Calculators Created by Kethavath Srinath

Osmania University (OU), Hyderabad
733
Formulas Created
908
Formulas Verified
208
Across Categories

List of Calculators by Kethavath Srinath

Following is a combined list of all the calculators that have been created and verified by Kethavath Srinath. Kethavath Srinath has created 733 and verified 908 calculators across 208 different categories till date.
Verified B Parameter (Nominal T-method)
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Verified C Parameter (Nominal T-method)
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14 More ABCD Parameter Calculators
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Verified B Parameter (Nominal pi-method)
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Verified C Parameter (Nominal pi-method)
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14 More ABCD Parameter Calculators
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Verified A Parameter (LTL)
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Verified Admittance Using B Parameter (LTL)
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Verified Admittance Using D Parameter (LTL)
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Verified B Parameter (LTL)
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Verified Characteristic Impedance Using B Parameter (LTL)
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Verified Characteristic Impedance Using C Parameter (LTL)
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Verified D Parameter (LTL)
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Verified Impedance Using A Parameter (LTL)
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Verified Impedance Using C Parameter (LTL)
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Verified Length Using A Parameter (LTL)
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Verified Length Using D Parameter (LTL)
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Verified Propagation Constant Using C Parameter (LTL)
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Verified Propagation Constant Using D Parameter (LTL)
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7 More ABCD Value Calculators
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Created Coefficient of Friction When Efficiency of a Trapezoidal Threaded Screw is Given
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Created Coefficient of Friction When Effort in Lowering a Load is Given
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Created Coefficient of Friction When Effort is Given
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Created Coefficient of Friction When Torque Required in Lifting a Load with Acme Tread is Given
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Created Coefficient of Friction When Torque Required in Lowering a Load is Given
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Created Efficiency of Acme Threaded Screw
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Created Effort Required in Lifting a Load with Acme Thread
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Created Effort Required in Lowering a Load
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Created Helix Angle When Effort Required in Lifting a Load with Acme Screw Thread is Given
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Created Helix Angle When Effort Required in Lowering a Load is Given
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Created Helix Angle When Torque Required in Lifting a Load With Acme Screw Thread is Given
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Created Helix Angle When Torque Required in Lowering a Load is Given
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Created Load When Effort Required in Lifting a Load with Acme Screw Thread is Given
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Created Load When Effort Required in Lowering a Load is Given
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Created Load When Torque Required in Lifting a Load with Acme Screw Thread is Given
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Created Load When Torque Required in Lowering a Load is Given
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Created Mean Diameter of Screw When Torque Required in Lowering a Load is Given
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Created Torque Required in Lifting a Load With Acme Screw Thread
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Created Torque Required in Lowering a Load
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Verified Local Sonic or Acoustic velocity at Ambient air conditions
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2 More Air Refrigeration Systems Calculators
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Verified Radius of Gyration of Column when Allowable Compressive Stress for Aluminium Columns is Given
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Verified Transition from Long to Short Column Range
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3 More Allowable Design Loads for Aluminium Columns Calculators
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Verified Allowable Load for Drop Hammer Driven Piles
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5 More Allowable Load on Piles Calculators
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Created Allowable Bearing Pressure when Area of Lowest Column of a Structure is Given
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Created Allowable Bearing Pressure when Full Area of Support is Occupied by Base Plate
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Created Area of foundation of the Lowest Column of a Structure
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Created Base Plate Thickness
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Created Equivalent Cantilever Dimension
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Created Load when Area of Lowest Column of a Structure is Given
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Verified Line Losses Using Area Of X-section(DC 3-wire)
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Verified Power Transmitted Using Area Of X-section(DC 3-wire)
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Verified Volume Of Conductor Material Using Area Of X-section(DC 3-wire)
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4 More Area Of X-Section Calculators
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Verified Length Of Wire Using Area Of X-section(1-phase 3-wire OS)
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Verified Line Losses Using Area Of X-section(1-phase 3-wire OS)
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Verified Load Current Using Area Of X-section(1-Phase 3-Wire OS)
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Verified Maximum Voltage Using Area Of X-section(1-phase 3-wire OS)
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Verified Power Factor Using Area Of X-section(1-phase 3-wire OS)
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Verified Power Transmitted Using Area Of X-section(1-phase 3-wire OS)
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Verified Resistivity Using Area Of X-section(1-phase 3-wire OS)
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Verified RMS Voltage Using Area Of X-Section(1-Phase 3-Wire OS)
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Verified Line Losses Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Verified Maximum Voltage Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Verified Power Factor Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Verified Power Transmitted Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Verified Resistivity Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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Verified RMS Voltage Using Area Of X-section(1-Phase 2-Wire Mid-point Earthed OS)
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3 More Area Of X-Section Calculators
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Verified Angle Of PF Using Area Of X-section(3-phase 4-wire OS)
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Verified Line Losses Using Area Of X-section(3-phase 4-wire OS)
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Verified Maximum Voltage Using Area Of X-section(3-phase 4-wire OS)
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Verified Power Factor Using Area Of X-section(3-phase 4-wire OS)
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Verified Resistivity Using Area Of X-section(3-phase 4-wire OS)
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3 More Area Of X-Section Calculators
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Verified Line Losses Using Area Of X-section(1-phase 2-wire OS)
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Verified Load Current Using Area Of X-Section(1-Phase 2-Wire OS)
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Verified Maximum Voltage Using Area Of X-section(1-phase 2-wire OS)
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Verified Power Factor Using Area Of X-section(1-phase 2-wire OS)
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Verified Power Transmitted Using Area Of X-section(1-phase 2-wire OS)
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Verified RMS Voltage Using Area Of X-Section(1-Phase 2-Wire OS)
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2 More Area Of X-Section Calculators
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Verified Length Of Wire Using Area Of X-section(2-phase 3-wire OS)
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Verified Load Current Using Area Of X-Section(2-phase 3-wire OS)
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Verified Power Factor Using Area Of X-section(2-phase 3-wire OS)
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Verified Power Transmitted Using Area Of X-Section(2-phase 3-wire OS)
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Verified Resistivity Using Area Of X-Section(2-phase 3-wire OS)
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Verified RMS Voltage Using Area Of X-Section(2-phase 3-wire OS)
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Verified Volume Of Conductor Material Using Area Of X-Section(2-phase 3-wire OS)
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2 More Area Of X-Section Calculators
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Verified Length Of Wire Using Area Of X-section(2-phase 4-wire OS)
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Verified Load Current Using Area Of X-section(2-phase 4-wire OS)
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Verified Power Factor Using Area Of X-section(2-phase 4-wire OS)
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Verified Power Transmitted Using Area Of X-Section(2-phase 4-wire OS)
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Verified Resistivity Using Area Of X-Section(2-phase 4-wire OS)
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Verified RMS Voltage Using Area Of X-Section(2-phase 4-wire OS)
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Verified Volume Of Conductor Material Using Area Of X-Section(2-phase 4-wire OS)
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2 More Area Of X-Section Calculators
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Verified Constant Using Area Of X-Section (1-Phase 2-Wire US)
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Verified Length Using Area Of X-Section (1-Phase 2-Wire US)
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Verified Power Factor Using Area Of X-Section (1-Phase 2-Wire US)
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Verified RMS Voltage Using Area Of X-Section (1-Phase 2-Wire US)
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Verified Volume Of Conductor Material Using Area Of X-Section (1-Phase 2-Wire US)
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4 More Area Of X-Section Calculators
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Verified Angle Of PF Using Area Of X-section(3-phase 3-wire OS)
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Verified RMS Voltage Using Area Of X-section(3-phase 3-wire OS)
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6 More Area Of X-Section Calculators
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Created Diameter of the Shaft When Principle Shear Stress is Given
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Created Equivalent Bending Moment When Shaft is Subjected to Fluctuating Loads
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Created Equivalent Torsional Moment When Shaft is Subjected to Fluctuating Loads
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Created Principle Shear Stress(maximum shear stress theory of failure)
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Verified Allowable Load when Safety Factor is Given
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Verified Allowable Load when Safety Factors are Given
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Verified Pile Capacity
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Verified Toe Resistance when Allowable Load and Safety Factor is Given
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1 More Axial Load Capacity of Single Piles Calculators
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Verified Allowable Compression Stress when Slenderness Ratio is Greater than Cc
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Verified Allowable Compression Stress when Slenderness Ratio is less than Cc
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Verified LRFD Design Strength of Member
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2 More Axially Loaded Steel Columns Design Calculators
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Verified Small signal input resistance in terms of common base current gain
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25 More Basic Configurations Calculators
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Basics (1)
Verified Total Cooling Load due to Equipment
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11 More Basics Calculators
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Beams (3)
Verified Horizontal Shearing Stress in a Rectangular Timber Beam when Notch in the Lower Face
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Verified Modified Total End Shear for Concentrated Loads
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Verified Modified Total End Shear for Uniform Loading
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10 More Beams Calculators
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Created Bending Moment when Cross-Sectional Area of Compressive Reinforcing is Given
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Created Bending Moment when Total Cross-Sectional Area of Tensile Reinforcing is Given
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Created Cross-Sectional Area of Compressive Reinforcing
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Created Total Cross-Sectional Area of Tensile Reinforcing
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Verified COP of Bell-Coleman Cycle for given temperatures, polytropic index(n) and adiabatic index(γ)
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4 More Bell-Coleman Cycle or Reversed Brayton or Joule Cycle Calculators
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Created Braking Torque When Brakes are Applied
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Created Coefficient of Friction When Braking Torque is Given
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Created Normal Reaction Force
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Created Normal Reaction Force When Braking Torque is Given
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Created Permissible Pressure Between the Block and Brake Drum When Normal Reaction is Given
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Created Radius of the Drum Brake When Braking Torque is Given
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2 More Block Brake With Short Shoe Calculators
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Created Core Diameter of Bolt When Maximum Tensile Stress in the Bolt is Given
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Created Core Diameter When Shear Area is Given
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Created Core Diameter When Strength of Bolt in Tension is Given
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Created Core Diameter When the Strength of the Bolt in Shear is Given
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Created Factor of Safety When Strength of Bolt in Tension is Given
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Created Height of Nut When Shear Area is Given
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Created Height of Nut When Strength of Bolt in Shear is Given
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Created Height of Standard Nut
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Created Maximum Tensile Stress in the Bolt
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Created Nominal Diameter of Bolt When Height of Standard Nut is Given
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Created Shear Area of a bolted joint
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Created Strength of Bolt in Tension
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Created Strength of the Bolt in Shear
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Created Tensile Force When Maximum Tensile Stress in the Bolt is Given
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Created Yield Strength in Shear When Strength of Bolt in Shear is Given
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Created Yield Strength in Tension When Strength of Bolt in Tension is Given
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Created Yield Strength in Tension When the strength of the Bolt in Shear is Given
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Verified Beam Effective Depth when Bond Stress on Bar Surface is Given
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Verified Total Shear when Bond Stress on Bar Surface is Given
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2 More Bond and Anchorage for Reinforcing Bars Calculators
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Verified Average Tensile Stress in the Weld
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Verified Efficiency of Welded Joint
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Verified Length of the Weld When Average Tensile Stress in the Weld is Given
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Verified Length of the Weld When Efficiency of the Welded Joint is Given
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Verified Permissible Tensile Stress for the Weld
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Verified Permissible Tensile Stress for the Weld When Efficiency of the Welded joint is Given
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Verified Tensile Force on the Plates in Terms of Thickness of the Plate
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Verified Tensile Force on the Plates When Average Tensile Stress in the Weld is Given
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Verified Tensile Force on the Plates When Efficiency of Welded Joint is Given
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Verified The Throat of the Butt Weld When Average Tensile Stress is Given
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Verified Thickness of the Plate When Efficiency of Welded Joint is Given
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Created Cross-sectional Area of Rod When Strain Energy stored in a Rod is Given
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Created Force Applied on the Rod When Strain Energy Stored in Tension Rod is Given
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Created Length of Shaft When Strain Energy in the Shaft Subjected to External Torque
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Created Length of the Rod When Strain Energy Stored is Given
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Created Length of the Shaft When Strain Energy Stored in the Shaft Subjected to Bending Moment is Given
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Created Modulus of Elasticity of the Rod When Strain Energy Stored is Given
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Created Modulus of Elasticity When Strain Energy Stored in the Shaft Subjected to Bending Moment is Given
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Created Modulus of Rigidity of the Rod When Strain Energy in the Rod is Given
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Created Moment of Inertia of Shaft When Strain Energy Stored in Shaft Subjected to Bending Moment
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Created Polar Moment of Inertia of the Rod When Strain Energy in the Rod is Given
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Created Strain Energy in the Rod When it is Subjected to External Torque
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Created Strain Energy Stored in Tension Rod
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Created Strain Energy Stored in the Rod Subjected to Bending Moment
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Created Torque When Strain Energy in the Rod When Subjected to External Torque is Given
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Created Distance from Neutral Axis to Compressive Reinforcing Steel when Unit Stress is Given
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Created Distance from Neutral Axis to Face of Concrete when Unit Stress is Given
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Created Distance from Neutral Axis to Tensile Reinforcing Steel when Unit Stress is Given
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Created Moment of Inertia of Transformed Beam Section
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Created Moment of Inertia when Unit Stress in Compressive Reinforcing Steel is Given
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Created Moment of Inertia when Unit Stress in Extreme Fiber of Concrete is Given
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Created Moment of Inertia when Unit Stress in Tensile Reinforcing Steel is Given
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Created Total Bending Moment when Unit Stress in Compressive Reinforcing Steel is Given
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Created Total Bending Moment when Unit Stress in Extreme Fiber of Concrete is Given
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Created Total Bending Moment when Unit Stress in Tensile Reinforcing Steel is Given
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Created Unit Stress in Compressive Reinforcing Steel
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Created Unit Stress in Extreme Fiber of Concrete
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Created Unit Stress in Tensile Reinforcing Steel
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Verified Coefficient of Friction at Collar According to Uniform Pressure Theory is Given
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Verified Coefficient of Friction at Collar According to Uniform Wear Theory is Given
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Verified Collar Friction Torque According to Uniform Pressure Theory
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Verified Collar Friction Torque According to Uniform Wear Theory
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Verified Load When Collar Friction Torque According to Uniform Pressure Theory is Given
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Verified Load When Collar Friction Torque According to Uniform Wear Theory is Given
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Verified Nominal Bearing Strength of the Concrete
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Verified Projection of Base Plate Beyond the Flange and Parallel to Web
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Verified Specified Compressive Strength of Concrete when Nominal Bearing Strength is Given
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8 More Column Base Plate Design Calculators
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Verified Concrete Compressive Strength when Total Allowable Axial Load is Given
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Verified Spiral Reinforcement Yield Strength when Spiral Volume to Concrete Core Volume Ratio is Given
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Verified Total Allowable Axial Load for Short Columns
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3 More Columns Calculators
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Verified Allowable Unit Stress on Timber Columns for a Single Member
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Verified Allowable Unit Stress on Timber Columns of Circular Cross Section
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Verified Allowable Unit Stress on Timber Columns of Square or Rectangular Cross Section
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Verified Elasticity Modulus when Allowable Unit Stress of Circular Timber Columns is Given
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Verified Elasticity Modulus when Allowable Unit Stress of Square or Rectangular Timber Columns is Given
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Verified Elasticity Modulus when Allowable Unit Stress on Timber Columns for a Single Member is Given
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Verified Critical Slenderness Ratio for Aluminium Columns
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Verified Critical Slenderness Ratio for Cast Iron Columns
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Verified Ultimate Load per Area for Aluminium Columns
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Verified Ultimate Load per Area for Aluminium Columns
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Verified Ultimate Load per Area for Cast Iron Columns
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Created Axial Load when Maximum Stress For Short Beams is Given
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Created Cross-Sectional Area when Maximum Stress For Short Beams is Given
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Created Deflection for Axial Compression and Bending
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Created Deflection for Transverse Loading when Deflection for Axial Bending is Given
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Created Maximum Bending Moment when Maximum Stress For Short Beams is Given
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Created Maximum Stress For Short Beams
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Created Maximum Stress For Short Beams when Deflection is Large
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Created Neutral Axis Moment of Inertia when Maximum Stress For Short Beams is Given
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Created Neutral Axis to Outermost Fiber Distance when Maximum Stress For Short Beams is Given
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Verified Circle Diameter when Axial Load for Spiral Columns is Given
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Verified Column Diameter when Maximum Permissible Eccentricity for Spiral Columns is Given
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Verified Longitudinal Reinforcement Area when Axial Load for Spiral Columns is Given
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Verified Maximum Permissible Eccentricity for Spiral Columns
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Verified Maximum Permissible Eccentricity for Tied Columns
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8 More Combined Bending and Compression Calculators
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Created Design Strength of an Axially Loaded Composite Column
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Verified Design Strength of Concrete for Direct Bearing
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Created Gross Area of Steel Core when Design Strength of Axially Loaded Composite Column is Given
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1 More Composite Columns Calculators
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Created Axial Force Transmitted by the outer Spring
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Created Cross-Sectional Area of Inner Spring When Axial Force Transmitted is Given
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Created Cross-sectional Area of Outer Spring When Axial Force Transmitted is Given
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Created Cross-sectional Area of the Inner Spring Wire
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Created Cross-sectional Area of the Outer Spring Wire
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Created Diametrical Clearance Between the Springs
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Created Wire Diameter of the Inner Spring When Axial Force Transmitted by the Outer Spring is Given
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Created Wire Diameter of the Inner Spring When Diametrical Clearance Between the Springs is Given
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Created Wire Diameter of the Outer Spring When Axial Force Transmitted by the Outer Spring is Given
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Created Wire Diameter of the Outer Spring When Diametrical Clearance Between the Springs is Given
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1 More Concentric Springs Calculators
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Verified Overturning Moment
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Verified Pressure P1 when Resultant is at Middle Third Edge
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Verified Pressure when Resultant is Outside Middle Third
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Verified Retaining Wall Righting Moment
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3 More Concrete Gravity Retaining Walls Calculators
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Created Negative Moment at Exterior Face of First Interior Support for More Than Two Spans
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Created Negative Moment at Exterior Face of First Interior Support for Two Spans
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Created Negative Moment at Interior Faces of Exterior Support where Support is a Column
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Created Negative Moment at Interior Faces of Exterior Supports where Support is a Spandrel Beam
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Created Negative Moment at Other Faces of Interior Supports
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Created Positive Moment for End Spans if Discontinuous End is Integral with Support
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Created Positive Moment for End Spans if Discontinuous End is Unrestrained
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Created Positive Moment for Interior Spans
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Created Shear Force at All Other Supports
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Created Shear Force in End Members at First Interior Support
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Verified Air infiltration rate into room (CFM)
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Verified Cooling load Heat Gain through windows
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Verified Duct Heat Gain
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Verified Latent cooling load for ventilation air
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Verified Latent Heat Gain per person when Latent Heat Gain from people is given
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Verified Sensible Cooling load due to Equipment
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Verified Sensible Cooling Load due to infiltrating air
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Verified Sensible Cooling load from ventilation air
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Verified Sensible Cooling Load Heat Gain through Structure
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Verified Sensible Heat Gain per people when Sensible Heat Gain from people is given
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Verified Total Cooling Load due to Equipment
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Verified Total heat removed from ventilation air
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8 More Cooling Loads Calculators
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Verified Armature Current Of Series DC Generator Using Converted Power
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Verified Armature Current Of Series DC Generator Using Generated Power
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Verified Armature Current Of Series DC Generator Using Kf
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Verified Armature Current Of Series DC Generator Using Terminal Voltage
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Verified Armature Current Of Series DC Generator Using Torque
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2 More Current Calculators
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Verified Delta Impedance For Delta Connected Load Using Negative Sequence Current
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Verified Delta Impedance For Delta Connected Load Using Positive Sequence Current
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Verified Delta Impedance For Delta Connected Load Using Positive Sequence Voltage
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1 More Delta Impedance Calculators
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Created Axial Force When Tensile Stress in the Shaft is Given
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Created Bending Moment When Bending Stress is Given(Pure Bending)
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Created Bending Stress in the Shaft (Pure Bending Moment)
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Created Bending Stress When Normal Stress is Given
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Created Diameter of Shaft When Tensile Stress in the Shaft is Given
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Created Diameter of Shaft When Torsional Shear Stress in a Shaft is Given(Pure Torsion)
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Created Diameter of the Shaft When Bending Stress is Given(Pure Bending)
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Created Normal Stress When Both Bending and Torsional act on the Shaft
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Created Normal Stress When Principal Shear Stress in the Shaft is Given(Bending & Torsion)
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Created Principal Shear Stress in the Shaft(Bending & Torsion)
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Created Tensile Stress in the Shaft When It is Subjected to Axial Tensile Force
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Created Tensile Stress When Normal Stress is Given
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Created Torsional Moment When Torsional Shear Stress in a Shaft is Given(Pure Torsion)
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Created Torsional Shear Stress in a Shaft(Pure Torsion)
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Created Torsional Shear Stress When Principal Shear Stress in the Shaft is Given
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Created Diameter of the Spring Wire When Mean Stress on the Spring is Given
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Created Diameter of the Spring Wire When Torsional Stress Amplitude is Given
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Created Force Amplitude of the Spring
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Created Force Amplitude When Torsional Stress Amplitude is Given
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Created Maximum Force on the Spring When Mean Force is Given
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Created Maximum Force When Force Amplitude is Given
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Created Mean Coil Diameter When Torsional Stress Amplitude is Given
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Created Mean Diameter of the Coil When Mean Stress on the Spring is Given
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Created Mean Force
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Created Mean Force When Mean Stress on the Spring is Given
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Created Mean Stress on the Spring
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Created Minimum Force on the Spring When Force Amplitude is Given
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Created Minimum Force on the Spring When Mean Force is Given
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Created Shear Stress Correction Factor When Mean Stress on the Spring is Given
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Created Shear Yield Strength (Oil-hardened Tempered Steel Wires)
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Created Shear Yield Strength (Patented and Cold-drawn Steel Wires)
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Created Spring Index When Mean Stress on the spring is Given
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Created Spring Index When Torsional Stress Amplitude is Given
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Created Stress Factor When Torsional Stress Amplitude is Given
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Created Torsional Stress Amplitude
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Created Ultimate Tensile Stress When Shear Yield Strength is Given (Patented and Cold-drawn Steel Wires)
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Created Ultimate Tensile Stress When Shear Yield Strength is Given(Oil-hardened Tempered Steel Wires)
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Created Brake Drum Rotational Angle When Work Done by the Brake is Given
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Created Braking Torque When Work Done by the Brake is Given
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Created Final Velocity When Kinetic Energy Absorbed by the Brakes is Given
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Created Initial Angular Velocity of the Body When Kinetic Energy of the Rotating Body is Given
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Created Initial Velocity of the System When Kinetic Energy Absorbed by the Brakes is Given
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Created Kinetic Energy Absorbed by the Brake
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Created Kinetic energy of a Rotating Body
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Created Mass of the System When Kinetic Energy Absorbed by the Brakes is Given
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Created Mass of the System When Kinetic Energy of Rotating Body is Given
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Created Mass of the System When Potential Energy Absorbed During Braking Period is Given
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Created Moment of Inertia of the System When Kinetic Energy of the Rotating Body is Given
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Created Potential Energy Absorbed During Braking Period
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Created Total Energy Absorbed by the Brake
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2 More Design of Brakes Calculators
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Created Angle of Twist of Hollow Shaft on Basis oF Torsional Rigidity
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Created Axial Tensile Force When Tensile Stress in the Hollow Shaft is Given
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Created Bending Moment When Bending Stress in Hollow Shaft is Given
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Created Bending Stress in Hollow Shaft
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Created Inner Diameter of Hollow Shaft When Ratio of Diameters is Given
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Created Length of the Shaft When Angle of Twist of Hollow shaft on Basis of Torsional Rigidity is Given
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Created Modulus of Rigidity When Angle of Twist of Hollow Shaft on basis of Torsional Rigidity
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Created Outer Diameter of Hollow Shaft When Angle of Twist is Given(Torsional Rigidity)
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Created Outer Diameter of Hollow Shaft When Bending Stress of Hollow Shaft is Given
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Created Outer Diameter of the Hollow Shaft When Principle Stress is Given
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Created Outer Diameter of the Shaft When Torsional Shear Stress is Given
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Created Outer Diameter When Ratio of Diameters is Given
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Created Principle Stress (Maximum Principle Stress Theory)
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Created Ratio of Diameters When Angle of Twist of Hollow Shaft (Torsional Rigidity) is Given
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Created Ratio of Diameters When Bending Stress of Hollow Shaft is Given
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Created Ratio of Diameters When Principle Stress is Given
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Created Ratio of Diameters When Tensile Stress in Hollow Shaft is Given
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Created Ratio of Diameters When Torsional Shear Stress in a Hollow Shaft is Given
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Created Ratio of Inner Diameter to Outer Diameter
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Created Tensile Stress in a Hollow Shaft When Subjected to Axial Force
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Created Torsional Moment When Angle of Twist on Basis of Torsional Rigidity is Given
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Created Torsional Moment When Torsional Shear Stress in a Hollow Shaft is Given
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Created Torsional Shear Stress When a Shaft is Subjected to Pure Torsional Moment
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Created Compressive Stress in the Key
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Created Diameter of the Shaft When Compressive Stress in the Key is Given
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Created Diameter of the Shaft When Shear Stress in the Key is Given
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Created Length of Key When Compressive Stress in the Key is Given
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Created Length of Key When Shear Stress in the Key is Given
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Created Shear Stress in the Key
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Created Torque Transmitted When Compressive Stress in the Key is Given
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Created Torque Transmitted When Shear Stress in the Key is Given
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Created Width of Key When Compressive Stress in the Key is Given
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Created Width of Key When Shear Stress in the Key is Given
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Created Compressive Stress Of Spigot
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Created Equivalent Stress By Distortion Energy Theory
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Created Factor Of Safety For The bi-axial State Of Stress
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Created Factor Of Safety For The Tri-axial State Of Stress
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Created Permissible Shear Stress For Cotter
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Created Permissible Shear Stress For Spigot
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Created Polar Moment Of Inertia Of Hollow Circular Shaft
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Created Polar Moment Of Inertia Of Solid Circular Shaft
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Created Shear Yield Strength by Maximum Shear Stress Theory
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Created Shear Yield Strength By The Maximum Distortion Energy Theory
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Created Stress Amplitude
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Created Tensile Stress In Spigot
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Verified Axial Force When Direct Compressive Stress is Given
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Verified Axial Force When Transverse Shear Stress is Given
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Verified Axial Load When Transverse Shear Stress at Root of Nut is Given
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Verified Axial Load When Unit Bearing Pressure is Given
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Verified Bearing Area Between Screw and Nut for one Thread
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Verified Core Diameter of Screw When Transverse Shear Stress in a Screw is Given
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Verified Core Diameter of Screw When Unit Bearing Pressure is Given
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Verified Core Diameter When Direct Compressive Stress is Given
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Verified Core Diameter When Torsional Shear Stress is Given
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Verified Direct Compressive Stress of Screw
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Verified Nominal Diameter of Screw When Transverse Shear Stress at the root of Nut is Given
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Verified Nominal Diameter of Screw When Unit Bearing Pressure is Given
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Verified Number of Threads in Engagement With Nut When Transverse Shear Stress at Root of Nut is Given
Go
Verified Number of Threads in Engagement With Nut When Transverse Shear Stress is Given
Go
Verified Thread Thickness at Core Diameter When Transverse Shear Stress is Given
Go
Verified Thread Thickness at Root of Nut When Transverse Shear Stress at Root of Nut is Given
Go
Verified Torsional Moment When Torsional Shear Stress is Given
Go
Verified Torsional Shear Stress of a Screw
Go
Verified Transverse Shear Stress at Root of the Nut
Go
Verified Transverse Shear Stress in a Screw
Go
Verified Unit Bearing Pressure for a Thread
Go
1 More Design of Screw and Nut Calculators
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Created Compressive Stress in the Key
Go
Created Compressive Stress induced in a Square Key due to Transmitted Torque
Go
Created Force on a Key
Go
Created Height of Key When Compressive Stress in the Key is Given
Go
Created Length of Key When Shear Stress in the Plane is Given
Go
Created Length of the Key When Compressive Stress in the Key is Given
Go
Created Shaft Diameter When Compressive Stress in the Key is Given
Go
Created Shaft Diameter When Force on a Key is Given
Go
Created Shear Stress in the Plane
Go
Created Shear Stress in the Plane in terms of Torque Transmitted
Go
Created Torque Transmitted When Compressive Stress in the Key is Given
Go
Created Torque Transmitted When Force on a Keys is Given
Go
Created Width of Key When Shear Stress in the Plane is Given
Go
Verified a-phase EMF Using Positive Sequence Current (LLGF)
Go
Verified a-phase EMF Using Positive Sequence Voltage (LLGF)
Go
Verified Negative Sequence Current Using Negative Sequence Voltage (LLGF)
Go
Verified Negative Sequence Voltage Using Negative Sequence Current (LLGF)
Go
Verified Zero Sequence Current Using Zero Sequence Voltage (LLGF)
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25 More Double L2G Fault Calculators
Go
Created Allowable Load per mm Length of Transverse Fillet Weld
Go
Created Force Acting When Shear Stress-induced in the plane that is inclined at an angle θ is Given
Go
Created Leg of the Weld When Maximum Shear Stress-induced in the Plane is Given
Go
Created Leg of the Weld When Shear Stress-induced in the Plane is Given
Go
Created Leg of Weld When Allowable Lod per mm Length of Transverse Fillet Weld is Given
Go
Created Length of the Weld When Shear Stress-induced in the Plane that is inclined at an Angle θ is Given
Go
Created length of Weld When Maximum Shear Stress-induced in the Plane is Given
Go
Created Maximum Shear Stress-induced in the Plane that is Inclined at an Angle θ
Go
Created Maximum Shear Stress-induced When Allowable Load per mm length of Transverse Fillet Weld is Given
Go
Created Shear Stress-induced in the Plane that is inclined at an Angle θ to the Horizontal
Go
Verified Power developed by synchronous motor
Go
Created Couple When Torsional Shear Stress-induced in the Throat Area of Welds is Given
Go
Created Distance of a point in Weld From Center of Gravity When Torsional Shear Stress-induced is Given
Go
Created Length of Weld When Polar Moment of Inertia of Weld About its Center of Gravity is Given
Go
Created Load acting on the Weld When Primary Stress-induced in Welds is Given
Go
Created Polar Moment of Inertia of all Welds about Center of Gravity When Torsional Shear Stress is Given
Go
Created Polar Moment of Inertia of Welds about its Center of Gravity
Go
Created Primary Shear Stress
Go
Created Throat Area of the Weld When Polar Moment of Inertia of Weld About its Center is Given
Go
Created Throat Area When Primary Shear Stress-induced in the Welds is Given
Go
Created Torsional Shear Stress-induced in the Throat Area of Welds
Go
Created Critical Buckling Load when Deflection in Eccentric Loading is Given
Go
Created Cross-Sectional Area when Radius of Gyration in Eccentric Loading is Given
Go
Created Cross-Sectional Area when Total Stress is Given where Load doesn't lie on a Plane
Go
Created Cross-Sectional Area when Total Unit Stress in Eccentric Loading is Given
Go
Created Deflection in Eccentric Loading
Go
Created Distance from XX to outermost fiber when Total Stress is Given where Load doesn't lie on a Plane
Go
Created Distance from YY to outermost fiber when Total Stress is Given where Load doesn't lie on a Plane
Go
Created Eccentricity w.r.t axis XX when Total Stress is Given where Load doesn't lie on a Plane
Go
Created Eccentricity w.r.t axis YY when Total Stress is Given where Load doesn't lie on a Plane
Go
Created Eccentricity when Deflection in Eccentric Loading is Given
Go
Created Load when Deflection in Eccentric Loading is Given
Go
Created Moment of Inertia About XX when Total Stress is Given where Load doesn't lie on a Plane
Go
Created Moment of Inertia About YY when Total Stress is Given where Load doesn't lie on a Plane
Go
Created Moment of Inertia of Cross-Section when Total Unit Stress in Eccentric Loading is Given
Go
Created Moment of Inertia when Radius of Gyration in Eccentric Loading is Given
Go
Created Neutral Axis to Outermost Fiber Distance when Total Unit Stress in Eccentric Loading is Given
Go
Created Radius of Gyration in Eccentric Loading
Go
Created Total Stress in Eccentric Loading when Load doesn't lie on a Plane
Go
Created Total Unit Stress in Eccentric Loading
Go
Created Total Unit Stress in Eccentric Loading when Radius of Gyration is Given
Go
Verified Maximum Stress For a Circular Cross Section
Go
Verified Maximum Stress For a Rectangular Cross Section
Go
Verified Theoretical Maximum Stress for ANC Code Alloy Steel Tubing
Go
Verified Theoretical Maximum Stress for Secant Code Steels
Go
Created Thickness of Wall for a Hollow Octagon
Go
8 More Eccentric Loads on Columns Calculators
Go
Created Imaginary Force at Center of Gravity When Primary Shear Force is Given
Go
Created Number of Bolts When Primary Shear Force is Given
Go
Created Primary Shear Force of Eccentrically Loaded Bolted Connection
Go
Verified Angular Speed Using Electrical Efficiency Of Dc Motor
Go
Verified Armature Copper Loss Using Overall Efficiency Of Dc Motor
Go
Verified Armature Current Using Electrical Efficiency Of Dc Motor
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Verified Armature Resistance using Overall Efficiency Of Dc Motor
Go
Verified Armature Torque Using Electrical Efficiency Of Dc Motor
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Verified armature torque using mechanical Efficiency Of Dc Motor
Go
Verified Constant Losses Using Overall Efficiency Of Dc Motor
Go
Verified Converted Power Using Electrical Efficiency Of Dc Motor
Go
Verified Converted Power Using Mechanical Efficiency Of Dc Motor
Go
Verified Core Loss Using Overall Efficiency Of Dc Motor
Go
Verified Current Using Overall Efficiency Of Dc Motor
Go
Verified Electrical Efficiency Of Dc Motor
Go
Verified field copper loss using Overall Efficiency Of Dc Motor
Go
Verified input power using Electrical Efficiency Of Dc Motor
Go
Verified Input Power using Overall Efficiency Of Dc Motor
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Verified Mechanical Efficiency Of Dc Motor
Go
Verified Mechanical Loss Using Overall Efficiency Of Dc Motor
Go
Verified Output Power Using Mechanical Efficiency Of Dc Motor
Go
Verified output power using Overall Efficiency Of Dc Motor
Go
Verified Overall Efficiency Of Dc Motor
Go
Verified Shunt Field Current Using Overall Efficiency Of Dc Motor
Go
Verified Torque Using Mechanical Efficiency Of Dc Motor
Go
Verified Total Loss Power Using Overall Efficiency Of Dc Motor
Go
Verified Voltage Using Electrical Efficiency Of Dc Motor
Go
Verified voltage using Overall Efficiency Of Dc Motor
Go
Verified Amount of Compression in the Parts Joined by the Bolt
Go
Verified Elongation of the Bolt Under the Action of Pre-Load
Go
Verified Nominal Diameter of the Bolt When Stiffness of the Bolt is Given
Go
Verified Pre-load When Amount of Compression in the Parts Joined by a Bolt is Given
Go
Verified Pre-load When Elongation of the Bolt is Given
Go
Verified Stiffness of the Bolt
Go
Verified The Resultant Load on the Bolt
Go
Verified Thickness of the Parts Held Together by the Bolt When Stiffness of the Bolt is Given
Go
Verified Young's Modulus of the Bolt When Stiffness of the Bolt is Given
Go
Verified Axial Buckling Load for a Warped Section
Go
Verified Polar Moment of Inertia for Pin Ended Columns
Go
Verified Slenderness Ratio of when Critical Buckling Load for Pin Ended Columns is Given
Go
9 More Elastic Flexural Buckling of Columns Calculators
Go
Created Absolute Value of Moment at Centerline of the Unbraced Beam Segment
Go
Created Absolute Value of Moment at Quarter Point of the Unbraced Beam Segment
Go
Created Absolute Value of Moment at Three-Quarter Point of the Unbraced Beam Segment
Go
Created Critical Bending Coefficient
Go
Created Critical Bending Moment for Simply Supported Open Section Beam
Go
Created Critical Bending Moment in Non-Uniform Bending
Go
Created Minor Axis Moment of Inertia when Critical Bending Moment of Simply Supported Open Beam is Given
Go
Created Shear Elasticity Modulus when Critical Bending Moment of Simply Supported Open Beam is Given
Go
5 More Elastic Lateral Buckling of Beams Calculators
Go
Verified Receiving End Current(ECM)
Go
Verified Sending End Current Using Impedance(ECM)
Go
Verified Sending End Current(ECM)
Go
4 More End Condenser Method Calculators
Go
Verified Equivalent Reactance From Secondary Side When Equivalent Impedance From Secondary Side Is Given
Go
Verified Equivalent Resistance From Secondary Side When Equivalent Impedance From Secondary Side Is Given
Go
2 More Equivalent Resistance From Secondary Side Calculators
Go
Created Bending Stress on Extra Full Length Leaves
Go
Created Deflection at the End of Spring
Go
Created Deflection of the Spring at Load Point
Go
Created Force Applied at the End of Spring When Bending Stress on Extra Full Length Leaves is Given
Go
Created Force Applied at the End of Spring When Force Taken by Extra Full length Leaves is Given
Go
Created Force Applied at the End of the Spring When Deflection at the End of the Spring is Given
Go
Created Force Taken by Extra Full Length Leaves When Force Applied at the End of the Spring is Given
Go
Created Length of Cantilever When Deflection at the End of the Spring is Given
Go
Created Length of Cantilever When Deflection of the Spring at Load Point is Given
Go
Created Length of the Cantilever When Bending Stress on Extra Full Length Leaves is Given
Go
Created Modulus of Elasticity of Leaf When Deflection of Spring at Load Point is Given
Go
Created Modulus of Elasticity When Deflection at the End of the Sprig is Given
Go
Created Number of Extra Full Length Leaves When Bending Stress on Extra Full Length Leaves is Given
Go
Created Number of Extra Full Length Leaves When Deflection at the End of Spring is Given
Go
Created Number of Extra Full Length Leaves When Deflection of Spring at Load Point is Given
Go
Created Number of Graduated Length Leaves When Bending Stress on Extra Full Length Leaves is Given
Go
Created Number of Graduated length leaves When Deflection at the End of Spring is Given
Go
Created Number of Graduated Length Leaves When Force Taken by Extra Full Length Leaves is Given
Go
Created Portion of Force Taken by Extra Full Length When Deflection of Spring at Load Point is Given
Go
Created Thickness of Each Leaf When Bending Stress on Extra Full Length Leaves is Given
Go
Created Thickness of Each Leaf When Deflection at the End of the Spring is Given
Go
Created Width of Each leaf When Bending Stress on Extra Full Length Leaves is Given
Go
Created Width of Each Leaf When Deflection of Spring at Load Point is Given
Go
Created Width of Leaf When Deflection at the end of the Spring is Given
Go
Fault (3)
Verified Delta Impedance For Delta Connected Load Using Negative Sequence Voltage
Go
Verified Star Impedance For Star Connected Load Using Positive Sequence Current
Go
Verified Star Impedance For Star Connected Load Using Zero Sequence Current
Go
35 More Fault Calculators
Go
Verified Roughness coefficient when flow velocity is given
Go
7 More Flow velocity in straight sewers Calculators
Go
Created Absolute Pressure at a Height h
Go
Created Angle of Inclined Manometer When Pressure at a Point is Given
Go
Created Angle of Inclined Manometer When Sensitivity is Given
Go
Created Angle of Jet When Maximum Vertical Elevation is Given
Go
Created Angle of Jet When Time of Flight of Liquid Jet is Given
Go
Created Angle of Jet When Time to Reach the Highest Point is Given
Go
Created Area of Surface Wetted When Center of Pressure is Given
Go
Created Area of the Surface Wetted When Total Hydrostatic Force is Given
Go
Created Bulk Modulus When Velocity Of Pressure Wave Is Given
Go
Created Buoyancy Force
Go
Created Center of pressure
Go
Created Density of the Liquid When Dynamic Pressure is Given
Go
Created Depth of Centroid When Center of Pressure is Given
Go
Created Depth of Centroid When Total Hydrostatic Force is Given
Go
Created Diameter Of Droplet When Pressure Change Is Given
Go
Created Diameter of Pipe When Head Loss due to Laminar Flow is Given
Go
Created Differential pressure between two points
Go
Created Differential pressure-Differential Manometer
Go
Created Discharge through an Elbow meter
Go
Created Distance Between Buoyancy Point and Center of Gravity When Metacenter Height is Given
Go
Created Distance Between Plates When Dynamic Viscosity Of A Fluid Is Given
Go
Created Dynamic Pressure
Go
Created Dynamic Pressure head-pitot tube
Go
Created Dynamic viscosity of fluids
Go
Created Dynamic Viscosity of Gases
Go
Created Dynamic Viscosity of Liquids
Go
Created Efficiency of transmission
Go
Created Experimental determination of Metacentric height
Go
Created Force in direction of jet striking a stationary vertical plate
Go
Created Friction Factor When Frictional Velocity is Given
Go
Created Friction velocity
Go
Created Frictional Factor of Laminar flow
Go
Created Head loss due to Laminar Flow
Go
Created Head Loss When Efficiency of Hydraulic Transmission is Given
Go
Created Height Of Fluid 1 When Differential Pressure Between Two Points Is Given
Go
Created Height Of Fluid 2 When Differential Pressure Between Two Points Is Given
Go
Created Height Of Liquid When Absolute Pressure Of That Liquid Is Given
Go
Created Hydraulic Transmission of Power
Go
Created Initial Velocity of Liquid Jet When Maximum Vertical Elevation is Given
Go
Created Initial Velocity When Time of Flight of the Liquid Jet is Given
Go
Created Initial Velocity When Time to Reach the Highest Point of Liquid is Given
Go
Created Length of Inclined Manometer When Pressure at a Point is Given
Go
Created Length of Pipe When Head loss is Given
Go
Created Mass Density When Velocity Of Pressure Wave Is Given
Go
Created Maximum Vertical Elevation of a Jet Profile
Go
Created Mean Velocity When Frictional Velocity is Given
Go
Created Metacentric Height when Moment of Inertia is Given
Go
Created Metacentric Height When Time Period of Rolling is Given
Go
Created Moment of Inertia about Centroid When Center of Pressure is Given
Go
Created Moment of Inertia of Waterline Area When Metacentric Height is Given
Go
Created Normal Stress 2
Go
Created Pressure Inside the Liquid Drop
Go
Created Pressure Inside the Soap Bubble
Go
Created Pressure using inclined Manometer
Go
Created Pressure Wave Velocity in Fluids
Go
Created Radius of Gyration When Time Period of Rolling is Given
Go
Created Rate of Flow When Head loss In Laminar Flow is Given
Go
Created Rate of Flow When Hydraulic Transmission Power is Given
Go
Created Reynolds Number When Frictional Factor of Laminar Flow is Given
Go
Created Sensitivity of inclined manometer
Go
Created Shear Stress When Dynamic Viscosity Of A Fluid Is Given
Go
Created Specific Weight Of A Liquid When Absolute Pressure Of That liquid At A height is Given
Go
Created Specific Weight Of Fluid 1 When Differential Pressure Between Two Points Is Given
Go
Created Specific Weight Of Fluid 2 When Differential Pressure Between Two Points Is Given
Go
Created Specific Weight of Inclined Manometer Liquid When Pressure at A Point is Given
Go
Created Specific Weight of Liquid When Head loss Due to Laminar Flow is Given
Go
Created Specific Weight of Liquid When Hydraulic Transmission Power is Given
Go
Created Specific Weight of Liquid When Total Hydrostatic Force is given
Go
Created Specific Weight Of The Liquid When Buoyancy Force Is Given
Go
Created Stagnation Pressure head
Go
Created Surface Area When Surface Tension Is Given
Go
Created Surface Energy When Surface Tension Is Given
Go
Created Surface tension
Go
Created Surface Tension Of Liquid Drop When Change In Pressure Is Given
Go
Created Surface Tension Of Soap Bubble When Pressure Change Is Given
Go
Created The diameter Of Soap Bubble When Pressure Change Is Given
Go
Created Theoretical discharge -Venturimeter
Go
Created Theoretical Velocity - Pitot Tube
Go
Created Time of Flight of Jet
Go
Created Time period of Rolling
Go
Created Time to Reach Highest Point
Go
Created Total Hydrostatic force
Go
Created Unstable Equilibrium of a Floating Body
Go
Created U-Tube Manometer equation
Go
Created Variation of y with x in Free Liquid Jet
Go
Created Velocity of Fluid When Dynamic Pressure is Given
Go
Created Velocity Of Moving Plates When Dynamic Viscosity Is Given
Go
Created Viscous Force When Head loss Due to Laminar Flow is Given
Go
Created Volume of the Liquid Displaced When Metacentric Height is Given
Go
Created Volume of the Submerged Object when Buoyancy Force is Given
Go
Created Vorticity
Go
34 More Fluid Mechanics Calculators
Go
Verified Allowable Compressive Stress Parallel to Grain for Long Columns
Go
4 More Forest Products Laboratory Recommendations Calculators
Go
Verified Correction Factor Nq for Rectangle
Go
Verified Correction Factor Ny for Rectangle
Go
Verified Maximum Soil Pressure
Go
8 More Foundation Stability Analysis Calculators
Go
Verified Area Of X-Section(2-Phase 4-Wire OS)
Go
Verified Constant(2-Phase 4-Wire OS)
Go
Verified Load Current(2-Phase 4-Wire OS)
Go
Verified Resistance(2-Phase 4-Wire OS)
Go
4 More Four Wire Calculators
Go
Verified Constant(3-Phase 4-Wire OS)
Go
Verified Line Losses(3-Phase 4-Wire OS)
Go
Verified Maximum Voltage(3-Phase 4-Wire OS)
Go
Verified Power Transmitted(3-Phase 4-Wire OS)
Go
Verified Resistance(3-Phase 4-Wire OS)
Go
3 More Four Wire Calculators
Go
Verified Machining Time for a Plunge-Grinder
Go
Verified Material Removal Rate in Cylindrical and Internal Grinder
Go
Verified Material Removal Rate in Horizontal and Vertical Spindle Surface-Grinder
Go
Verified Material Removal Rate in the Plunge-Grinder
Go
Verified Traverse Speed for Cylindrical and in Internal-Grinder when MRR is Given
Go
Verified Traverse Speed in Horizontal and Vertical Spindle Surface-Grinder when MRR is Given
Go
4 More Grinding Operation Calculators
Go
Verified Allowable Design Load on Rock Socket
Go
Verified Socket Length when Allowable Design Load on Rock Socket is Given
Go
4 More Group of Piles Calculators
Go
Created Black bodies heat exchange by radiation
Go
Created Convective processes heat transfer coefficient
Go
Created Heat Exchange By Radiation Due To Geometric Arrangement
Go
Created Heat flux
Go
Created Heat transfer
Go
Created Non Ideal Body Surface Emittance
Go
Created One dimensional heat flux
Go
Created Thermal resistance in convection heat transfer
Go
7 More Heat Transfer Calculators
Go
Created Axial Deflection of the Spring Due to Axial Load When Stiffness of the Spring is Given
Go
Created Axial Spring Force When Stiffness of the Spring is Given
Go
Created Diameter of Spring Wire When Load Stress Equation is Given
Go
Created Diameter of the Wire When Spring Index is Given
Go
Created Inside Diameter of the Spring Coil When Mean Coil Diameter is Given
Go
Created Load Stress Equation
Go
Created Mean Coil Diameter
Go
Created Mean Coil Diameter When Spring Index is Given
Go
Created Outside Diameter of the Spring Coil When Mean Coil Diameter is Given
Go
Created Solid Length of the Spring
Go
Created Spring Index
Go
Created Spring Index When Load Stress Equation is Given
Go
Created Stiffness of the Spring
Go
Created Total Number of Coils When Solid Length of the Spring is Given
Go
Created Bending Moment Applied on the Spring When Bending Stress is Given
Go
Created Bending Stress in the Spring
Go
Created Diameter of the Spring Wire When Bending Stress in the Spring is Given
Go
Created Diameter of the Spring Wire When Stiffness of Helical Torsion Spring is Given
Go
Created Mean Coil Diameter When Stiffness of Helical Torsion Spring is Given
Go
Created Modulus of Elasticity When Stiffness of Helical Torsion Spring is Given
Go
Created Number of Coils of the Spring When Stiffness of Helical Torsion Spring is Given
Go
Created Stiffness of Helical Torsion Spring
Go
Created Stress Concentration Factor When Bending Stress in the Spring is Given
Go
Verified Characteristic Impedance For Incident Waves
Go
Verified Incident Current
Go
Verified Incident Voltage
Go
Verified Incident Voltage Using Reflected And Transmitted Voltage
Go
1 More Incident Wave Calculators
Go
Verified Specific Gravity of the Material when Absolute Volume of the Component is Given
Go
2 More Job Mix Concrete Volume Calculators
Go
K (5)
Verified Length Of Wire Using K(Two-Wire One Conductor Earthed)
Go
Verified Line Losses Using K(Two-Wire One Conductor Earthed)
Go
Verified Maximum Voltage Using K(Two-Wire One Conductor Earthed)
Go
Verified Power Transmitted Using K(Two-Wire One Conductor Earthed)
Go
Verified Volume Using K(Two-Wire One Conductor Earthed)
Go
1 More K Calculators
Go
K (2)
Verified Line Losses Using Constant(DC 3-wire)
Go
Verified Volume Of Conductor Material Using Constant(DC 3-wire)
Go
4 More K Calculators
Go
K (4)
Verified Area Of X-Section Using Constant (1-Phase 2-Wire US)
Go
Verified Power Transmitted Using Constant (1-Phase 2-Wire US)
Go
Verified RMS Voltage Using Constant (1-Phase 2-Wire US)
Go
Verified Volume Of Conductor Material Using Constant (1-Phase 2-Wire US)
Go
7 More K Calculators
Go
Verified c-phase Current Using Fault Impedance (LLF)
Go
Verified c-phase Voltage Using c-phase Current (LLF)
Go
Verified Fault Impedance Using b-phase Current (LLF)
Go
Verified Fault Impedance Using c-phase Current (LLF)
Go
Verified Negative Sequence Current(LLF)
Go
13 More L2L Fault Calculators
Go
Verified Horizontal Subgrade Reaction Coefficient when Characteristic Pile Length is Given
Go
Verified Pile Stiffness when Characteristic Pile Length for Laterally Loaded Piles is Given
Go
5 More Laterally Loaded Vertical Piles Calculators
Go
Verified Length Of Line Using Line Losses(Two-Wire One Conductor Earthed)
Go
Verified Maximum Voltage Using Line Losses(Two-Wire One Conductor Earthed)
Go
Verified Resistance Using Line Losses(Two-Wire One Conductor Earthed)
Go
Verified Transmitted Power Using Line Losses(Two-Wire One Conductor Earthed)
Go
3 More Line Losses Calculators
Go
Verified Area Of X-section Using Line Losses(Two-Wire Mid-point Earthed)
Go
Verified Resistivity Using Line Losses(Two-Wire Mid-point Earthed)
Go
5 More Line Losses Calculators
Go
Verified Area Of X-section Using Line Losses(DC 3-wire)
Go
Verified Resistance Using Line Losses(DC 3-wire)
Go
Verified Resistivity Using Line Losses(DC 3-wire)
Go
4 More Line Losses Calculators
Go
Verified Area Of X-Section Using Line Losses (1-Phase 2-Wire US)
Go
Verified Power Transmitted Using Line Losses (1-Phase 2-Wire US)
Go
9 More Line Losses Calculators
Go
Verified Constant Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Verified Length Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Verified Load Current Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Verified Maximum Voltage Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Verified Power Factor Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Verified Power Transmitted Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Verified Resistance Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Verified Resistivity Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Verified RMS Voltage Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
Verified Volume Of Conductor Material Using Line Losses (1-Phase 2-Wire Mid-Point OS)
Go
1 More Line Losses Calculators
Go
Verified Constant Using Line Losses (1-Phase 2-Wire OS)
Go
Verified Length Using Line Losses (1-Phase 2-Wire OS)
Go
Verified Load Current Using Line Losses (1-Phase 2-Wire OS)
Go
Verified Maximum Voltage Using Line Losses (1-Phase 2-Wire OS)
Go
Verified Power Factor Using Line Losses (1-Phase 2-Wire OS)
Go
Verified Power Transmitted Using Line Losses (1-Phase 2-Wire OS)
Go
Verified Resistance Using Line Losses (1-Phase 2-Wire OS)
Go
Verified Resistivity Using Line Losses (1-Phase 2-Wire OS)
Go
Verified RMS Voltage Using Line Losses (1-Phase 2-Wire OS)
Go
Verified Volume Of Conductor Material Using Line Losses (1-Phase 2-Wire OS)
Go
1 More Line Losses Calculators
Go
Verified Area Of X-Section Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Constant Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Length Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Load Current Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Maximum Voltage Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Power Factor Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Power Transmitted Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Resistance Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Resistivity Using Line Losses (2-Phase 4-Wire OS)
Go
Verified RMS Voltage Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Volume Of Conductor Material Using Line Losses (2-Phase 4-Wire OS)
Go
Verified Area Of X-Section Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Constant Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Length Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Load Current Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Maximum Voltage Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Power Factor Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Power Transmitted Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Resistance Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Resistivity Using Line Losses (1-Phase 3-Wire OS)
Go
Verified RMS Voltage Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Volume Of Conductor Material Using Line Losses (1-Phase 3-Wire OS)
Go
Verified Area Of X-Section Using Line Losses (2-Phase 3-Wire OS)
Go
Verified Length Using Line Losses (2-Phase 3-Wire OS)
Go
Verified Maximum Voltage Using Line Losses (2-Phase 3-Wire OS)
Go
Verified Power Factor Using Line Losses (2-Phase 3-Wire OS)
Go
Verified Resistance Using Line Losses (2-Phase 3-Wire OS)
Go
Verified Resistivity Using Line Losses (2-Phase 3-Wire OS)
Go
Verified RMS Voltage Using Line Losses (2-Phase 3-Wire OS)
Go
Verified Transmitted Power Using Line Losses (2-Phase 3-Wire OS)
Go
1 More Line Losses Calculators
Go
Verified Area Of X-Section Using Line Losses (2-Phase 3-Wire US)
Go
Verified Length Using Line Losses (2-Phase 3-Wire US)
Go
Verified Maximum Voltage Using Line Losses (2-Phase 3-Wire US)
Go
Verified Power Factor Using Line Losses (2-Phase 3-Wire US)
Go
Verified Resistance Using Line Losses (2-Phase 3-Wire US)
Go
Verified Resistivity Using Line Losses (2-Phase 3-Wire US)
Go
Verified RMS Voltage Using Line Losses (2-Phase 3-Wire US)
Go
Verified Transmitted Power Using Line Losses (2-Phase 3-Wire US)
Go
1 More Line Losses Calculators
Go
Verified Transmitted Power Using Load Current(Two-Wire One Conductor Earthed)
Go
1 More Load Current Calculators
Go
Verified Area Of X-Section Using Load Current (1-Phase 2-Wire US)
Go
Verified Line Losses Using Load Current (1-Phase 2-Wire US)
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Verified Maximum Voltage Using Load Current (1-Phase 2-Wire US)
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Verified Power Factor Using Load Current (1-Phase 2-Wire US)
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Verified Power Transmitted Using Load Current (1-Phase 2-Wire US)
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5 More Load Current Calculators
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Verified Area Of X-Section Using Load Current (1-Phase 2-Wire OS)
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Verified Constant Using Load Current (1-Phase 2-Wire OS)
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Verified Length Using Load Current (1-Phase 2-Wire OS)
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Verified Line Losses Using Load Current (1-Phase 2-Wire OS)
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Verified Maximum Voltage Using Load Current (1-Phase 2-Wire OS)
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Verified Power Factor Using Load Current (1-Phase 2-Wire OS)
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Verified Power Transmitted Using Load Current (1-Phase 2-Wire OS)
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Verified Resistance Using Load Current (1-Phase 2-Wire OS)
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Verified Resistivity Using Load Current (1-Phase 2-Wire OS)
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Verified RMS Voltage Using Load Current (1-Phase 2-Wire OS)
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Verified Volume Of Conductor Material Using Load Current (1-Phase 2-Wire OS)
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Verified Constant Using Load Current (1-Phase 2-Wire Mid-Point OS)
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Verified Length Using Load Current (1-Phase 2-Wire Mid-Point OS)
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Verified Line Losses Using Load Current (1-Phase 2-Wire Mid-Point OS)
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Verified Maximum Voltage Using Load Current (1-Phase 2-Wire Mid-Point OS)
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Verified Power Factor Using Load Current (1-Phase 2-Wire Mid-Point OS)
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Verified Power Transmitted Using Load Current (1-Phase 2-Wire Mid-Point OS)
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Verified Resistance Using Load Current (1-Phase 2-Wire Mid-Point OS)
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Verified Resistivity Using Load Current (1-Phase 2-Wire Mid-Point OS)
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Verified RMS Voltage Using Load Current (1-Phase 2-Wire Mid-Point OS)
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Verified Volume Of Conductor Material Using Load Current (1-Phase 2-Wire Mid-Point OS)
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1 More Load Current Calculators
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Verified Area Of X-Section Using Load Current (2-Phase 4-Wire OS)
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Verified Constant Using Load Current (2-Phase 4-Wire OS)
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Verified Length Using Load Current (2-Phase 4-Wire OS)
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Verified Line Losses Using Load Current (2-Phase 4-Wire OS)
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Verified Maximum Voltage Using Load Current (2-Phase 4-Wire OS)
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Verified Power Factor Using Load Current (2-Phase 4-Wire OS)
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Verified Power Transmitted Using Load Current (2-Phase 4-Wire OS)
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Verified Resistance Using Load Current (2-Phase 4-Wire OS)
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Verified Resistivity Using Load Current (2-Phase 4-Wire OS)
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Verified RMS Voltage Using Load Current (2-Phase 4-Wire OS)
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Verified Volume Of Conductor Material Using Load Current (2-Phase 4-Wire OS)
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Verified Area Of X-Section Using Load Current (1-Phase 3-Wire OS)
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Verified Constant Using Load Current (1-Phase 3-Wire OS)
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Verified Length Using Load Current (1-Phase 3-Wire OS)
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Verified Line Losses Using Load Current (1-Phase 3-Wire OS)
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Verified Maximum Voltage Using Load Current (1-Phase 3-Wire OS)
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Verified Power Factor Using Load Current (1-Phase 3-Wire OS)
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Verified Power Transmitted Using Load Current (1-Phase 3-Wire OS)
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Verified Resistance Using Load Current (1-Phase 3-Wire OS)
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Verified Resistivity Using Load Current (1-Phase 3-Wire OS)
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Verified RMS Voltage Using Load Current (1-Phase 3-Wire OS)
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Verified Volume Of Conductor Material Using Load Current (1-Phase 3-Wire OS)
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Verified Load Current In Each Outer (2-phase 3-wire OS)
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Verified RMS Voltage Using Load Current (2-phase 3-wire OS)
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3 More Load Current Calculators
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Verified Angle Of PF Using Load Current (3-phase 4-wire OS)
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Verified Maximum Voltage Using Load Current (3-phase 4-wire OS)
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Verified Power Factor Using Load Current (3-phase 4-wire OS)
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Verified Power Transmitted Using Load Current (3-phase 4-wire OS)
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1 More Load Current Calculators
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Verified Maximum Voltage Using Load Current(3-phase 3-wire OS)
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4 More Load Current Calculators
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Verified Angle Of PF Using Load Current (1-phase 3-wire US)
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Verified Maximum Voltage Using Load Current (1-phase 3-wire US)
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3 More Load Current Calculators
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Verified Load Reduction Factor when the Ends of the Column are Fixed
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Verified Radius of Gyration for Fixed End Columns when Load Reduction Factor is Given
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Verified Radius of Gyration for Single Curvature Bent Member when Load Reduction Factor is Given
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3 More Long Columns Calculators
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Verified Admittance Using Characteristic Impedance (LTL)
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Verified Admittance Using Propagation Constant (LTL)
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Verified Capacitance Using Surge Impedance (LTL)
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Verified Characteristic Impedance (LTL)
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Verified Characteristic Impedance Using Sending End Current (LTL)
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Verified Characteristic Impedance Using Sending End Voltage (LTL)
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Verified Impedance Using Characteristic Impedance (LTL)
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Verified Impedance Using Propagation Constant (LTL)
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Verified Inductance Using Surge Impedance (LTL)
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Verified Propagation Constant (LTL)
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Verified Receiving End Angle (LTL)
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Verified Receiving End Angle Using Hyperbolic Sine(LTL)
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Verified Receiving End Current Using Sending End Current (LTL)
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Verified Receiving End Current Using Sending End Voltage (LTL)
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Verified Receiving End Voltage Using Sending End Current (LTL)
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Verified Receiving End Voltage Using Sending End Voltage (LTL)
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Verified Sending End Current (LTL)
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Verified Sending End Voltage (LTL)
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Verified Surge Impedance (LTL)
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Created Inner Diameter of Cylinder When Thickness of Boiler Shell is Given
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Created Internal Pressure When Thickness of Boiler Shell is Given
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Created Permissible Tensile Stress for Cylinder when Thickness of Boiler Shell is Given
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Created Thickness of Boiler Shell
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Created Power Transmitted
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Created Thickness Of Cotter Joint
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11 More Machine Design Calculators
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Verified Average Material Removal Rate using Uncut Chip Cross-Section Area
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Verified Average Material Removal Rate when Depth of Cut is Given
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Verified Average Material Removal Rate when Depth of Cut is Given for Boring Operation
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Verified Cross-sectional Area of the Uncut Chip
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Verified Cutting Speed Angle When Resultant Cutting Speed is Given
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Verified Depth of Cut in Slab Milling when Tool Engagement Angle is Given
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Verified Energy per Unit Material Removal when Efficiency of Motor Drive System is Given
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Verified Feed in Slab Milling when Feed Speed is Given
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Verified Feed Rate for Turning Operation when Machining Time is Given
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Verified Feed Speed in Vertical Milling when Maximum Chip Thickness is Given
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Verified Feed Speed of the Workpiece in Slab Milling
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Verified Length of Approach for Drilling Operation
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Verified Length of Cut when Machining Time is Given
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Verified Machining Power when Overall Efficiency is Given
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Verified Machining Time For Drilling Operation
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Verified Machining Time For Milling Operation
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Verified Machining Time For Shaping Operation
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Verified Machining Time For Turning Operation
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Verified Material Removal Rate during Drilling Operation
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Verified Material Removal Rate during Drilling Operation when Enlarging an Existing Hole
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Verified Material Removal Rate during Drilling Operation when Feed is Given
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Verified Maximum Chip Thickness in Vertical Milling
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Verified Maximum Chip Thickness obtained in Slab Milling when Depth of Cut is Given
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Verified Maximum Chip Thickness obtained in Slab Milling when Tool Engagement Angle is Given
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Verified Mean Cutting Speed
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Verified Minimum Length of Approach required in Face Milling
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Verified Minimum Length of Approach required in Slab Milling
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Verified Overall Efficiency of Machine Tool and Motor Drive System
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Verified Power required for Machining Operation
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Verified Resultant Cutting Velocity
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Verified Tool Engagement Angle in Slab Milling when Depth of Cut is Given
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2 More Machine tools and machine operations Calculators
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Verified Depth of cut in terms of Machining time for maximum power
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Verified Diameter of the workpiece terms of Machining time for maximum power
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Verified Length of Workpiece in terms of Machining time for maximum power
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Verified Machining time for maximum power in Turning
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Verified Power available for Machining in terms of Machining time for maximum power
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Verified Specific cutting energy in terms of Machining time for maximum power
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Verified Volume of material to be removed when Machining time for maximum power is given
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51 More Maximum Power Condition Calculators
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Created Diameter of the Shaft When Permissible Value of Maximum Principle Stress is Given
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Created Factor of Safety When Permissible Value of Maximum Principle Stress is Given
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Created Permissible Value of Maximum Principle Stress
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Created Permissible Value of Maximum Principle Stress in terms of Factor of Safety
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Created Yield Stress in Shear When Permissible Value of Maximum Principle Stress is Given
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Created Bending Moment When Principle Shear Stress is Given
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Created Diameter of the Shaft When Principle Shear Stress is Given
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Created Equivalent Bending Moment
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Created Factor of Safety When Permissible Value of Maximum Shear Stress is Given
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Created Permissible Value of Maximum Shear Stress
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Created Principle Shear Stress
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Created Torsional Moment When Equivalent Bending Moment is Given
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Created Torsional Moment When Principle Shear Stress is Given
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Created Yield Strength in Shear (maximum shear Stress theory)
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Verified Area of Shear
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Verified Chip Thickness
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Verified chip thickness when cutting ratio is given
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Verified Cross Sectional area of Uncut chip When Specific Cutting energy in machining is given
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Verified Cutting force when rate of energy consumption during machining is given
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Verified Cutting Force When Specific Cutting Energy in machining is given
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Verified Cutting Ratio
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Verified Cutting Ratio when Shear Angle of Continuous chip is given
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Verified Cutting Speed When Rate of energy Consumption during Machining is given
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Verified Density of Workpiece when Thickness of Chip is given
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Verified Force required to remove the Chip and acting on the Tool Face
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Verified length of the chip when thickness of chip is given
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Verified Length of the Shear Plane of Chip
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Verified Mass of the chip when thickness of chip is given
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Verified metal removal rate when specific cutting energy is given
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Verified Plowing Force when Force required to remove the Chip
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Verified Rate of Energy Consumption during Machining
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Verified Rate of Energy Consumption during Machining When Specific Cutting Energy is given
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Verified Resultant cutting Force when Force required to remove the Chip is given
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Verified Shear Angle of Continuous Chip Formation
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Verified Shear Strength of Material on the Shear PLane
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Verified specific cutting energy in machining
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Verified Total Shear force by the tool
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Verified Undeformed Chip Thickness When Cutting Ratio is Given
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Verified Undeformed Chip Thickness When Length of Shear Plane of Chip is Given
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Verified Width of the Chip when Thickness of Chip is given
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Created Modulus of Elasticity of Concrete in SI Units
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Created Modulus of Elasticity of Concrete in USCS Units
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Created Modulus of Elasticity of Normal Weight and Density Concrete in SI Units
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Created Modulus of Elasticity of Normal Weight and Density Concrete in USCS Units
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1 More Modulus of Elasticity of Concrete Calculators
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Verified Differential input signal of the non-inverting configuration
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36 More MOS Field-Effect Transistors (MOSFETs) Calculators
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Created Bending Stress in the Plate(Extra Full Length)
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Created Bending Stress in the Plate(Graduated-length Leaves)
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Created Bending Stress on the Graduated Length Leaves
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Created Deflection at the Load Point (Graduated Length Leaves)
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Created Force applied at the end of Spring
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Created Force Applied at the End of Spring When Bending Stress on the Graduated Length Leaves is Given
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Created Force Applied at the End of Spring When Force Taken by Graduated length Leaves is Given
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Created Force Taken by Extra Full Length Leaves in Terms of Number of Leaves
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Created Force Taken by Full length Leaves When Force at the end of the Spring is Given
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Created Force Taken by Graduated Length Leaves in Terms of Force Applied at the End of the Spring
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Created Force Taken by Graduated length leaves in terms of Number of Leaves
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Created Force Taken by the Full Length Leaves When Bending Stress in the Plate(Extra Full Length) is Given
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Created Force Taken by the Graduated length Leaves When Bending Stress in the Plate is Given
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Created Force Taken by the Graduated length Leaves When Deflection at the Load Point is Given
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Created Force Taken by the Graduated Length Leaves When Force Applied at the End of the Spring is Given
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Created Length of Cantilever When Bending Stress in the Plate is Given
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Created Length of Cantilever When Bending Stress in the Plate(Extra Full Length) is Given
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Created Length of Cantilever When Bending Stress on the Graduated Length Leaves is Given
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Created Length of Cantilever When Deflection at the Load Point(Graduated Length Leaves) is Given
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Created Modulus of Elasticity of leaf When Deflection at the Load Point (Graduated Length Leaves) is Given
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Created Number of Extra Full Length Leaves When Bending Stress on Graduated Length Leaves is Given
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Created Number of Extra Full Length Leaves When Force Taken by Graduated Length Leaves is Given
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Created Number of Extra Full Length Leaves When Force Taken by Graduated Length Leaves is Given
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Created Number of Full Length Leaves When Bending Stress in the Plate(Extra Full Length) is Given
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Created Number of Graduated length leaves When Bending Stress in the Plate is Given
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Created Number of Graduated length Leaves When Bending Stress on the Graduated Length Leaves is Given
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Created Number of Graduated length leaves When Deflection at Load Point (Graduated-Length Leaves) is given
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Created Number of Graduated length leaves When Force Taken by Graduated length Leaves is Given
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Created Thickness of each Leaf Bending Stress in the Plate(Extra Full Length) is Given
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Created Thickness of each Leaf When Bending Stress in the Plate is Given
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Created Thickness of Each Leaf When Bending Stress on Graduated Length Leaves is Given
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Created Thickness of Each Leaf When Bending Stress on Graduated Length Leaves is Given
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Created Thickness of each Leaf When Deflection at the Load Point (Graduated Length Leaves) is Given
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Created Width of Each Leaf When Bending Stress in the Plate is Given
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Created Width of Each Leaf When Bending Stress in the Plate(Extra Full Length) is Given
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Created Width of Each Leaf When Bending Stress on Graduated Length Leaves is Given
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Created Width of Each Leaf When Deflection at the Load Point(Graduated Length Leaves) is Given
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Created Force Applied at the End of Spring
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Created Force Applied at the End of the Spring When Pre-Load Required to Close the Gap is Given
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Created Initial Nip in the Leaf Spring
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Created Initial Pre-Load Required to Close the Gap
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Created Length of Cantilever When Initial Nip of Leaf Spring is Given
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Created Modulus of Elasticity When Initial Nip of the Spring is Given
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Created Number of Full Length Leaves When Initial Pre-load Required to Close the Gap is Given
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Created Number of Graduated length Leaves When Initial Pre-Load Required to Close the Gap is Given
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Created Thickness of Each Leaf When Initial Nip of the Leaf Spring is Given
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Created Total Number of Leaves When Pre-Load Required to Close the Gap is Given
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Created Total Number of Springs When Initial Nip of the Leaf Spring is Given
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Created Width of Each Leaf When Initial Nip of Leaf Spring is Given
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Verified Load Current Using Losses (Nominal pi-method)
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Verified Losses Using Transmission Efficiency (Nominal pi-method)
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Verified Receiving End Angle Using Transmission Efficiency (Nominal pi-method)
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Verified Receiving End Current Using Sending End Power (Nominal pi-method)
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Verified Receiving End Voltage Using Sending End Power (Nominal pi-method)
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Verified Receiving End Voltage Using Transmission Efficiency (Nominal pi-method)
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Verified Sending End Power Using Transmission Efficiency (Nominal pi-method)
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13 More Nominal pi-method Calculators
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Verified Capacitive Current (Nominal T-method)
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Verified Capacitive Voltage Using Sending End Voltage (Nominal T-method)
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Verified Impedance Using Capacitive Voltage (Nominal T-method)
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Verified Impedance Using Sending End Voltage (Nominal T-method)
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Verified Losses Using Sending End Power (Nominal T-method)
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Verified Receiving End Angle Using Sending End Power (Nominal T-method)
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Verified Receiving End Current (Nominal T-method)
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Verified Receiving End Current Using Losses (Nominal T-method)
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Verified Receiving End Current Using Sending End Power (Nominal T-method)
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Verified Receiving End Voltage Using Sending End Power (Nominal T-method)
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9 More Nominal T-method Calculators
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Verified a-phase EMF Using Zero Sequence Impedance (1OC)
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Verified Negative Sequence Impedance Using Negative Sequence Voltage (1OC)
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Verified Negative Sequence Voltage Using Negative Sequence Impedance (1OC)
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Verified Positive Sequence Potential Difference Using Potential Difference Between a-Phase (1OC)
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Verified Positive Sequence Voltage Using Positive Sequence Impedance
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Verified Potential Difference Between a-Phase Using Positive Sequence Potential Difference (1OC)
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Verified Potential Difference Between a-Phase Using Zero Sequence Potential Difference (1OC)
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Verified Potential Difference Between b-Phase (1OC)
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Verified Zero Sequence Impedance Using Zero Sequence Voltage (1OC)
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Verified Zero Sequence Potential Difference Using Potential Difference Between a-Phase (1OC)
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Verified Zero Sequence Voltage Using Zero Sequence Impedance (1OC)
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16 More One conductor open Calculators
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Verified Allowable Load per mm Length of the Weld
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Verified Force When Stress induced in the Plane is Given
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Verified Leg of the Weld When Shear Stress in the Fillet Weld is Given
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Verified Leg of the Weld When Shear Stress-induced in the Plane is Given
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Verified Leg of the Weld When Throat of the Weld is Given
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Verified Length of the Weld When Shear Stress-induced in the Plane is given
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Verified Length of Weld When Shear Stress in the Fillet Weld is Given
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Verified Maximum Shear Stress-induced in the Plane When Parallel Fillet Weld is Subjected to Force
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Verified Shear Stress in the Fillet Weld
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Verified Shear Stress induced in the Plane When Parallel Fillet weld is Subjected to a Force
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Verified Tensile Force on the Plate When Shear Stress in the Fillet is Given
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Verified Throat of the Weld
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Created Width of the Plane in Double Parallel Fillet Weld
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Verified Photon’s Momentum when Wavelength is Given
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7 More Photoelectric Effect Calculators
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Created Coefficient of Friction When Efficiency of Square Threaded Screw is Given
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Created Core Diameter of Power Screw
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Created Efficiency of Square Threaded Screw
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Verified External Torque Required to Raise The Load in Terms of Efficiency
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Created Helix Angle of Thread
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Created Lead of Screw When Helix angle is Given
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Verified Lead of the Screw When Overall Efficiency is Given
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Verified load When Overall Efficiency is Given
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Created Maximum Efficiency of Square Threaded Screw
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Created Mean Diameter of Power Screw
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Created Mean diameter of Screw When Helix Angle is Given
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Created Nominal Diameter of Power Screw
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Created Nominal Diameter of Power Screw When Mean DIameter is Given
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Verified Overall Efficiency of a Power Screw
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Created Pitch of Power Screw
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Created Pitch of the Screw When Mean Diameter is Given
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Verified Radiation energy emitted by a black body per unit time and surface area
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6 More Radiation Calculators
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Verified B Using Reactive End Reactive Power Component
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Verified B Using Reactive End Real Power Component
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Verified Reactive End Reactive Power Component
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Verified Reactive End Real Power Component
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Created Bending Moment when Stress in Concrete is Given
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Created Depth of Beam when Stress in Concrete is Given
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Created Depth of Heavy Beams and Girders
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Created Depth of Light Beams
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Created Depth of Roof and Floor Slabs
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Created Stress in Concrete
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Created Stress in Steel
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Created Stress in Steel When Cross-Sectional Reinforcing Tensile Area to Beam Area Ratio is Given
Go
Created Width of Beam when Stress in Concrete is Given
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Verified Critical Molar Volume of real gas using Redlich–Kwong equation in terms of a only
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40 More Redlich–Kwong Model of Real Gas Calculators
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Verified Characteristic Impedance For Reflected Waves
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Verified Characteristic Impedance Using Reflected Current
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Verified Incident Voltage Using Reflected Current
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Verified Incident Voltage Using Reflected Voltage
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Verified Load Impedance Using Reflected Voltage
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Verified Reflected Current
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Verified Reflected Current Using Incident And Transmitted Current
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Verified Reflected Current Using Load Impedance
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Verified Reflected Voltage
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Verified Reflected Voltage Using Incident And Transmitted Voltage
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3 More Reflected Waves Calculators
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Verified Incident Current Using Reflection Coefficient Of Current
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Verified Reflected Current Using Reflection Coefficient Of Current
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Verified Reflection Coefficient For Current
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1 More Reflection Coefficient For Current Calculators
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Verified Incident Voltage Using Reflection Coefficient Of Voltage
Go
Verified Reflected Voltage Using Reflection Coefficient Of Voltage
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Verified Reflection Coefficient For Voltage
Go
Verified Reflection Coefficient Of Current Using Reflection Coefficient Of Voltage
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Verified Resistivity Using Resistance(Two-Wire One Conductor Earthed)
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2 More Resistance Calculators
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Verified Area Of X-Section Using Resistance (2-phase 3-wire OS)
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Verified Length Of Wire Using Resistance (2-phase 3-wire OS)
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2 More Resistance Calculators
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Verified Area Of X-Section Using Resistance (3-phase 4-wire OS)
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Verified Resistivity Using Resistance (3-phase 4-wire OS)
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1 More Resistance Calculators
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Verified Area Of X-Section Using Resistance (1-Phase 2-Wire US)
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Verified Constant Using Resistance (1-Phase 2-Wire US)
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Verified Length Using Resistance (1-Phase 2-Wire US)
Go
Verified Line Losses Using Resistance (1-Phase 2-Wire US)
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5 More Resistance Calculators
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Created Crushing Resistance of Plates per Pitch Length
Go
Created Diameter of the Rivet When Margin of a Rivet is Given
Go
Created Length of Rivet Shank
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Created Length of Shan Portion necessary to form the Closing Head
Go
Created Length of Shank Portion necessary to Form the Closing Head When Length of Rivet Shank is Given
Go
Created Margin of a Rivet
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Created Number of Rivets Per Pitch When Crushing Resistance of Plates is Given
Go
Created Permissible Compressive Stress of Plate Material When Crushing Resistance of Plates is Given
Go
Created Permissible Shear Stress for Rivet When Shear Resistance of Rivet Per Pitch Length is Given
Go
Created Permissible Shear Stress for Rivet(for a Single Shear)
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Verified Permissible Tensile Stress of Plate When Tensile Resistance of the Plate between two Rivets is Given
Go
Created Pitch of Rivet
Go
Created Pitch of Rivets When Tensile Resistance of the Plate between two Rivets is Given
Go
Created Shank Diameter of Rivet When Crushing Resistance of Plates is Given
Go
Created Shank Diameter of Rivet When Shear Resistance of Rivet per Pitch is Given
Go
Created Shank Diameter of the Rivet When Pitch of Rivet is Given
Go
Created Shear Resistance of Rivet per Pitch Length
Go
Created Shear Resistance of Rivet Per Pitch Length (for Double Shear)
Go
Created Shear Resistance of Rivet Per Pitch Length (for Single Shear)
Go
Created Tensile Resistance of the Plate between two Rivets
Go
Created Thickness of plate 1 When Length of Rivet Shank is Given
Go
Created Thickness of Plate 2 When Length of Rivet Shank is Given
Go
Created Thickness of Plate When Tensile Resistance of the Plate between two Rivets is Given
Go
Created Thickness of Plates When Crushing Resistance is Given
Go
Created Transverse Pitch (for Zig-Zag riveting)
Go
Created Transverse Pitch of Rivet (Chain Riveting)
Go
3 More Riveted Joints Calculators
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Verified Deflection for Channel or Z Bar when Load in Middle
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Verified Deflection for Channel or Z Bar when Load is Distributed
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Verified Deflection for Deck Beam when Load in Middle
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Verified Deflection for Hollow Cylinder when Load in Middle
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Verified Deflection for Hollow Cylinder when Load is Distributed
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Verified Deflection for Hollow Rectangle When Load is Distributed
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Verified Deflection for Solid Cylinder when Load in Middle
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Verified Deflection for Solid Cylinder When Load is Distributed
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Verified Greatest Safe Load for Channel or Z Bar when Load in Middle
Go
Verified Greatest Safe Load for Channel or Z Bar when Load is Distributed
Go
Verified Greatest Safe Load for Deck Beam when Load in Middle
Go
Verified Greatest Safe Load for Deck Beam when Load is Distributed
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Verified Greatest Safe Load for Even Legged Angle when Load in Middle
Go
Verified Greatest Safe Load for Hollow Rectangle When Load is Distributed
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Verified Greatest Safe Load for Solid Cylinder When Load is Distributed
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17 More Rolling and Moving Loads Calculators
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Verified Receiving End Angle Using Sending End Power(ECM)
Go
Verified Receiving End Current Using Sending End Power(ECM)
Go
Verified Receiving End Power Using Sending End Power(ECM)
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3 More Sending End Power Calculators
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Created Combined Stiffness of 2 Springs When Connected in Parallel
Go
Created Combined Stiffness of 3 Springs When Connected in Parallel
Go
Created Combined Stiffness of Three Springs Connected in Series
Go
Created Combined Stiffness of Two Springs Connected in Series
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Verified Angular Speed Of Series DC Motor Using Kf
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Verified Angular Speed Of Series DC Motor Using Output Power
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Verified Armature Current Of Series DC Motor Using Input Power
Go
Verified Armature Current Of Series DC Motor Using Kf
Go
Verified Armature Current Of Series DC Motor Using Speed
Go
Verified Armature Current Of Series DC Motor Using Torque
Go
Verified Armature Current Of Series DC Motor Using Voltage
Go
Verified Armature Induced Voltage Of Series DC Motor Using Kf
Go
Verified Armature Induced Voltage Of Series DC Using Voltage
Go
Verified Armature Resistance Of Series DC Motor Using Voltage
Go
Verified Input Power Of Series DC Motor
Go
Verified K of Series DC Motor Using Speed
Go
Verified Kf of Series DC Motor Using Armature Induced Voltage
Go
Verified Kf Of Series DC Motor Using Torque
Go
Verified Magnetic Flux Of Series DC Motor Using Kf
Go
Verified Magnetic Flux Of Series DC Motor Using Speed
Go
Verified Magnetic Flux Of Series DC motor Using Torque
Go
Verified Output Power Of Series DC Motor
Go
Verified Series Field Resistance Of Series DC Motor Using Speed
Go
Verified Series Field Resistance Of Series DC Motor Using Voltage
Go
Verified Speed Of Series DC Motor
Go
Verified Torque Of Series DC Motor Using Kf
Go
Verified Torque Of Series DC Motor Using Output Power
Go
Verified Voltage Equation Of Series DC Motor
Go
Verified Voltage Of Series DC Motor Using Input Power
Go
Verified Voltage Of Series DC Motor Using Speed
Go
Verified Airgap Power Of Series Generator Using Km
Go
Verified Angular Speed Of Series DC Generator Using Generated Power
Go
Verified Angular Speed Of Series DC Generator Using Kf
Go
Verified Angular Speed Of Series DC Generator Using Torque
Go
Verified Armature Resistance Of Series DC Generator Using Voltage
Go
Verified Converted Power Of Series DC Generator
Go
Verified Converted Power Of Series DC Generator Using Input Power
Go
Verified Core Losses Of Series DC Generator Using Converted Power
Go
Verified Kf Of Series DC Generator
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Verified Kf Of Series DC Generator Using Torque
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Verified Km Of Series Generator
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Verified Km Of Series Generator Using Angular Speed
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Verified Km Of Series Generator Using Armature Current
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Verified Km Of Series Generator Using Terminal Voltage
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Verified Km Of Series Generator Using Torque
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Verified Load Power Of Series DC Generator
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Verified Magnetic flux Of Series DC Generator Using Kf
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Verified Magnetic flux Of Series DC Generator Using Torque
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Verified mechanical Losses Of Series DC Generator Using Converted Power
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Verified Power Generated By A Series DC Generator
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Verified Series Field Resistance Of Series DC Generator Using Terminal Voltage
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Verified The Stray Losses Of Series DC Generator Using Converted Power
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Verified Torque Of Series DC Generator Using Angular Speed And Armature Current
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Verified Torque Of Series DC Generator Using Generated Power
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Verified Torque Of Series DC Generator Using Input Power
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Verified Torque Of Series DC Generator Using Kf
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Verified Voltage Of Series Generator
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7 More Series Generator Calculators
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Verified Shaft Resistance Stress by Empirical Procedure
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1 More Shaft Resistance in Cohesionless Soils Calculators
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Verified Ultimate Resistance for Cohesive and Cohesionless Soils
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Verified Weight of shaft when ultimate resistance is given
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3 More Shaft Settlement Calculators
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Created Cross-Sectional Area of Web Reinforcement
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Created Effective Depth of Beam when Shearing Unit Stress in a Reinforced Concrete Beam is Given
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Created Effective Depth when Cross-Sectional Area of Web Reinforcement is Given
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Created Shear Carried by Concrete when Cross-Sectional Area of Web Reinforcement is Given
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Created Shearing Unit Stress in a Reinforced Concrete Beam
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Created Stirrups Spacing when Cross-Sectional Area of Web Reinforcement is Given
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Created Total Shear when Cross-Sectional Area of Web Reinforcement is Given
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Created Total Shear when Shearing Unit Stress in a Reinforced Concrete Beam is Given
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Created Width of Beam when Shearing Unit Stress in a Reinforced Concrete Beam is Given
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Verified Blank size when there is corner radius on punch (15r ≤ d ≤ 20r)
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Verified Blank size when there is corner radius on punch (10r ≤ d ≤ 15r)
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Verified Blank size when there is corner radius on punch (d < 10r)
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Verified Percent reduction after drawing
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21 More Sheet Metal Operations Calculators
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Verified Smallest Moment of Inertia Allowable at Worst Section for Low Carbon Steel
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Verified Smallest Moment of Inertia Allowable at Worst Section for Medium Carbon Steel
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2 More Short Columns Calculators
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Verified Allowable Bond Stress for Horizontal Tension Bars of Sizes and Deformations Conforming to ASTM A 408
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1 More Short Columns with Ties Calculators
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Verified Impedance (STL)
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Verified Receiving End Angle Using Receiving End Power (STL)
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Verified Receiving End Angle Using Transmission Efficiency (STL)
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Verified Receiving End Current Using Impedance (STL)
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Verified Receiving End Current Using Sending End Angle (STL)
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Verified Receiving End Current Using Transmission Efficiency (STL)
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Verified Receiving End Power (STL)
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Verified Receiving End Voltage Using Impedance (STL)
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Verified Receiving End Voltage Using Losses (STL)
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Verified Receiving End Voltage Using Receiving End Power (STL)
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Verified Receiving End Voltage Using Transmission Efficiency (STL)
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Verified Receiving End Voltage Using Voltage Regulation (STL)
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Verified Resistance Using Transmission Efficiency (STL)
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Verified Sending End Angle Using Losses (STL)
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Verified Sending End Angle Using Sending End Power (STL)
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Verified Sending End Angle Using Transmission Efficiency (STL)
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Verified Sending End Current Using Losses (STL)
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Verified Sending End Current Using Sending End Power (STL)
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Verified Sending End Current Using Transmission Efficiency (STL)
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Verified Sending End Power (STL)
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Verified Sending End Voltage Using Impedance (STL)
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Verified Sending End Voltage Using Power Factor(STL)
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Verified Sending End Voltage Using Transmission Efficiency (STL)
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Verified Sending End Voltage Using Voltage Regulation (STL)
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Verified Transmission Efficiency (STL)
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Verified Voltage Regulation (STL)
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8 More Short Transmission Lines Calculators
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Verified Angular Speed Of DC Shunt Motor Using Kf
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Verified Angular Speed Of DC Shunt Motor Using Output Power
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Verified Armature Conductors Of DC Shunt Motor Using K
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Verified Armature Current Of Shunt DC Motor Using Input Power
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Verified Armature Current Of Shunt DC Motor Using The Torque
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Verified Armature Current Of Shunt DC Motor Using Voltage
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Verified Armature Parallel Path Of Shunt DC Motor Using K
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Verified Armature Resistance Of Shunt DC Motor Using Voltage
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Verified Back Emf Of Shunt DC Motor Using Motor Speed
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Verified Full Load Speed Of Shunt DC Motor
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Verified Induced Back EMF Of DC Shunt Motor Using kf
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Verified Induced Back EMF Shunt DC Motor Using Voltage
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Verified Input Power Of Shunt DC Motor
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Verified K Of Shunt DC Motor
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Verified K Using Speed Of Shunt DC Motor
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Verified Kf Of DC Shunt Motor
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Verified Kf Of DC Shunt Motor Using Torque
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Verified Magnetic Flux Of DC Shunt Motor Using Kf
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Verified Magnetic flux Of DC Shunt Motor Using Torque
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Verified Magnetic Flux using Speed of Shunt DC Motor
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Verified Maximum Power Condition Of Shunt DC Motor
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Verified No Load Speed Of Shunt DC Motor
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Verified Number Of Pole Of Shunt DC Motor Using K
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Verified Output Power Of Shunt DC Motor
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Verified Shunt DC Motor Speed Using Back Emf
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Verified Shunt Field Current Of Shunt DC Motor
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Verified Shunt Field Resistance Of Shunt DC Motor Using The Shunt Field Current
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Verified Speed Regulation Of Shunt DC Motor
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Verified Torque Of DC Shunt Motor Using Kf
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Verified Torque Of DC Shunt Motor Using Output Power
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Verified Voltage Of Shunt DC Motor
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Verified Voltage Of Shunt DC Motor Using Input Power
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Verified Voltage Of Shunt DC Motor Using Shunt Field Current
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Verified Specific heat capacity at constant pressure
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1 More Simple Air Cooling System Calculators
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Created Angle of Rotation of Arbor With Respect to the Drum
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Created Bending Moment due to Force When Maximum Bending Stress induced in the Spring is Given
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Created Bending Moment due to the Force
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Created Bending Moment due to the Force When Angle of Rotation of Arbor With Respect to the Drum is Given
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Created Bending Moment due to the Force When Deflection of one End of Spring is Given
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Created Bending Moment When Strain Energy Stored in the Spring is Given
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Created Deflection of one End of Spring With Respect to Other End
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Created Distance of centre of Gravity of Spiral from outer end When Bending Moment due to Force is Given
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Created Distance of centre of Gravity of Spiral from outer end When Deflection of one End of Spring is Given
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Created Force When Bending Moment Due to that Force is Given
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Created Length of Strip From Outer end to inner End When Angle of Rotation of Arbor is Given
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Created Length of Strip From Outer end to inner End When Deflection of one End of Spring is Given
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Created Length of Strip From Outer end to Inner End When Strain Energy Stored in the Spring is Given
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Created Maximum Bending Stress Induced at the Outer end of the Spring
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Created Modulus of Elasticity of Spring Wire When Strain Energy Stored in the Spring is Given
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Created Modulus of Elasticity When Angle of Rotation of Arbor is Given
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Created Modulus of Elasticity When Deflection of one End of Spring With Respect to Other End is Given
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Created Strain Energy Stored in the Spring
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Created Thickness of the Strip When Angle of Rotation of the Arbor With Respect to Drum
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Created Thickness of the Strip When Deflection of one End of Spring With Respect to Other End is Given
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Created Thickness of the Strip When Maximum Bending Stress Induced at the Outer end of the Spring is Given
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Created Thickness of the Strip When Strain Energy Stored in the Strip is Given
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Created Width of the Strip When Angle of Rotation of Arbor With Respect to the Drum is Given
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Created Width of the Strip When Deflection of one End of Spring is Given
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Created Width of the Strip When Deflection of one End of Spring With Respect to Other End is Given
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Created Width of the Strip When Maximum Bending Stress induced at the Outer End of the Spring is Given
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Created Width of the Strip When Strain Energy Stored in the Spring is Given
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Created Major diameter of of Spline When Mean Radius of Spline is Given
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Created Mean Radius of Splines
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Created Mean Radius of Splines When Torque Transmitting Capacity is Given
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Created Minor Diameter of the Spline When Mean Radius of Spline is Given
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Created Permissible Pressure on Splines When Torque Transmitting Capacity is Given
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Created Torque Transmitting Capacity in Terms of Diameter of Splines
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Created Torque Transmitting Capacity of Splines
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Created Total Area of Splines
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Created Total Area of Splines When Torque Transmitting Capacity is Given
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Verified Length over which Deformation Takes Place when Strain Energy in Shear is Given
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Verified Shear Area when Strain Energy in Shear is Given
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Verified Shear Modulus of Elasticity when Strain Energy in Shear is Given
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Verified Strain Energy in Shear when Shear Deformation is Given
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15 More Strain Energy in Structural Members Calculators
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Verified Bending Stress
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Verified Direct Stress
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Verified Equivalent Bending Moment
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Verified Equivalent Torsional Moment
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Verified Maximum Shearing Stress
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Verified Moment of Inertia about Polar Axis
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Verified Moment of Inertia for Hollow Circular Shaft
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Verified Rankine's Formula for Columns
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Verified Shear Stress of Circular Beam
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Verified Shearing Stress
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Verified Slenderness Ratio
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Verified Strain Energy due to Torsion in Hollow Shaft
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Verified Strain Energy in Torsion
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Verified Strain Energy in Torsion for Solid Shaft
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Verified Torsional Shear Stress
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Verified Total Angle of Twist
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36 More Strength of Materials Calculators
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Created Deflection of the Spring
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Created Deflection of the Spring When Strain Energy Stored is Given
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Created Diameter of Spring Wire When Deflection in the Spring is Given
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Created Diameter of Spring Wire When Resultant Stress in the Spring is Given
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Created Diameter of the Spring Wire When Rate of Spring is Given
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Created Diameter of the Spring Wire When Shear Stress Correction Factor is Given
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Created Force acting on the Spring When Resultant Stress is Given
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Created Force Applied on the Spring When Deflection in the Spring is Given
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Created Force Applied on the Spring When Strain Energy Stored in the Spring is Given
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Created Mean Coil Diameter When Deflection in the Spring is Given
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Created Mean Coil Diameter When Rate of Spring is Given
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Created Mean Coil Diameter When Resultant Stress in the Spring is Given
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Created Mean Coil diameter When Shear Stress Correction Factor is Given
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Created Modulus of Rigidity When Deflection in the Spring is Given
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Created Modulus of Rigidity When Rate of Spring is Given
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Created Number of Active Coils When Deflection in the Spring is Given
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Created Rate of Spring
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Created Rate of Spring in terms of Deflection
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Created Resultant Stress in the Spring
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Created Shear Stress Correction Factor
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Created Shear Stress Correction Factor in terms of Diameter of Spring Wire
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Created Spring Index When Shear Stress Correction Factor is Given
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Created Strain Energy Stored in the Spring
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Created Stress Factor of the Spring
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Created Angular Frequency of Spring
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Created Mass of the Spring
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Created Mass of the Spring When Natural Angular Frequency of the Spring (One End Free) is Given
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Created Mass of the Spring When Natural Angular Frequency of the Spring is Given
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Created Natural Angular Frequency of the Spring (One End Free)
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Created Stiffness of Spring When Natural Angular Frequency of the Spring (One End Free) is Given
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Created Stiffness of Spring When Natural Angular Frequency of the spring is given
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Verified 3-Phase Input Power Of Synchronous Motor
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Verified 3-Phase Mechanical Power Of Synchronous Motor
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Verified Angel Between Voltage And Armature Current Using 3-phase Input Power
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Verified Angel Between Voltage And Armature Current Using 3-phase Mechanical Power
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Verified Angel Between Voltage And Armature Current using input Power
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Verified Armature Current Of Synchronous Motor Using 3-phase Mechanical Power
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Verified Armature Current Of Synchronous Motor Using Input Power
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Verified Armature Current Of Synchronous Motor Using Mechanical Power
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Verified armature resistance Of Synchronous Motor Using 3-phase Mechanical Power
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Verified Armature Resistance Of Synchronous Motor Using Input Power
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Verified Armature Resistance Of Synchronous Motor Using The Mechanical Power
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Verified Back EMF Of Synchronous Motor Using Ka
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Verified Back EMF Of Synchronous Motor Using Mechanical Power
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Verified Difference Between input and mechanical Power
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Verified Input Power Of The Synchronous Motor
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Verified Ka Of Synchronous Motor Using Back Emf
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Verified Load Current Of Synchronous Motor Using 3-phase Input Power
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Verified Load Current Of Synchronous Motor Using 3-phase Mechanical Power
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Verified Load Voltage Of Synchronous Motor Using 3-phase Input Power
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Verified Load Voltage Of Synchronous Motor Using 3-phase Mechanical Power
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Verified Magnetic Flux Of Synchronous Motor Using Back EMF
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Verified Mechanical Power Of Synchronous Motor
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Verified Mechanical Power Of Synchronous Motor Using Gross Torque
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Verified Mechanical Power Of Synchronous Motor Using Input Power
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Verified Power Factor Of Synchronous Motor Using 3-phase Input Power
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Verified Power Factor Of Synchronous Motor Using 3-phase Mechanical Power
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Verified Power Factor Of Synchronous Motor Using Input Power
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Verified Synchronous Speed Of Synchronous Motor Using ka
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Verified Synchronous Speed Of Synchronous Motor Using Mechanical Power
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Verified Voltage Of Synchronous Motor Using Input Power
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Verified Average Temperature rise of chip from Secondary Deformation
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Verified Length of Heat source per Chip Thickness when Max Temperature rise in Secondary shear zone is given
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Created Maximum temperature in secondary deformation zone
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Verified Maximum Temperature rise in the Chip in the Secondary deformation zone
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Verified Thermal Number when maximum Temperature rise in the Chip in the Secondary Deformation zone is given
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24 More Tempratures in metal cutting Calculators
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Created Tensile Strength of Normal Weight and Density Concrete in SI Units
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Created Tensile Strength of Normal Weight and Density Concrete in USCS Units
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Verified Enthalpy at point 2
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9 More Theoretical Vapour compression cycle with Dry Saturated vapour after compression Calculators
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Verified Area of contact when Total Frictional force in metal cutting is given
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Verified coefficient of friction in metal cutting
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Verified normal force on shear plane of the tool
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Verified normal stress due to tool
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Verified Resultant Tool Force when Shear force on shear plane is given
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Verified shear force on shear plane when shear strength is given
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Created Shear Force on the Shear Plane
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Verified Shear Strength of Material when Total Frictional force in metal cutting is given
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Verified Shear Strength When coefficient of friction in Metal Cutting is Given
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Verified Total frictional force in metal cutting
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Verified Yield pressure when coefficient of friction in metal cutting is given
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Created Newton's law of cooling
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Created Ratio of specific heat
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Created Average speed of gases
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Created Degree of Freedom When Equipartition Energy is Given
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Created Degree of Freedom When Molar Internal Energy Of An Ideal Gas is Given
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Created Entropy When Helmholtz Free Energy is Given
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Created Equipartition energy
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Created Equipartition energy for molecule having n degrees of freedom
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Created Helmholtz free energy
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Created Internal Energy When Helmholtz Free Energy Is Given
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Created Isothermal Compression Of An Ideal Gas
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Created Isothermal Work Done by the gas
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Created Latent heat
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Created Molar internal energy of an ideal gas
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Created Molar Internal Energy of an Ideal Gas
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Created Molar Mass of the Gas When Average Speed of the Gas is Given
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Created Molar Mass of the Gas When Most Probable Speed of the Gas is Given
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Created Molar Mass Of The Gas When RMS Velocity Of The Gas Is Given
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Created Most probable speed
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Created Number of Moles When Internal Energy of Ideal Gas is Given
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Created Pressure
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Created RMS speed
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Created Specific heat
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Created Specific heat at constant volume
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Created Stefan–Boltzmann law
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Created Temperature of Ideal Gas When Internal Energy of the Ideal Gas is Given
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Created Temperature Of The Gas When Average Speed Of Gas Is Given
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Created Temperature Of The Gas When Equipartition energy for molecule is Given
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Created Temperature of the Gas When Equipartition energy is Given
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Created Temperature of the Gas When Most Probable Speed of Gas is Given
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Created Temperature Of The Gas When RMS Velocity Of The Gas Is Given
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Created Temperature When Helmholtz free Energy is Given
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Created Thermal Expansion
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Created Thermal stress of a material
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85 More Thermodynamics Calculators
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Created Core Diameter When Diameter of the Hole is Given
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Created Diameter of the Hole of Bolt
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Created Nominal Diameter of the Bolt When Diameter of the Hole is Given
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Verified c-phase Potential Differences (3oc)
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10 More Three conductors open Calculators
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Verified Maximum Voltage(1-Phase 3-Wire OS)
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Verified Power Transmitted(1-Phase 3-Wire OS)
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6 More Three Wire Calculators
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Verified Area Of X-Section(3-Phase 3-Wire OS)
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Verified Constant(3-Phase 3-Wire OS)
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Verified Load Current(3-Phase 3-Wire OS)
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Verified Maximum Voltage(3-Phase 3-Wire OS)
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Verified Power Transmitted(3-Phase 3-Wire OS)
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Verified Resistance(3-Phase 3-Wire OS)
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2 More Three Wire Calculators
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Verified Area Of X-section(DC 3-wire)
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Verified Constant(DC 3-wire)
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Verified Resistance(DC 3-wire)
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Verified Volume Of Conductor Material (DC 3-wire)
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4 More Three-Wire Calculators
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Verified Constant(2-Phase 3-Wire OS)
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Verified Maximum Voltage(2-Phase 3-Wire OS)
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6 More Three-Wire Calculators
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Verified Quasi Constant Value for Piles in Sands
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2 More Toe Capacity Load Calculators
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Verified Nominal Diameter When Wrench Torque is Given
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Verified Pre-load When Wrench Torque is Given
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Verified Wrench Torque Required to Create the Required Pre-Load
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Created Coefficient of Friction When Effort is Given
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Created Coefficient of Friction When Torque is Given
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Created Effort Required in Lifting a load using Screw
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Created Effort When Torque is Given
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Created Helix angle When Effort is Given
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Created Helix angle When Torque is Given
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Created Load When Effort in Lifting is Given
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Created Load When Torque is Given
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Created Mean Diameter When Torque is Given
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Created Torque Required When Effort is Given
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Created Torque When Load on the Screw is Given
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Created Coefficient of Friction When Load is Given
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Created Coefficient of Friction When Torque Required in Lowering a Load is Given
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Created Effort Required in Lowering a Load
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Created Helix Angle When Effort Required in Lowering load is Given
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Created Helix Angle When Torque Required in Lowering a Load is Given
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Created Load When Effort Required in Lowering Load is Given
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Created Load When Torque Required in Lowering a Load is Given
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Created Mean Diameter of Screw When Torque Required in Lowering a Load is Given
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Created Torque Required in Lowering a Load
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Created Angle of Twist of the Shaft
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Created Length of the Shaft Subjected to Torsional Moment When Angle of Twist is Given
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Created Modulus of Rigidity When angle of Twist is Given
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Created Shaft Diameter When Angle of Twist in the Shaft is Given
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Created Torsional Moment When Angle OF Twist in the Shaft is Given
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Verified Primary Reactance Using Equivalent Reactance From Primary Side
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Verified Secondary Leakage Reactance When Equivalent Reactance From Primary Side Is Given
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36 More Transformer Calculators
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Verified Receiving End Angle Using Transmission Efficiency (Nominal T-method)
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Verified Receiving End Power Using Transmission Efficiency (Nominal T-method)
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Verified Sending End Current Using Transmission Efficiency (Nominal T-method)
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Verified Sending End Voltage Using Transmission Efficiency (Nominal T-method)
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7 More Transmission Efficiency Calculators
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Verified Characteristic Impedance Using Transmitted Voltage
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Verified Incident Voltage Using Transmitted Voltage
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Verified Load Impedance For Transmitted Waves
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Verified Load Impedance Using Transmitted Current
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Verified Transmitted Current
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Verified Transmitted Current Using Incident And Reflected Current
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Verified Transmitted Current Using Incident Current
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Verified Transmitted Voltage
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Verified Transmitted Voltage Using Incident And Reflected Voltage
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Verified Transmitted Voltage Using Incident Current
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3 More Transmitted Or Refracted Waves Calculators
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Verified Length of the weld When Tensile Stress in Transverse Fillet Weld is Given
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Verified Permissible Tensile Stress for the Weld
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Verified Tensile Force on the Plates When Tensile Stress in Transverse Fillet Weld is Given
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Verified Tensile Stress in Transverse Fillet Weld
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Verified Tensile Stress in Transverse Fillet Weld when Leg of Weld is Given
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Verified Thickness of the Plate When Tensile Stress in Transverse Fillet Weld is Given
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Created Coefficient of Friction When Efficiency of Trapezoidal Threaded Screw is Given
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Created Coefficient of Friction When Effort in Lowering a Load is Given
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Created Coefficient of Friction When Effort is Given
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Created Coefficient of Friction When Torque Required in Lifting a Load with Trapezoidal Tread is Given
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Created Coefficient of Friction When Torque Required in Lowering a Load is Given
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Created Efficiency of Trapezoidal Threaded Screw
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Created Effort Required in Lifting a Load with Trapezoidal Screw Thread
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Created Effort Required in Lowering Load using Trapezoidal Threaded Screw
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Created Helix Angle When Effort Required in Lifting a Load with Trapezoidal Screw Thread is Given
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Created Helix Angle When Effort Required in Lowering a Load is Given
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Created Helix Angle When Torque Required in Lifting a Load With Trapezoidal Screw Thread is Given
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Created Helix Angle When Torque Required in Lowering a Load is Given
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Created Load When Effort Required in Lifting a Load with Trapezoidal Screw Thread is Given
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Created Load When Effort Required in Lowering a Load is Given
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Created Load When Torque Required in Lifting a Load with Trapezoidal Screw Thread is Given
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Created Load When Torque Required in Lowering a Load is Given
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Created Mean Diameter of Screw When Torque in lifting a Load with Trapezoidal Thread Screw is Given
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Created Mean Diameter of Screw When Torque Required in Lowering a Load is Given
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Created Torque Required in Lifting a Load With Trapezoidal Screw Thread
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Created Torque Required in Lowering a Load
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Verified Constant (1-Phase 2-Wire US)
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Verified Line Losses (1-Phase 2-Wire US)
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Verified Maximum Voltage(1-Phase 2-Wire US)
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Verified Power Transmitted(1-Phase 2-Wire US)
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Verified Resistance (1-Phase 2-Wire US)
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4 More Two Wire Calculators
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Verified Area Of X-Section(Two-Wire One Conductor Earthed)
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Verified K(Two-Wire One Conductor Earthed)
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Verified Maximum Voltage(Two-Wire One Conductor Earthed)
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Verified Transmitted Power(Two-Wire One Conductor Earthed)
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Verified Volume Of Conductor Material(Two-Wire One Conductor Earthed)
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3 More Two-Wire Calculators
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Verified Maximum Voltage(1-Phase 2-Wire OS)
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Verified Power Transmitted(1-Phase 2-Wire OS)
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Verified Resistance(1-Phase 2-Wire OS)
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5 More Two-Wire Calculators
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Verified Line Losses(Two-Wire Mid-point Earthed)
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Verified Load Current(Two-Wire Mid-point Earthed)
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Verified Maximum Voltage(Two-Wire Mid-point Earthed)
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Verified Power Transmitted(Two-Wire Mid-point Earthed)
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4 More Two-Wire Mid-point Earthed Calculators
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Verified Line Losses(1-Phase 2-Wire Mid-Point Earthed)
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Verified Power Transmitted(1-Phase 2-Wire Mid-Point Earthed)
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6 More Two-Wire Mid-point Earthed Calculators
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Verified 28-day Concrete Compressive Strength when Column Ultimate Strength is Given
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Created Axial-Load Capacity of Short Rectangular Members
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Created Balanced Moment when Load and Eccentricity is Given
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Created Balanced Moment when Φ is Given
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Verified Column Ultimate Strength with Zero Eccentricity of Load
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Created Compressive Reinforcement Area when Axial-Load Capacity of Short Rectangular Members is Given
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Verified Eccentricity of Slender Columns
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Created Tensile Stress in Steel when Axial-Load Capacity of Short Rectangular Members is Given
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Created Tension Reinforcement Area when Axial-Load Capacity of Short Rectangular Members is Given
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Verified Ultimate Strength for No Compression Reinforcement
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Verified Ultimate Strength for Short, Circular Members when Governed by Compression
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Verified Ultimate Strength for Short, Square Members when Governed by Compression
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Verified Ultimate Strength for Symmetrical Reinforcement
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Verified Ultimate Strength for Symmetrical Reinforcement in Single Layers
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Verified Yield Strength of Reinforcing Steel when Column Ultimate Strength is Given
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4 More Ultimate Strength Design of Concrete Columns Calculators
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Verified Depth when the Neutral Axis Lies in the Flange
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Verified Equivalent Rectangular Compressive Stress Distribution Depth
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3 More Ultimate Strength Design of I and T Beams Calculators
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Created Absolute Value of Max Moment in the Unbraced Beam Segment
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Verified Condition for Maximum Moment in Interior Spans of Beams When Plastic Hinge is Formed
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Verified Ultimate Load for Continuous Beam When k is Given
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1 More Ultimate Strength of Continuous Beams Calculators
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Created Bending Moment About Axis XX when Maximum Stress in Unsymmetrical Bending is Given
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Created Bending Moment About Axis YY when Maximum Stress in Unsymmetrical Bending is Given
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Created Distance From Point to XX Axis when Maximum Stress in Unsymmetrical Bending is Given
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Created Distance from YY axis to stress point when Maximum Stress in Unsymmetrical Bending is Given
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Created Maximum Stress in Unsymmetrical Bending
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Verified Moment of Inertia About YY when Maximum Stress in Unsymmetrical Bending is Given
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1 More Unsymmetrical Bending Calculators
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Verified Alpha Parameter Of A Transistor
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Verified Alpha Parameter Of A Transistor Using Beta
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Verified Base current Of A Transistor Using Beta
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Verified Beta Parameter of a Transistor
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Verified Beta Parameter Of A Transistor Using Base Current
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Verified collector current Of A Transistor Using alpha
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Verified Collector current Of A Transistor Using Beta
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Verified Current In A Transistor
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Verified Emitter Current of a Transistor Using Alpha
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Verified Transconductance
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Verified Armature Induced Voltage Of Series DC Generator
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Verified Armature Induced Voltage Of Series DC Generator Using Converted Power
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Verified Armature Induced Voltage Of Series DC Generator Using Generated Power
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Verified Armature Induced Voltage Of Series DC Generator Using Kf
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Verified Terminal Voltage Of Series DC Generator
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2 More Voltage Calculators