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Verified Nominal Diameter of Power Screw When Mean DIameter is Given
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13 More Power Screws Calculators
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Verified Condition for maximum or minimum shear stress(Member under direct and shear stress)
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Verified Major principal stress(Member subjected to two perpendicular direct stress and a shear stress)
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Verified Maximum axial force
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Verified Maximum shear stress
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Verified Maximum shear stress(Member under direct and shear stress)
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Verified Minor principal stress(Member subjected to two perpendicular direct stress and a shear stress)
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Verified Normal stress for an oblique section
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Verified Normal stress for principal planes (planes at angle of 0 degree)
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Verified Normal stress for principal planes (planes at angle of 0 degree)
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Verified Normal stress for principal planes (planes at angle of 90 degree)
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Verified Normal stress if obliquity is given
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Verified Normal stress on the oblique section if stress applied in two perpendicular directions
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Verified Obliquity
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Verified Resultant stress on the oblique section if stress applied in two perpendicular directions
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Verified Safe stress if safe value of axial pull is known
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Verified Safe value of axial pull
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Verified Shear stress if obliquity is given
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Verified Stress in the direction of maximum axial force
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Verified Tangential stress for an oblique section
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Verified Tangential stress on the oblique section if stress applied in two perpendicular directions
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Prism (2)
Created Surface Area of Prisms
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Created Surface Area of triangular prism
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Verified Maximum pressure for backward extrusion of carbon steels
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12 More Production Engineering Calculators
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Created Height of object when horizontal distance is given
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6 More Projectile Motion ( object thrown at some angle 'theta' ) Calculators
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Created Displacement of the body from the mean position
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Created Maximum displacement from mean position if displacement of the body from mean position is known
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Created Maximum displacement from mean position if maximum kinetic energy is known
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Created Maximum displacement from mean position if maximum potential energy is known
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Created Maximum displacement from mean position if maximum velocity at mean position is known
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Created Maximum displacement from mean position if velocity at mean position is known
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Created Maximum kinetic energy at mean position
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Created Maximum potential energy at mean position
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Created Maximum velocity at the mean position
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Created Natural circular frequency if displacement of the body is known
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Created Natural circular frequency if maximum velocity at mean position is known
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Created Natural frequency if natural circular frequency is known
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Created Time period in terms of natural circular frequency
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Created Velocity at mean position
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3 More Rayleigh’s Method Calculators
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Created Breadth of rectangular section in terms of section modulus
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Created Distance of outermost layer from neutral layer for rectangular section
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Created Length of rectangular section if distance of outermost layer from neutral layer is known
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Created Length of rectangular section in terms of section modulus
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Created Section modulus for rectangular section
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Created Average shear stress for the rectangular section
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Created Average shear stress if maximum shear stress is given(rectangular section)
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Created Distance of C.G of the area(area above considered level)from neutral axis for rectangular section
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Created Distance of the considered level from neutral axis for rectangular section
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Created Maximum shear stress for the rectangular section
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Created Moment of inertia of the rectangular section about neutral axis
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Created Shear force for the rectangular section
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Created Shear force variation across neutral axis for rectangular section
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Created Shear stress for the rectangular section
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Created Shear stress variation across neutral axis for rectangular section
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Created Bending stress due to eccentricity about x-x axis
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Created Bending stress due to eccentricity about x-x axis in terms of eccentric load on column
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Created Bending stress due to eccentricity about y-y axis
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Created Bending stress due to eccentricity about y-y axis in terms of eccentric load on column
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Created Distance of load point from x axis if bending stress about x-x axis is known
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Created Distance of load point from x axis if bending stress about x-x axis is known
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Created Eccentric load on column if bending stress along x-x axis is known
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Created Eccentric load on column if bending stress along y-y axis is known
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Created Eccentricity of load about X-X axis
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Created Eccentricity of load about x-x axis if bending stress about x-x axis is known
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Created Eccentricity of load about Y-Y axis
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Created Eccentricity of load about y-y axis if bending stress about y-y axis is known
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Created Moment of inertia about x-x axis if bending stress about x-x axis is known
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Created Moment of inertia about y-y axis if bending stress about y-y axis is known
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Created Moment of load about X-X axis
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Created Moment of load about x-x axis if bending stress about x-x axis is known
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Created Moment of load about Y-Y axis
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Created Moment of load about y-y axis if bending stress about y-y axis is known
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Created Bending stress in terms of eccentric load and eccentricity
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Created Bending stress in terms of moment due to load
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Created Depth of column in terms of bending stress and eccentric load
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Created Depth of column in terms of bending stress and moment due to load
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Created Eccentric load in terms of bending stress
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Created Eccentric load in terms of maximum stress
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Created Eccentric load in terms of minimum stress
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Created Eccentricity if moment due to eccentric load is given
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Created Eccentricity in terms of bending stress
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Created Eccentricity in terms of maximum stress
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Created Eccentricity in terms of minimum stress
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Created Load if moment due to eccentric load is known
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Created Maximum stress
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Created Maximum stress in terms of eccentric load and eccentricity
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Created Minimum stress
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Created Minimum stress in terms of eccentric load and eccentricity
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Created Moment due to eccentric load
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Created Moment due to load in terms of bending stress
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Created Moment of inertia of the column section about neutral axis
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Created Width of column in terms of bending stress and eccentric load
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Created Width of column in terms of bending stress and moment due to load
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Verified Compressive strain if the modulus of elasticity and compressive stress is known
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Verified Compressive stress if the modulus of elasticity and compressive strain are known
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Verified Lateral strain in terms of decrease in breadth
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Verified Lateral strain in terms of decrease in depth
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Verified Longitudinal strain in terms of poisson's ratio
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Verified Modulus of elasticity if normal stress and corresponding strain is known
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Verified Permissible stress if factor of safety is known
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Verified Shear stress if modulus of rigidity and shear strain is known
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Verified Tensile strain if the modulus of elasticity and tensile stress are known
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Verified Tensile stress if the modulus of elasticity and tensile strain are known
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Verified Ultimate stress if factor of safety is known
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8 More Relationship Between Stress and Strain Calculators
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Verified Electrode tip diameter
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3 More Resistance spot welding parameters for mild steels Calculators
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Verified Maximum Reduction in Thickness Possible
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Verified Pressure acting on the rolls from entry side
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Verified Pressure acting on the rolls in exit region
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Verified Pressure considering rolling similar to plane-strain-upsetting process
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Verified Projected Area
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Verified Projected Length
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Verified Total Elongation of Stock
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11 More Rolling process Calculators
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Created Coefficient of Friction between the cylinder and the surface of inclined plane if cylinder is rolling without slipping down
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Created Moment of Inertia of a solid sphere about its diameter
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Created Moment of inertia of a circular disc about an axis through its center and perpendicular to its plane
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Created Moment of inertia of a circular ring about an axis through its center and perpendicular to its plane
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Created Moment of Inertia of a right circular hollow cylinder about its axis
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Created Moment of Inertia of a right circular solid cylinder about its symmetry axis
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Created Moment of Inertia of a rod about an axis through its center of mass and perpendicular to rod
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Created Moment of Inertia of a spherical shell about its diameter
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2 More Rotational Motion Calculators
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Created Distance of the outermost layer from neutral axis in terms of maximum moment of resistance
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Created Distance of the outermost layer from neutral axis in terms of section modulus
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Created Maximum moment of resistance
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Created Maximum moment of resistance in terms of section modulus
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Created Maximum stress if maximum moment of resistance and section modulus is given
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Created Maximum stress if maximum moment of resistance is known
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Created Moment of inertia about neutral axis in terms of maximum moment of resistance
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Created Moment of inertia about neutral axis in terms of section modulus
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Created Section modulus
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Created Section modulus in terms of maximum moment of resistance
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Verified Axial/ Thrust Load When (Fa/Fr)<=e
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Verified Axial/ Thrust Load When (Fa/Fr)>e
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Verified Equivalent Dynamic Load When (Fa/Fr)<=e
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Verified Equivalent Dynamic Load When (Fa/Fr)>e
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Verified Factor Y1 When (Fa/Fr)<=e
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Verified Factor Y2 When (Fa/Fr)>e
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Verified Radial Load When (Fa/Fr)<=e
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Verified Radial Load When (Fa/Fr)>e
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Verified Signal current in the base
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33 More Series Generator Calculators
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Created Area of the section above considered level
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Created Distance of C.G of the area(above considered level) from neutral axis
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Created Moment of the inertia of section about neutral axis
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Created Shear force at the section
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Created Shear force at the section if shear area is known
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Created Shear stress at the section
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Created Width of the beam at considered level
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Created Area of the flange(area above the considered section)
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Created Distance of C.G of the area(area above the considered section)of flange from neutral axis
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Created Distance of the considered section from neutral axis if shear stress in the flange is given
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Created Distance of the considered section from neutral axis(for the lower edge of flange)
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Created Distance of the considered section from neutral axis(for the upper edge of flange)
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Created Inner length of the I-section if shear stress for the lower edge of flange is given
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Created Moment of inertia of section for I-section
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Created Moment of inertia of the I-section if shear stress for the lower edge of flange is given
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Created Outer length of I-section if shear stress in the flange is known
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Created Outer length of the I-section if shear stress for the lower edge of flange is given
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Created Shear force distribution in the I-section(for the lower edge of flange)
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Created Shear force in the flange for I-section
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Created Shear stress distribution in the I-section(for the lower edge of flange)
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Created Shear stress in the flange for I-section
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Created Width of the section if area of the flange(area above the considered section)is known
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Created Distance of considered level from neutral axis(at junction of top of web)
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Created Maximum shear force(at neutral axis)
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Created Maximum shear stress(at neutral axis)
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Created Moment of inertia of section if maximum shear stress and force is known
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Created Moment of inertia of section if shear stress at the junction of top of web is known
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Created Moment of inertia of section if shear stress of web is known
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Created Moment of the flanged area about neutral axis
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Created Moment of the shaded area of web about neutral axis
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Created Shear force in the web
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Created Shear force(at junction of top of web)
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Created Shear stress in the web
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Created Shear stress(at junction of top of web)
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Created Thickness of the web
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Created Thickness of web if maximum shear stress and force is known
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Created Thickness of web if shear stress at the junction of top of web is known
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Created Thickness of web if shear stress of web is known
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Created Width of section if moment of flange area about neutral axis is known
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Created Width of section if shear stress at the junction of top of web is known
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Verified Blank Size for Drawing Operation
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Verified Clearance Between Two Shears
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Verified Drawing Force for Cylindrical shells
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Verified Ironing Force after drawing
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Verified Mean diameter of the shell after ironing
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Verified Punching Force for Holes Smaller Than Sheet Thickness
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Verified Stripping force
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Verified Thickness of shell before ironing
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17 More Sheet Metal Operations Calculators
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Verified C.O.P. of air cycle for given power input and tonnage of refrigeration
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Verified C.O.P. of simple air cycle
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Verified Compression Work
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Verified Expansion Work
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Verified Heat rejected during cooling process
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Verified Mass of air to produce Q tonnes of refrigeration
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Verified Power required for refrigeration system
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Verified Refrigeration Effect Produced
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4 More Simple Air Cooling System Calculators
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Verified C.O.P. of air cycle for given power input and tonnage of refrigeration
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Verified Mass of air to produce Q tonnes of refrigeration
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3 More Simple Air Evaporative Cooling System Calculators
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Created Frequency of oscillation for SHM
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Created Frequency of SHM for compound pendulum
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Created Minimum periodic time of SHM for compound pendulum
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Created Periodic time for SHM
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Created Periodic time of SHM for compound pendulum in terms of radius of gyration
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Created Restoring torque for simple pendulum
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4 More Simple Harmonic Motion Calculators
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Verified Finite resistance between drain and source
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Verified Signal current in the emitter in terms of the input signal
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Verified Transconductance in terms of collector current
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Verified Transconductance in terms of process transconductance parameter in NMOS
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Verified Transconductance in terms of process transconductance parameter in PMOS
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Verified Transconductance when process transconductance parameter and drain current are given
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Verified Transconductance when process transconductance parameter and drain current are given in PMOS
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Verified Transconductance, when process transconductance parameter and overdrive voltage are given in NMOS
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Verified Transconductance, when process transconductance parameter and overdrive voltage are given in PMOS
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Verified Voltage gain in terms of a single component of the drain voltage
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Verified Voltage gain in terms of load resistance
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Verified Voltage gain in terms of the small-signal
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Verified Voltage gain in terms of transconductance
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Verified Voltage gain in terms of transconductance and load resistance
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35 More Small-Signal Operation and Models Calculators
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Verified Capacitance of circuit from sparking time
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Verified Frequency of discharge
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Verified Inductance of circuit from sparking time
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Verified Sparking time
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Verified Sparking time from frequency of discharge
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Sphere (1)
Created Curved Surface Area of Sphere
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1 More Sphere Calculators
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Verified Axial Force When Fa/Fr<=e
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Verified Axial Force When Fa/Fr>e
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Verified Constant Y1 When Fa/Fr<=e
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Verified Constant Y2 When Fa/Fr>e
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Verified Equivalent Dynamic Load When Fa/Fr<=e
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Verified Equivalent Dynamic Load When Fa/Fr>e
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Verified Radial Force When Fa/Fr<=e
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Verified Radial Force When Fa/Fr>e
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Created Crank Angle
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Created Displacement of the valve from its mid-position
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6 More Steam Engine Valves and Reversing Gears Calculators
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Verified Load applied suddenly, in terms of stress induced by sudden applied load
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Verified Maximum strain energy stored in the body( When the load is applied suddenly)
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Verified Modulus of resilience
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Verified Modulus of resilience if stress induced is given
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Verified Modulus of resilience if total strain energy is given