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Calculators Created by Saurabh Patil
Saurabh Patil
Shri Govindram Seksaria Institute of Technology and Science
(SGSITS )
,
Indore
695
Formulas Created
32
Formulas Verified
107
Across Categories
List of Calculators by Saurabh Patil
Following is a combined list of all the calculators that have been created and verified by Saurabh Patil. Saurabh Patil has created 695 and verified 32 calculators across 107 different categories till date.
Aircraft Preliminary Weight Built Up
(1)
Created
Velocity at Maximum Endurance given Preliminary Endurance for Prop-Driven Aircraft
Go
20 More Aircraft Preliminary Weight Built Up Calculators
Go
Analysis of Bar
(1)
Created
Elongation of bar given applied tensile load, area and length
Go
1 More Analysis of Bar Calculators
Go
Atom
(1)
Verified
Wavelength of Emitted Radiation for Transition between States
Go
9 More Atom Calculators
Go
Basics
(1)
Verified
Daylight Hours
Go
7 More Basics Calculators
Go
Basics
(1)
Verified
Bending Stress in Beam
Go
1 More Basics Calculators
Go
Bearing Reactions
(12)
Created
Bending stress in crankpin of centre crankshaft at TDC position given reaction on Bearing 1
Go
Created
Distance between Bearing 1 and 2 of centre crankshaft at TDC position given Piston diameter
Go
Created
Force on Crank Pin due to gas pressure inside cylinder
Go
Created
Horizontal Reaction on Bearing 2 of centre crankshaft at TDC position due to belt tension
Go
Created
Horizontal Reaction on Bearing 3 of centre crankshaft at TDC position due to belt tension
Go
Created
Resultant Reaction on Bearing 2 of centre crankshaft at TDC position
Go
Created
Resultant Reaction on Bearing 3 of centre crankshaft at TDC position
Go
Created
Vertical Reaction on Bearing 1 of centre crankshaft at TDC position due to force on crank pin
Go
Created
Vertical Reaction on Bearing 1 of centre crankshaft at TDC position given crankweb dimension
Go
Created
Vertical Reaction on Bearing 2 of centre crankshaft at TDC position due to force on crank pin
Go
Created
Vertical Reaction on Bearing 2 of centre crankshaft at TDC position due to weight of flywheel
Go
Created
Vertical Reaction on Bearing 3 of centre crankshaft at TDC position due to weight of flywheel
Go
Bearing Reactions
(10)
Created
Distance between Bearing 1 and 2 of Side Crankshaft at TDC Position
Go
Created
Horizontal Reaction on Bearing 1 of side crankshaft at TDC position by belt tension given moment
Go
Created
Horizontal Reaction on Bearing 1 of side crankshaft at TDC position due to belt tension
Go
Created
Horizontal Reaction on Bearing 2 of side crankshaft at TDC position due to belt tension
Go
Created
Resultant reaction at Bearing 1 of side crankshaft at TDC position
Go
Created
Resultant reaction at Bearing 1 of side crankshaft at TDC position given bearing pressure
Go
Created
Vertical Reaction on Bearing 1 of side crankshaft at TDC position due to force on crank pin
Go
Created
Vertical Reaction on Bearing 1 of side crankshaft at TDC position due to weight of flywheel
Go
Created
Vertical Reaction on Bearing 2 of side crankshaft at TDC position due to force on crank pin
Go
Created
Vertical Reaction on Bearing 2 of side crankshaft at TDC position due to weight of flywheel
Go
Bearing Reactions
(8)
Created
Horizontal Reaction on Bearing 1 of side crankshaft at max torque due to belt tensions
Go
Created
Horizontal Reaction on Bearing 1 of side crankshaft due to tangential force at max torque
Go
Created
Horizontal Reaction on Bearing 2 of side crankshaft at max torque due to belt tensions
Go
Created
Horizontal Reaction on Bearing 2 of side crankshaft due to tangential force at max torque
Go
Created
Vertical Reaction on Bearing 1 of side crankshaft at max torque due to weight of flywheel
Go
Created
Vertical Reaction on Bearing 1 of side crankshaft due to radial force at max torque
Go
Created
Vertical Reaction on Bearing 2 of side crankshaft at max torque due to weight of flywheel
Go
Created
Vertical Reaction on Bearing 2 of side crankshaft due to radial force at max torque
Go
Bearings Reactions
(18)
Created
Distance between crank pin and centre crankshaft designed at max torque
Go
Created
Force acting on piston top due to gas pressure for maximum torque on center crankshaft
Go
Created
Gap of Bearing 2 from Flywheel of centre crankshaft at max torque position
Go
Created
Gap of Bearing 3 from Flywheel of centre crankshaft at max torque position
Go
Created
Horizontal Reaction on Bearing 1 of centre crankshaft due to tangential force at max torque
Go
Created
Horizontal Reaction on Bearing 2 of centre crankshaft due to belt tension at max torque
Go
Created
Horizontal Reaction on Bearing 2 of centre crankshaft due to tangential force at max torque
Go
Created
Horizontal Reaction on Bearing 3 of centre crankshaft due to belt tension at max torque
Go
Created
Resultant reaction at journal of Bearing 2 of centre crankshaft at max torque given bearing pressure
Go
Created
Resultant Reaction on Bearing 1 of centre crankshaft at angle of max torque
Go
Created
Resultant Reaction on Bearing 2 of centre crankshaft at angle of max torque
Go
Created
Resultant Reaction on Bearing 3 of centre crankshaft at angle of max torque
Go
Created
Tangential component of force at crank pin given horizontal reaction on bearing 1
Go
Created
Tangential component of force at crank pin given horizontal reaction on bearing 2
Go
Created
Vertical Reaction on Bearing 1 of centre crankshaft due to radial force at max torque
Go
Created
Vertical Reaction on Bearing 2 of centre crankshaft due to flywheel weight at max torque
Go
Created
Vertical Reaction on Bearing 2 of centre crankshaft due to radial force at max torque
Go
Created
Vertical Reaction on Bearing 3 of centre crankshaft due to flywheel weight at max torque
Go
Bending Stress in Lever
(5)
Created
Bending stress in lever of elliptical cross section
Go
Created
Bending stress in lever of elliptical cross section given bending moment
Go
Created
Bending stress in lever of rectangular cross section
Go
Created
Bending stress in lever of rectangular cross section given bending moment
Go
Created
Maximum bending moment in lever
Go
Biaxial Stress Deformation System
(2)
Verified
Strain in x direction in biaxial system
Go
Verified
Strain in Y direction in biaxial system
Go
Big and Small End Bearings
(12)
Created
Angular Velocity of Crank given Engine Speed in RPM
Go
Created
Bearing Pressure on Crank Pin Bush
Go
Created
Bearing Pressure on Piston Pin Bush
Go
Created
Crank Radius given Stroke Length of Piston
Go
Created
Mass of Reciprocating Parts in Engine Cylinder
Go
Created
Maximum Force Acting on Crank Pin Bearing given Allowable Bearing Pressure
Go
Created
Maximum Force Acting on Piston Pin Bearing
Go
Created
Maximum Force Acting on Piston Pin Bearing given Allowable Bearing Pressure
Go
Created
Maximum Height of Connecting Rod at Big End
Go
Created
Maximum Height of Connecting Rod at Small End
Go
Created
Minimum Height of Connecting Rod at Big End
Go
Created
Minimum Height of Connecting Rod at Small End
Go
Big End Cap and Bolts
(11)
Created
Bending Moment on Big End Cap of Connecting Rod
Go
Created
Core Diameter of Bolts of Big End Cap of Connecting Rod
Go
Created
Inertia Force on Bolts of Connecting Rod
Go
Created
Mass of Connecting Rod
Go
Created
Maximum Bending Moment on Connecting Rod
Go
Created
Maximum Bending Stress in Big End Cap of Connecting Rod
Go
Created
Maximum Inertia Force on Bolts of Connecting Rod
Go
Created
Maximum Inertia Force on Bolts of Connecting Rod given Permissible Tensile Stress of Bolts
Go
Created
Span Length of Big End Cap of Connecting Rod
Go
Created
Thickness of Big End Cap of Connecting Rod given Bending Stress in Cap
Go
Created
Width of Big End Cap of Connecting Rod given Bending Stress in Cap
Go
Bore and Length of Engine Cylinder
(7)
Created
Bore of Engine Cylinder given Length
Go
Created
Gas Force Acting on Cylinder Cover
Go
Created
Indicated Mean Effective Pressure
Go
Created
Length of Engine Cylinder given Cylinder Bore
Go
Created
Length of Engine Cylinder given Stroke Length
Go
Created
Maximum Gas Pressure Inside Engine Cylinder
Go
Created
Stroke Length of Engine given Length of Cylinder
Go
Buckling of Connecting Rod
(11)
Created
Area Moment of Inertia for Connecting Rod Cross Section
Go
Created
Critical Buckling Load on Connecting Rod by Rankine Formula
Go
Created
Critical Buckling Load on Connecting Rod Considering Factor of Safety
Go
Created
Critical Buckling Load on Steel Connecting Rod given Thickness of Flange or Web of Connecting Rod
Go
Created
Force Acting on Connecting Rod
Go
Created
Height of Cross Section of Connecting Rod at Middle Section
Go
Created
Maximum Force Acting on Connecting Rod given Maximum Gas Pressure
Go
Created
Radius of Gyration of I Cross Section about xx Axis
Go
Created
Radius of Gyration of I Cross Section about yy Axis
Go
Created
Whipping Stress in Connecting Rod of I Cross Section
Go
Created
Width of I Cross Section of Connecting Rod
Go
Concentrating Collectors
(1)
Verified
Inclination of reflectors
Go
22 More Concentrating Collectors Calculators
Go
Cross-Sectional Area of Socket and Spigot
(3)
Created
Cross Section Area of Socket End Resisting Shear Failure
Go
Created
Cross Section Area of Socket of Cotter Joint Prone to Failure
Go
Created
Cross Section Area of Spigot of Cotter Joint Prone to Failure
Go
Cylinder Head and its Studs
(12)
Created
Core Diameter of Studs
Go
Created
Core Diameter of Studs given Nominal Diameter
Go
Created
Maximum Number of Studs for Cylinder Head
Go
Created
Maximum Pitch of Studs for Cylinder Head
Go
Created
Minimum Number of Studs for Cylinder Head
Go
Created
Minimum Pitch of Studs for Cylinder Head
Go
Created
Net Resisting Force Offered by Cylinder Head Studs
Go
Created
Nominal Diameter of Studs
Go
Created
Pitch Circle Diameter of Studs
Go
Created
Pitch Circle Diameter of Studs given Pitch and Number of Studs
Go
Created
Pitch of Englne Cylinder Head Studs
Go
Created
Thickness of Cylinder Head
Go
Depth of Groove
(1)
Created
Depth of Groove given Allowable Static Thrust Load on Ring which is Subject to Shear
Go
3 More Depth of Groove Calculators
Go
Design of Bearings
(14)
Created
Bearing pressure at bearing1 of side crankshaft at TDC position
Go
Created
Bending moment at bearing 1 of side crankshaft at TDC position
Go
Created
Bending moment in shaft at bearing1 of side crankshaft at TDC position
Go
Created
Bending stress in shaft at bearing1 of side crankshaft at TDC position
Go
Created
Diameter of journal at bearing1 of side crankshaft at TDC position
Go
Created
Diameter of shaft at bearing1 of side crankshaft at TDC position
Go
Created
Length of Bearing 1 of Side Crankshaft at TDC Position given Bending Moment at Bearing
Go
Created
Length of bearing1 of side crankshaft at TDC position
Go
Created
Length of crankpin given bending moment at bearing 1 of side crankshaft at TDC position
Go
Created
Maximum length of Bearing 1 of side crankshaft at TDC position given crankpin diameter
Go
Created
Maximum thickness of crankweb given crankpin diameter
Go
Created
Minimum length of Bearing 1 of side crankshaft at TDC position given crankpin diameter
Go
Created
Minimum thickness of crankweb given crankpin diameter
Go
Created
Overhang Distance of piston force from Bearing 1 of side crankshaft at TDC position
Go
Design of Crank Pin
(9)
Created
Bending Moment at centre plane of crank pin of centre crankshaft at TDC position
Go
Created
Bending Moment at centre plane of crankpin of centre crankshaft at TDC position given bending stress
Go
Created
Bending stress in crank pin of centre crankshaft at TDC position given diameter of crank pin
Go
Created
Diameter of crank pin of centre crankshaft at TDC position given allowable bearing pressure
Go
Created
Diameter of crank pin of centre crankshaft at TDC position given bending stress and bending moment
Go
Created
Diameter of crank pin of centre crankshaft at TDC position given thickness of crank web
Go
Created
Diameter of crank pin of centre crankshaft at TDC position given width of crank web
Go
Created
Force on crank pin given crank pin length, diameter and bearing pressure
Go
Created
Length of crank pin of centre crankshaft at TDC position given allowable bearing pressure
Go
Design of Crank Pin
(8)
Created
Bearing pressure at crank pin bush of centre crankshaft for max torque
Go
Created
Bending moment at central plane of crank pin of centre crankshaft at max torque
Go
Created
Diameter of crank pin of centre crankshaft for max torque
Go
Created
Diameter of crank pin of centre crankshaft for max torque given bending and torsional moment
Go
Created
Length of crank pin of centre crankshaft for max torque given allowable bearing pressure
Go
Created
Shear stress in crankpin of centre crankshaft for max torque
Go
Created
Shear stress in crankpin of centre crankshaft for max torque given bending and torsional moment
Go
Created
Torsional moment at central plane of crank pin of centre crankshaft at max torque
Go
Design of Crank Pin
(11)
Created
Bending stress in crank pin of side crankshaft at max torque given crankpin diameter
Go
Created
Diameter of crankpin given mean bending stress in crankpin
Go
Created
Length of crankpin given mean bending moment in crankpin
Go
Created
Maximum bending moment in crankpin when load acts at end point on crankpin as cantilever beam
Go
Created
Maximum bending moment in crankpin when load is uniformly distributed along length as cantilever
Go
Created
Maximum length of crankpin given crankpin diameter
Go
Created
Mean bending moment in crankpin
Go
Created
Mean bending moment in crankpin given bending stress and crankpin diameter
Go
Created
Mean bending stress in crankpin given bending moment and crankpin diameter
Go
Created
Minimum length of crankpin given crankpin diameter
Go
Created
Section modulus of crankpin
Go
Design of Crank Pin
(4)
Created
Bending Moment in horizontal plane of crank pin of side crankshaft at max torque
Go
Created
Bending Moment in vertical plane of crank pin of side crankshaft at max torque
Go
Created
Resultant Bending Moment in crank pin of side crankshaft at max torque
Go
Created
Resultant Bending Moment in crank pin of side crankshaft at max torque given crankpin diameter
Go
Design of Crank Web
(15)
Created
Bending moment at central plane of crank web of centre crankshaft at TDC position
Go
Created
Bending stress at central plane of crank web of centre crankshaft at TDC position
Go
Created
Direct compressive stress in central plane of crank web of centre crankshaft at TDC position
Go
Created
Maximum Bending stress in crank web of centre crankshaft at TDC position given bending moment
Go
Created
Thickness of crank web of centre crankshaft at TDC position given bearing pressure for crank pin
Go
Created
Thickness of crank web of centre crankshaft at TDC position given bending moment in crank pin
Go
Created
Thickness of crank web of centre crankshaft at TDC position given compressive stress
Go
Created
Thickness of crank web of centre crankshaft at TDC position given diameter of crank pin
Go
Created
Thickness of crank web of centre crankshaft at TDC position given width of crank web
Go
Created
Total compressive stress at central plane of crank web of centre crankshaft at TDC position
Go
Created
Width of crank web of centre crankshaft at TDC position given bearing pressure for crank pin
Go
Created
Width of crank web of centre crankshaft at TDC position given bending moment in crank pin
Go
Created
Width of crank web of centre crankshaft at TDC position given compressive stress
Go
Created
Width of crank web of centre crankshaft at TDC position given diameter of crank pin
Go
Created
Width of crank web of centre crankshaft at TDC position given thickness of crank web
Go
Design of Crank Web
(20)
Created
Bending moment in crankweb of centre crankshaft due to radial thrust for max torque given stress
Go
Created
Bending moment in crankweb of centre crankshaft due to radial thrust for maximum torque
Go
Created
Bending moment in crankweb of centre crankshaft due to tangential thrust for max torque given stress
Go
Created
Bending moment in crankweb of centre crankshaft due to tangential thrust for maximum torque
Go
Created
Bending stress in crankweb of centre crankshaft due to radial thrust for max torque given moment
Go
Created
Bending stress in crankweb of centre crankshaft due to tangential thrust for max torque given moment
Go
Created
Direct compressive stress in crankweb of centre crankshaft due to radial thrust for max torque
Go
Created
Maximum compressive stress in crankweb of centre crankshaft for max torque
Go
Created
Maximum compressive stress in crankweb of centre crankshaft for max torque given crankweb dimensions
Go
Created
Maximum compressive stress in crankweb of centre crankshaft for max torque given direct stress
Go
Created
Polar section modulus of crankweb of centre crankshaft for max torque
Go
Created
Section modulus of crankweb of centre crankshaft for max torque
Go
Created
Shear stress in crankweb of centre crankshaft for max torque given polar section modulus
Go
Created
Shear stress in crankweb of centre crankshaft for max torque given reaction on bearing1
Go
Created
Shear stress in crankweb of centre crankshaft for max torque given reaction on bearing2
Go
Created
Shear stress in crankweb of centre crankshaft for max torque given torsional moment
Go
Created
Torsional moment in crankweb of centre crankshaft for max torque given polar section modulus
Go
Created
Torsional moment in crankweb of centre crankshaft for max torque given reaction on bearing1
Go
Created
Torsional moment in crankweb of centre crankshaft for max torque given reaction on bearing2
Go
Created
Torsional moment in crankweb of centre crankshaft for max torque given shear stress
Go
Design of Crank Web
(9)
Created
Bending moment in central plane of crankweb
Go
Created
Bending stress in central plane of crankweb
Go
Created
Bending stress in central plane of crankweb given bending moment
Go
Created
Direct compressive stress in central plane of crankweb of side crankshaft at TDC Position
Go
Created
Length of crankpin given bending moment in central plane of crankweb
Go
Created
Length of crankpin given bending stress in central plane of crankweb
Go
Created
Thickness of crankweb given bending moment at bearing 1 of side crankshaft at TDC position
Go
Created
Thickness of crankweb given bending moment in central plane of crankweb
Go
Created
Total compressive stress in central plane of crankweb of side crankshaft at TDC position
Go
Design of Crank Web
(14)
Created
Bending moment in crankweb of side crankshaft due to radial thrust for max torque given stress
Go
Created
Bending moment in crankweb of side crankshaft due to radial thrust for maximum torque
Go
Created
Bending moment in crankweb of side crankshaft due to tangential thrust for max torque
Go
Created
Bending moment in crankweb of side crankshaft due to tangential thrust for max torque given stress
Go
Created
Bending stress in crankweb of side crankshaft due to radial thrust for max torque
Go
Created
Bending stress in crankweb of side crankshaft due to radial thrust for max torque given moment
Go
Created
Bending stress in crankweb of side crankshaft due to tangential thrust for max torque
Go
Created
Bending stress in crankweb of side crankshaft due to tangential thrust for max torque given moment
Go
Created
Direct compressive stress in crankweb of side crankshaft due to radial thrust for max torque
Go
Created
Maximum compressive stress in crankweb of side crankshaft for max torque
Go
Created
Maximum compressive stress in crankweb of side crankshaft for max torque given individual stresses
Go
Created
Shear stress in crankweb of side crankshaft at max torque
Go
Created
Torsional moment in crankweb of side crankshaft at max torque
Go
Created
Total compressive stress in crankweb of side crankshaft at max torque
Go
Design of Crankshaft Bearing
(3)
Created
Bearing pressure of journal at bearing 2 of centre crankshaft for max torque
Go
Created
Diameter of journal at bearing 2 of centre crankshaft for max torque
Go
Created
Length of journal at bearing 2 of centre crankshaft for max torque
Go
Design of Cross Section of Rocker Arm
(7)
Created
Area Moment of Inertia of Cross Section of Rocker Arm
Go
Created
Area Moment of Inertia of Cross Section of Rocker Arm given Bending Stress and Moment
Go
Created
Bending Moment in Rocker Arm near Boss of Rocker Arm at Fulcrum Pin
Go
Created
Bending Moment in Rocker Arm near Boss of Rocker Arm given Bending Stress
Go
Created
Diameter of Fulcrum Pin of Rocker Arm given Bending Moment near Boss of Rocker Arm
Go
Created
Diameter of Fulcrum Pin of Rocker Arm given Outside Diameter of Boss at Fulcrum Pin
Go
Created
Length of Rocker Arm of Exhaust Valve Side
Go
Design of Curved Beams
(18)
Created
Area of cross section of curved beam given bending stress at inner fiber
Go
Created
Area of cross section of curved beam given bending stress at outer fiber
Go
Created
Bending moment at fibre of curved beam given bending stress and eccentricity
Go
Created
Bending moment at fibre of curved beam given bending stress and radius of centroidal axis
Go
Created
Bending moment in curved beam given bending stress at inner fibre
Go
Created
Bending moment in curved beam given bending stress at outer fibre
Go
Created
Bending stress at inner fibre of curved beam given bending moment
Go
Created
Bending stress at outer fibre of curved beam given bending moment
Go
Created
Bending stress in fibre of curved beam given eccentricity
Go
Created
Bending stress in fibre of curved beam given radius of centroidal axis
Go
Created
Diameter of circular curved beam given radius of centroidal axis
Go
Created
Distance of fibre from neutral axis of rectangular curved beam given inner and outer fiber radius
Go
Created
Distance of fibre from neutral axis of rectangular curved beam given radius of centroidal axis
Go
Created
Distance of inner fiber from neutral axis of curved beam given bending stress at fibre
Go
Created
Distance of outer fibre from neutral axis of curved beam given bending stress at fibre
Go
Created
Eccentricity between centroidal and neutral axis of curved beam given bending stress at inner fibre
Go
Created
Eccentricity between centroidal and neutral axis of curved beam given bending stress at outer fibre
Go
Created
Eccentricity between centroidal and neutral axis of curved beam given radius of both axis
Go
2 More Design of Curved Beams Calculators
Go
Design of Forked End
(22)
Created
Bearing Pressure at Roller Pin of Forked End of Rocker Arm
Go
Created
Bending Moment in Central Plane of Roller Pin of Forked End of Rocker Arm
Go
Created
Bending Stress in Roller Pin of Forked End of Rocker Arm given Bending Moment
Go
Created
Diameter of Roller Pin at Forked End of Rocker Arm
Go
Created
Diameter of Roller Pin at Forked End of Rocker Arm given its Length
Go
Created
Diameter of Roller Pin of Forked End of Rocker Arm Considering Double Shear Failure of Pin
Go
Created
Diameter of Roller Pin of Forked End of Rocker Arm given Force at Roller Pin
Go
Created
Diameter of Roller Pin of Forked End of Rocker Arm given Outer Diameter of Eye of Roller Pin
Go
Created
Force on Roller Pin of Forked End of Rocker Arm
Go
Created
Force on Roller Pin of Forked End of Rocker Arm given Shear Stress in Roller Pin
Go
Created
Length of Roller Pin at Forked End of Rocker Arm given Thickness of Eye of Roller Pin
Go
Created
Length of Roller Pin of Forked End of Rocker Arm
Go
Created
Length of Roller Pin of Forked End of Rocker Arm Considering Double Shear Failure of Pin
Go
Created
Length of Roller Pin of Forked End of Rocker Arm given Force at Roller Pin
Go
Created
Length of Roller Pin of Forked End of Rocker Arm given its Diameter
Go
Created
Maximum Bending Moment in Roller Pin of Forked End of Rocker Arm
Go
Created
Maximum Bending Moment in Roller Pin of Forked End of Rocker Arm given Bending Stress
Go
Created
Outer Diameter of Eye of Roller Pin of Forked End of Rocker Arm
Go
Created
Section Modulus of Roller Pin of Forked End of Rocker Arm
Go
Created
Shear Stress in Roller Pin of Forked End of Rocker Arm
Go
Created
Shear Stress in Roller Pin of Forked End of Rocker Arm given Force on Roller Pin
Go
Created
Thickness of Eye of Roller Pin of Forked End of Rocker Arm
Go
Design of Fulcrum Pin
(17)
Created
Angle between Two Arms of Rocker Arm
Go
Created
Bearing Pressure at Fulcrum Pin of Rocker Arm
Go
Created
Diameter of Fulcrum Pin of Rocker Arm Considering Double Shear Failure of Pin
Go
Created
Diameter of Fulcrum Pin of Rocker Arm given Bearing Pressure
Go
Created
Diameter of Fulcrum Pin of Rocker Arm given Length of Fulcrum Pin
Go
Created
Diameter of Fulcrum Pin of Rocker Arm given Reaction at Pin
Go
Created
Length of Fulcrum Pin of Rocker Arm considering Double Shear Failure of Pin
Go
Created
Length of Fulcrum Pin of Rocker Arm given Bearing Pressure
Go
Created
Length of Fulcrum Pin of Rocker Arm given Diameter of Fulcrum Pin
Go
Created
Length of Fulcrum Pin of Rocker Arm given Reaction at Pin
Go
Created
Outside Diameter of Boss of Rocker Arm at Fulcrum Pin
Go
Created
Reaction at Fulcrum Pin of Rocker Arm
Go
Created
Reaction at Fulcrum Pin of Rocker Arm Considering bearing Pressure
Go
Created
Reaction at Fulcrum Pin of Rocker Arm considering Double Shear Failure of Pin
Go
Created
Reaction at Fulcrum Pin of Rocker Arm for Equal Arm Lengths
Go
Created
Shear Stress in Fulcrum Pin of Rocker Arm
Go
Created
Shear Stress in Fulcrum Pin of Rocker Arm given Reaction at Pin
Go
Design of Fulcrum Pin
(8)
Created
Bearing pressure in fulcrum pin of lever given reaction force and diameter of pin
Go
Created
Compressive stress in fulcrum pin of lever given reaction force, depth of lever arm
Go
Created
Diameter of fulcrum pin given compressive stress in pin
Go
Created
Diameter of fulcrum pin of lever given bending moment and effort force
Go
Created
Diameter of fulcrum pin of lever given reaction force and bearing pressure
Go
Created
Length of flucrum pin of lever given reaction force and bearing pressure
Go
Created
Length of fulcrum pin boss given compressive stress in pin
Go
Created
Maximum length of flucrum pin of lever given diameter of fulcrum pin
Go
Design of Shaft at Juncture of Crank Web
(7)
Created
Bending moment in horizontal plane of centre crankshaft at juncture of right crankweb for max torque
Go
Created
Bending moment in vertical plane of centre crankshaft at juncture of right crankweb for max torque
Go
Created
Diameter of centre crankshaft at juncture of right crankweb for max torque given crankweb moment
Go
Created
Diameter of centre crankshaft at juncture of right crankweb for max torque given moments
Go
Created
Resultant bending moment in centre crankshaft at juncture of right crankweb for maximum torque
Go
Created
Shear stress in centre crankshaft at juncture of right crankweb for maximum torque
Go
Created
Torsional moment in centre crankshaft at juncture of right crankweb for maximum torque
Go
Design of Shaft at Juncture of Crank Web
(9)
Created
Bending moment in horizontal plane of side-crankshaft at juncture of crankweb for max torque
Go
Created
Bending moment in vertical plane of side-crankshaft at juncture of crankweb for max torque
Go
Created
Diameter of side crankshaft at juncture of crankweb for max torque
Go
Created
Diameter of side-crankshaft at juncture of crankweb for max torque given moments
Go
Created
Resultant bending moment in side crankshaft at juncture of crankweb for max torque given moments
Go
Created
Resultant bending moment in side-crankshaft at juncture of crankweb for max torque
Go
Created
Shear stress in side-crankshaft at juncture of crankweb for max torque
Go
Created
Shear stress in side-crankshaft at juncture of crankweb for max torque given moments
Go
Created
Torsional moment in side-crankshaft at juncture of crankweb for max torque
Go
Design of Shaft Under Flywheel
(8)
Created
Bending Moment in horizantal plane of centre crankshaft below flywheel at TDC due to belt tension
Go
Created
Bending Moment in vertical plane of centre crankshaft below flywheel at TDC due to flywheel weight
Go
Created
Bending stress in centre crankshaft at TDC position below flywheel given shaft diameter
Go
Created
Diameter of part of centre crankshaft under flywheel at TDC position
Go
Created
Gap of Bearing 2 from Flywheel of centre crankshaft at TDC position
Go
Created
Gap of Bearing 3 from Flywheel of centre crankshaft at TDC position
Go
Created
Resultant Bending Moment in centre crankshaft at TDC position below flywheel
Go
Created
Resultant Bending Moment in centre crankshaft at TDC position below flywheel given shaft diameter
Go
Design of Shaft Under Flywheel
(6)
Created
Bending moment at central plane of centre crankshaft below flywheel at max torque
Go
Created
Diameter of centre crankshaft under flywheel at max torque
Go
Created
Diameter of centre crankshaft under flywheel at max torque given bending and torsional moment
Go
Created
Shear stress in centre crankshaft below flywheel for max torque
Go
Created
Shear stress in centre crankshaft below flywheel for max torque given bending and torsional moment
Go
Created
Torsional moment at central plane of centre crankshaft below flywheel at max torque
Go
Design of Shaft Under Flywheel
(8)
Created
Bending Moment in horizontal plane of side crankshaft at TDC position below flywheel due to flywheel
Go
Created
Bending Moment in vertical plane of side crankshaft at TDC position below flywheel due to flywheel
Go
Created
Diameter of part of side crankshaft under flywheel at TDC position
Go
Created
Gap of Bearing 1 from Flywheel of side crankshaft at TDC position
Go
Created
Gap of Bearing 2 from Flywheel of side crankshaft at TDC position
Go
Created
Resultant Bending Moment in side crankshaft at TDC position below flywheel
Go
Created
Resultant Bending Moment in side crankshaft at TDC position below flywheel given shaft diameter
Go
Created
Resultant Bending stress in side crankshaft at TDC position below flywheel given bending moment
Go
Design of Shaft Under Flywheel
(9)
Created
Diameter of side crankshaft under flywheel at max torque given moments
Go
Created
Diameter of side-crankshaft under flywheel at max torque
Go
Created
Horizontal Bending Moment at Central Plane of Side Crankshaft below Flywheel at max Torque
Go
Created
Resultant Bending moment at side crankshaft below flywheel at max torque given bearing reactions
Go
Created
Resultant Bending moment at side crankshaft below flywheel at max torque given moments
Go
Created
Torsional moment at central plane of side-crankshaft below flywheel at max torque
Go
Created
Torsional shear stress in side-crankshaft below flywheel for max torque
Go
Created
Torsional shear stress in side-crankshaft below flywheel for max torque given moments
Go
Created
Vertical bending moment at central plane of side crankshaft below flywheel at max torque
Go
Design of Tappet
(10)
Created
Compressive Force on Tappet of Rocker Arm of Engine Valve
Go
Created
Compressive Force on Tappet of Rocker Arm of Engine Valve given Stress in Tappet
Go
Created
Compressive Stress in Tappet of Rocker Arm of Engine Valve
Go
Created
Core Diameter of Tappet of Rocker Arm of Valve given Total Force on Rocker Arm of Exhaust Valve
Go
Created
Core Diameter of Tappet or Stud of Rocker Arm of Engine Valve
Go
Created
Depth of Circular End of Rocker Arm of Engine Valve
Go
Created
Diameter of Circular End of Rocker Arm of Engine Valve
Go
Created
Nominal Diameter of Tappet or Stud of Rocker Arm of Engine Valve
Go
Created
Nominal Diameter of Tappet or Stud of Rocker Arm of Engine Valve given its Core Diameter
Go
Created
Stress in Tappet of Rocker Arm of Engine Valve given Total Force on Rocker Arm of Exhaust Valve
Go
Diameter of Pin of Knuckle joint
(13)
Created
Diameter of Knuckle Pin given Bending Moment in Pin
Go
Created
Diameter of Knuckle Pin given Bending Stress in Pin
Go
Created
Diameter of Pin of Knuckle Joint given Compressive Stress in Eye End Portion of Pin
Go
Created
Diameter of Pin of Knuckle Joint given Compressive Stress in Fork End Portion of Pin
Go
Created
Diameter of Pin of Knuckle Joint given Diameter of Pinhead
Go
Created
Diameter of Pin of Knuckle Joint given Load and Shear Stress in Pin
Go
Created
Diameter of Pin of Knuckle Joint given Outer Diameter of Eye
Go
Created
Diameter of Pin of Knuckle Joint given Shear Stress in Eye
Go
Created
Diameter of Pin of Knuckle Joint given Shear Stress in Fork
Go
Created
Diameter of Pin of Knuckle Joint given Tensile Stress in Eye
Go
Created
Diameter of Pin of Knuckle Joint given Tensile Stress in Fork
Go
Created
Diameter of Pinhead of Knuckle Joint given Diameter of Pin
Go
Created
Length of Pin of Knuckle Joint in Contact with Eye End
Go
Diameter of Push Rod
(6)
Created
Inner Diameter of Engine Push Rod given Radius of Gyration
Go
Created
Maximum Inner Diameter of Engine Push Rod given Outer Diameter
Go
Created
Maximum Outer Diameter of Engine Push Rod given Inner Diameter
Go
Created
Minimum Inner Diameter of Engine Push Rod given Outer Diameter
Go
Created
Minimum Outer Diameter of Engine Push Rod given Inner Diameter
Go
Created
Outer Diameter of Engine Push Rod given Radius of Gyration
Go
Diameter of Rod of Cotter Joint
(4)
Created
Diameter of Rod of Cotter Joint given Socket Collar Diameter
Go
Created
Diameter of Rod of Cotter Joint given Spigot Collar Diameter
Go
Created
Diameter of Rod of Cotter Joint given Thickness of Cotter
Go
Created
Diameter of Rod of Cotter Joint given Thickness of Spigot Collar
Go
1 More Diameter of Rod of Cotter Joint Calculators
Go
Diameter of Rod Of Knuckle Joint
(5)
Created
Diameter of Rod of Knuckle Joint given its Enlarged Diameter near Joint
Go
Created
Diameter of Rod of Knuckle Joint given Tensile Stress in Rod
Go
Created
Enlarged Diameter of Rod of Knuckle Joint near Joint
Go
Created
Rod Diameter of Knuckle Joint given Thickness of Eye
Go
Created
Rod Diameter of Knuckle Joint given Thickness of Fork Eye
Go
Diameter of Socket Collar
(5)
Created
Diameter of Socket Collar given Rod Diameter
Go
Created
Diameter of Socket Collar of Cotter Joint given Bending Stress in Cotter
Go
Created
Diameter of Socket Collar of Cotter Joint given Compressive Stress
Go
Created
Diameter of socket collar of cotter joint given shear stress in socket
Go
Created
Inside Diameter of Socket of Cotter Joint given Shear Stress in Socket
Go
Diameter of Spigot and Spigot Collar
(4)
Created
Diameter of Spigot Collar given Rod Diameter
Go
Created
Diameter of Spigot of Cotter Joint given Bending Stress in Cotter
Go
Created
Diameter of Spigot of Cotter Joint given Compressive Stress
Go
Created
Diameter of Spigot of Cotter Joint given Shear Stress in Spigot
Go
2 More Diameter of Spigot and Spigot Collar Calculators
Go
Diameter of Spring Wire
(9)
Created
Diameter of Wire of Engine Valve Spring
Go
Created
Diameter of Wire of Engine Valve Spring given Maximum Compression in Spring
Go
Created
Diameter of Wire of Engine Valve Spring given Mean Coil Diameter
Go
Created
Diameter of Wire of Engine Valve Spring given Number of Active Turns of Spring
Go
Created
Diameter of Wire of Engine Valve Spring given Torsional Shear Stress in Wire
Go
Created
Diameter of Wire of Engine Valve Spring given Total Turns of Spring
Go
Created
Spring Index of Engine Valve Spring given Shear Stress, Maximum Force and Wire Diameter
Go
Created
Wahl Factor for Engine Valve Spring given Mean Coil Diameter and Wire Diameter
Go
Created
Wahl Factor for Engine Valve Spring given Spring Index
Go
Dimensions of Lever Arm
(6)
Created
Angle between arms of lever given effort, load and net reaction at fulcrum
Go
Created
Depth of lever arm given width
Go
Created
Length of major axis for elliptical cross sectioned lever given minor axis
Go
Created
Length of minor axis for elliptical cross sectioned lever given major axis
Go
Created
Outside diameter of boss in lever
Go
Created
Width of lever arm given depth
Go
Direct And Bending Stress
(1)
Created
Standard gauge length for UTM test specimen
Go
Effort, Load and Reaction on Lever
(4)
Created
Effort Force Applied on Lever given Bending Moment
Go
Created
Reaction Force at Fulcrum of Lever given Bearing Pressure
Go
Created
Reaction Force at Fulcrum of Lever given Effort, Load and Contained Angle
Go
Created
Reaction Force at Fulcrum of Right Angled Lever
Go
6 More Effort, Load and Reaction on Lever Calculators
Go
Emperical Relationships for Cylinder Wall, Head, Jacket and Liner
(10)
Created
Maximum Thickness of Cylinder Flange given Nominal Diameter of Stud
Go
Created
Maximum Thickness of Cylinder Flange given Thickness of Cylinder Wall
Go
Created
Maximum Thickness of Dry Liner
Go
Created
Maximum Thickness of Water Jacket Wall
Go
Created
Minimum Thickness of Cylinder Flange given Nominal Diameter of Stud
Go
Created
Minimum Thickness of Cylinder Flange given Thickness of Cylinder Wall
Go
Created
Minimum Thickness of Dry Liner
Go
Created
Minimum Thickness of Water Jacket Wall
Go
Created
Thickness of Engine Cylinder Wall given Cylinder Inner Diameter
Go
Created
Water Space between Outer Cylinder Wall and Inner Jacket Wall
Go
Energy Density and Energy Stored
(1)
Verified
Energy Stored in Capacitor given Capacitance and Voltage
Go
6 More Energy Density and Energy Stored Calculators
Go
Flat Plate Against Fluctuating Loads
(6)
Created
Load on Flat Plate with Shoulder Fillet given Nominal Stress
Go
Created
Major Axis of Elliptical Crack Hole in Flat Plate given Theoretical Stress Concentration Factor
Go
Created
Minor Axis of Elliptical Crack Hole in Flat Plate given Theoretical Stress Concentration Factor
Go
Created
Nominal Tensile Stress in Flat Plate with Shoulder Fillet
Go
Created
Smaller Width of Flat Plate with Shoulder Fillet given Nominal stress
Go
Created
Thickness of Flat Plate with Shoulder Fillet given Nominal Stress
Go
Flight Envelope
(1)
Verified
Minimum Flight Velocity
Go
15 More Flight Envelope Calculators
Go
Force on Crank Pin
(8)
Created
Angle between connecting rod and line of dead centres
Go
Created
Angle between crank and line of dead centres
Go
Created
Force acting on piston top due to gas pressure given thrust force on connecting rod
Go
Created
Force on connecting rod given radial component of force at crankpin
Go
Created
Force on connecting rod given tangential component of force at crankpin
Go
Created
Radial component of force at crank pin given force on connecting rod
Go
Created
Tangential component of force at crank pin given force on connecting rod
Go
Created
Thrust on connecting rod due to force on piston head
Go
Force on Rocker Arm of Valves
(16)
Created
Back Pressure when Exhaust Valve Opens
Go
Created
Bending Stress in Rocker Arm near Boss of Rocker Arm given Bending Moment
Go
Created
Downward Inertia Force on Exhaust Valve as it Moves Upwards
Go
Created
Downward Inertia Force on Exhaust Valve given Total Force on Rocker Arm of Exhaust Valve
Go
Created
Downward Inertia Force on Valve given Total Force on Rocker Arm of Inlet Valve
Go
Created
Gas Load on Exhaust Valve given Total Force on Rocker Arm of Exhaust Valve
Go
Created
Gas Load on Exhaust Valve when it Opens
Go
Created
Initial Spring Force on Exhaust Valve
Go
Created
Initial Spring Force on Exhaust Valve given Total Force on Rocker Arm of Exhaust Valve
Go
Created
Initial Spring Force on Valve given Total Force on Rocker Arm of Inlet Valve
Go
Created
Maximum Suction Pressure on Exhaust Valve
Go
Created
Total Force on Rocker Arm of Exhaust Valve
Go
Created
Total Force on Rocker Arm of Exhaust Valve given Bending Moment near Boss of Rocker Arm
Go
Created
Total Force on Rocker Arm of Exhaust Valve given Suction Pressure
Go
Created
Total Force on Rocker Arm of Inlet Valve
Go
Created
Total Force on Rocker Arm of Inlet Valve given Suction Pressure
Go
Fracture Mechanics
(10)
Created
Fracture toughness given stress intensity factor
Go
Created
Fracture toughness given tensile stress at edge of crack
Go
Created
Half crack length given fracture toughness
Go
Created
Half crack length given stress intensity factor
Go
Created
Nominal tensile stress at edge of crack given fracture toughness
Go
Created
Nominal tensile stress at edge of crack given load, plate thickness and plate width
Go
Created
Nominal tensile stress at edge of crack given stress intensity factor
Go
Created
Stress Intensity factor for cracked plate
Go
Created
Thickness of plate given nominal tensile stress at edge of crack
Go
Created
Width of plate given nominal tensile stress at edge of crack
Go
Frequency of Vibration
(4)
Created
Mass of Engine Valve Spring given its Natural Frequency of Vibration and Stiffness
Go
Created
Natural Frequency of Vibration of Engine Valve Spring given its Mass and Stiffness
Go
Created
Stiffness of Engine Valve Spring given its Natural Frequency of Vibration and Mass
Go
Created
Stiffness of Engine Valve Spring given Total Turns of Spring
Go
Helical Springs
(1)
Created
Direct shear stress in spring wire
Go
13 More Helical Springs Calculators
Go
Length of Arms
(1)
Created
Length of effort arm of lever given bending moment
Go
4 More Length of Arms Calculators
Go
Length of Spring
(6)
Created
Free Length of Engine Valve Spring
Go
Created
Solid Length of Engine Valve Spring
Go
Created
Solid Length of Engine Valve Spring given its Free Length and Maximum Compression
Go
Created
Solid Length of Engine Valve Spring given Number of Active Turns of Spring and Wire Diameter
Go
Created
Solid Length of Engine Valve Spring given Total Number of Turns of Spring and Wire Diameter
Go
Created
Total Gap between Coils of Engine Valve Spring given Maximum Compression of Spring
Go
Lift to Drag Ratio
(2)
Created
Lift to Drag Ratio for Maximum Endurance given Max Lift to Drag Ratio for Prop-driven Aircraft
Go
Created
Maximum Lift to Drag Ratio given Lift to Drag Ratio for Max Endurance of Prop-Driven Aircraft
Go
4 More Lift to Drag Ratio Calculators
Go
Load Capacities of Elements of Cotter Joint
(8)
Created
Force on Cotter given Shear Stress in Cotter
Go
Created
Load Taken by Cotter Joint Rod given Tensile Stress in Rod
Go
Created
Load Taken by Socket of Cotter Joint given Compressive Stress
Go
Created
Load Taken by Socket of Cotter Joint given Shear Stress in Socket
Go
Created
Load Taken by Socket of Cotter Joint given Tensile Stress in Socket
Go
Created
Load Taken by Spigot of Cotter Joint given Compressive Stress in Spigot Considering Crushing Failure
Go
Created
Load Taken by Spigot of Cotter Joint given Shear Stress in Spigot
Go
Created
Maximum Load taken by Cotter Joint given Spigot Diameter, Thickness and Stress
Go
Maximum Compression of Spring
(4)
Created
Maximum Compression of Engine Valve Spring given its Free Length and Solid Length
Go
Created
Maximum Compression of Engine Valve Spring given Number of Active Turns
Go
Created
Maximum Compression of Engine Valve Spring given Total Gap between Coils of Spring
Go
Created
Maximum Compression of Engine Valve Spring given Total Turns
Go
Mean Coil Diameter of Spring
(5)
Created
Diameter of coil of engine valve spring given maximum compression in spring
Go
Created
Diameter of coil of engine valve spring given torsional shear stress in wire
Go
Created
Mean coil diameter of engine valve spring given number of active turns of spring
Go
Created
Mean coil diameter of engine valve spring given total turns of spring
Go
Created
Mean coil diameter of engine valve spring given wire diameter
Go
Metal Cutting
(1)
Verified
Shear Plane Angle
Go
14 More Metal Cutting Calculators
Go
Modulus of Rigidity of Spring Wire
(3)
Created
Modulus of Rigidity of Engine Valve Spring given Maximum Compression in Spring
Go
Created
Modulus of Rigidity of Engine Valve Spring given Number of Active Turns of Spring
Go
Created
Modulus of Rigidity of Engine Valve Spring given Total Number of Turns of Spring
Go
Number of Active Turns
(4)
Created
Number of Active Turns of Engine Valve Spring
Go
Created
Number of Active Turns of Engine Valve Spring given Maximum Compression in Spring
Go
Created
Number of Active Turns of Engine Valve Spring given Pitch of Spring
Go
Created
Number of Active Turns of Engine Valve Spring given Total Turns
Go
Other Renewable Energy Sources
(5)
Verified
Angular Velocity of Rotor given Tip Speed Ratio
Go
Verified
Power Coefficient of Wind Machine
Go
Verified
Power Extracted by Rotor given Power Coefficient of Wind Machine
Go
Verified
Rotor Radius given Tip Speed Ratio
Go
Verified
Tip Speed Ratio
Go
7 More Other Renewable Energy Sources Calculators
Go
Outer Diameter of Eye of Knuckle Joint
(5)
Created
Outer Diameter of Eye of Knuckle Joint given Diameter of Pin
Go
Created
Outer Diameter of Eye of Knuckle Joint given Shear Stress in Eye
Go
Created
Outer Diameter of Eye of Knuckle Joint given Shear Stress in Fork
Go
Created
Outer Diameter of Eye of Knuckle Joint given Tensile Stress in Eye
Go
Created
Outer Diameter of Eye of Knuckle Joint given Tensile Stress in Fork
Go
Parameters
(1)
Verified
Maximum Blade Efficiency
Go
9 More Parameters Calculators
Go
Photovoltaic Conversion
(9)
Verified
Fill Factor of Solar Cell given Maximum Conversion Efficiency
Go
Verified
Load current corresponding to Maximum power
Go
Verified
Load current in Solar cell
Go
Verified
Maximum power output of cell
Go
Verified
Open Circuit Voltage given Reverse Saturation Current
Go
Verified
Reverse Saturation Current given Load current at Maximum Power
Go
Verified
Reverse Saturation Current given Power of Photovoltaic Cell
Go
Verified
Short Circuit Current given Load Current at Maximum Power
Go
Verified
Short Circuit Current given Maximum Conversion Efficiency
Go
11 More Photovoltaic Conversion Calculators
Go
Piston Barrel
(3)
Created
Maximum Thickness of Piston Barrel at Lower End
Go
Created
Minimum Thickness of Piston Barrel at Lower End
Go
Created
Thickness of Piston Barrel at Top End
Go
Piston Pin
(10)
Created
Area Moment of Inertia for Piston Pin Cross Section
Go
Created
Inner Diameter of Piston Pin
Go
Created
Length of Piston Pin used in Connecting Rod
Go
Created
Maximum Bending Moment on Piston Pin
Go
Created
Maximum Bending Stress in Piston Pin
Go
Created
Mean Diameter of Piston Bosses for Aluminium Alloy Piston
Go
Created
Mean Diameter of Piston Bosses for Grey Cast Iron Piston
Go
Created
Outer Diameter of Piston Pin
Go
Created
Outer Diameter of Piston Pin given its Inner Diameter
Go
Created
Resisting Bearing Force by Piston Pin
Go
Piston Pin and Crank Pin
(8)
Created
Inner Diameter of Bush on Crank Pin
Go
Created
Inner Diameter of Bush on Piston Pin
Go
Created
Length of Bush on Crank Pin
Go
Created
Length of Bush on Piston Pin
Go
Created
Maximum Length of Bush on Crank Pin
Go
Created
Maximum Length of Bush on Piston Pin
Go
Created
Minimum Length of Bush on Crank Pin
Go
Created
Minimum Length of Bush on Piston Pin
Go
Piston Ribs and Cup
(3)
Created
Maximum Thickness of Piston Ribs
Go
Created
Minimum Thickness of Piston Ribs
Go
Created
Radius of Piston Cup
Go
Piston Rings
(11)
Created
Length of Ring Section of Piston
Go
Created
Maximum Gap between Free Ends of Ring after Assembly
Go
Created
Maximum Gap between Free Ends of Ring before Assembly
Go
Created
Maximum Width of Top Land
Go
Created
Minimum Axial Thickness of Piston Ring given Cylinder Inner Diameter
Go
Created
Minimum Axial Thickness of Piston Ring given Radial Width of Ring
Go
Created
Minimum Gap between Free Ends of Ring after Assembly
Go
Created
Minimum Gap between Free Ends of Ring before Assembly
Go
Created
Minimum Width of Ring Groove
Go
Created
Number of Piston Rings
Go
Created
Radial Width of Piston Ring
Go
Piston Skirt
(8)
Created
Length of Piston Skirt given Allowable Bearing Pressure
Go
Created
Length of Piston Skirt given Side Thrust
Go
Created
Maximum Length of Piston Skirt
Go
Created
Maximum Total Length of Piston
Go
Created
Minimum Length of Piston Skirt
Go
Created
Side Thrust on Piston
Go
Created
Side Thrust on Piston Skirt
Go
Created
Total Length of Piston
Go
Pitch of Coils
(3)
Created
Pitch of Engine Valve Spring
Go
Created
Pitch of Engine Valve Spring given its Free Length and Number of Active Turns
Go
Created
Pitch of Engine Valve Spring given its Free Length and Total Number of Turns
Go
Radiation
(1)
Verified
Thermal Resistance of black body surface due to radiation
Go
7 More Radiation Calculators
Go
Radius of Fiber and Axis
(16)
Created
Radius of centroidal axis of curved beam given bending stress
Go
Created
Radius of centroidal axis of curved beam given eccentricity between axis
Go
Created
Radius of centroidal axis of curved beam of circular section given radius of inner fiber
Go
Created
Radius of centroidal axis of curved beam of rectangular section given radius of inner fiber
Go
Created
Radius of inner fiber of circular curved beam given radius of neutral axis and outer fiber
Go
Created
Radius of inner fiber of curved beam given bending stress at fiber
Go
Created
Radius of inner fiber of curved beam of circular section given radius of centroidal axis
Go
Created
Radius of inner fiber of rectangular curved beam given radius of neutral axis and outer fiber
Go
Created
Radius of inner fibre of curved beam of rectangular section given radius of centroidal axis
Go
Created
Radius of neutral axis of curved beam given bending stress
Go
Created
Radius of neutral axis of curved beam given eccentricity between axis
Go
Created
Radius of neutral axis of curved beam of circular section given radius of inner and outer fibre
Go
Created
Radius of neutral axis of curved beam of rectangular section given radius of inner and outer fiber
Go
Created
Radius of outer fiber of circular curved beam given radius of neutral axis and inner fiber
Go
Created
Radius of outer fiber of rectangular curved beam given radius of neutral axis and inner fiber
Go
Created
Radius of outer fibre of curved beam given bending stress at fiber
Go
Rectangular Plate Against Fluctuating Loads
(5)
Created
Diameter of Transverse Hole of Rectangular Plate with Stress Concentration given Nominal Stress
Go
Created
Load on Rectangular Plate with Transverse Hole given Nominal Stress
Go
Created
Nominal Tensile Stress in Rectangular Plate with Transverse Hole
Go
Created
Thickness of Rectangular Plate with Transverse Hole given Nominal Stress
Go
Created
Width of Rectangular Plate with Transverse Hole given Nominal Stress
Go
Rectangular Section Is Subjected To Eccentric Load
(1)
Created
Maximum stress when subjected to eccentric axial load
Go
21 More Rectangular Section Is Subjected To Eccentric Load Calculators
Go
Riveted Joints
(1)
Created
Diameter of rivets for lap joint
Go
16 More Riveted Joints Calculators
Go
Round Shaft Against Fluctuating Loads
(7)
Created
Bending Moment in Round Shaft with Shoulder Fillet given Nominal Stress
Go
Created
Nominal Bending Stress in Round Shaft with Shoulder Fillet
Go
Created
Nominal Tensile Stress in Round Shaft with Shoulder Fillet
Go
Created
Nominal Torsional Stress in Round Shaft with Shoulder Fillet
Go
Created
Smaller Diameter of Round Shaft with Shoulder Fillet in Tension or Compression
Go
Created
Tensile Force in Round Shaft with Shoulder Fillet given Nominal Stress
Go
Created
Torsional Moment in Round Shaft with Shoulder Fillet given Nominal Stress
Go
Stress and Force in Push Rod
(10)
Created
Actual Length of Engine Push Rod
Go
Created
Area of Cross Section of Engine Push Rod
Go
Created
Compressive Stress in Engine Push Rod
Go
Created
Cross Section Area of Engine Push Rod given Force, Stress, and Radius of Gyration
Go
Created
Force Acting on Engine Push Rod
Go
Created
Force Acting on Engine Push Rod given its Dimensions and Stress Generated
Go
Created
Force Acting on Engine Push Rod Made of Steel
Go
Created
Moment of Inertia of Cross Section of Engine Push Rod
Go
Created
Radius of Gyration of Cross Section of Engine Push Rod
Go
Created
Radius of gyration of engine push rod given stress, force and cross section area
Go
Stress Concentration Factors
(4)
Created
Diameter of Shaft given Ratio of Torsional Strength of Shaft with Keyway to without Keyway
Go
Created
Height of Shaft Keyway given Ratio of Torsional Strength of Shaft with Keyway to without Keyway
Go
Created
Ratio of Torsional Strength of Shaft with Keyway to without Keyway
Go
Created
Width of Shaft Keyway given Ratio of Torsional Strength of Shaft with Keyway to without Keyway
Go
4 More Stress Concentration Factors Calculators
Go
Stress Due to Suction Pressure
(6)
Created
Maximum Force on Engine Valve Spring given Maximum Compression in Spring
Go
Created
Maximum Force on Engine Valve Spring given Torsional Shear Stress in Wire
Go
Created
Stiffness of Engine Valve Spring
Go
Created
Torsional Shear Stress in Wire of Engine Valve Spring
Go
Created
Torsional Shear Stress in Wire of Engine Valve Spring given Maximum Force on Spring
Go
Created
Total Force on Engine Valve Spring
Go
Stresses in Engine Cylinder Wall
(5)
Created
Allowable Tensile Stress for Stud Material
Go
Created
Apparent Circumferential Hoop Stress in Engine Cylinder Wall
Go
Created
Apparent Longitudinal Stress in Engine Cylinder Wall
Go
Created
Net Circumferential Hoop Stress in Engine Cylinder Wall
Go
Created
Net Longitudinal Stress in Engine Cylinder Wall
Go
Stresses in Knuckle joint
(11)
Created
Bending Stress in Knuckle Pin given Bending Moment in Pin
Go
Created
Bending Stress in Knuckle Pin given Load, Thickness of Eyes and Pin Diameter
Go
Created
Compressive Stress in Pin Inside Eye of Knuckle Joint given Load and Pin Dimensions
Go
Created
Compressive Stress in Pin Inside Fork of Knuckle Joint given Load and Pin Dimensions
Go
Created
Max Bending Moment in Knuckle Pin given Load, Thickness of Eye and Fork
Go
Created
Shear Stress in Eye of Knuckle Joint given Load, Outer Diameter of Eye and its Thickness
Go
Created
Shear Stress in Fork of Knuckle Joint given Load, Outer Diameter of Eye and Pin Diameter
Go
Created
Shear Stress in Pin of Knuckle Joint given Load and Pin Diameter
Go
Created
Tensile Stress in Eye of Knuckle Joint given Load, Outer Diameter of Eye and its Thickness
Go
Created
Tensile Stress in Fork of Knuckle Joint given Load, Outer Diameter of Eye and Pin Diameter
Go
Created
Tensile Stress in Rod of Knuckle Joint
Go
Stresses on Cotter Joint
(9)
Created
Bending Stress in Cotter of Cotter Joint
Go
Created
Compressive Stress in Socket of Cotter Joint given Diameter of Spigot and of Socket Collar
Go
Created
Compressive Stress in Spigot of Cotter Joint Considering Crushing Failure
Go
Created
Shear Stress in Cotter given Cotter Thickness and Width
Go
Created
Shear Stress in Socket of Cotter Joint given Inner and Outer Diameter of Socket
Go
Created
Shear Stress in Spigot of Cotter Joint given Diameter of Spigot and Load
Go
Created
Tensile Stress in Rod of Cotter Joint
Go
Created
Tensile Stress in Socket of Cotter Joint given Outer and Inner Diameter of Socket
Go
Created
Tensile Stress in Spigot of Cotter Joint given Diameter of Spigot, Thickenss of Cotter and Load
Go
Thermal Energy Storage
(5)
Verified
Liquid Temperature given Energy Discharge Rate
Go
Verified
Make up Liquid Temperature given Energy Discharge Rate
Go
Verified
Mass flow rate maintained during charging and discharging
Go
Verified
Overall heat transfer coefficient in liquid storage tank
Go
Verified
Theoretical Storage Capacity given Change in Initial Temperature
Go
3 More Thermal Energy Storage Calculators
Go
Thickness of Cotter and Spigot Collar
(6)
Created
Thickness of Cotter given Compressive Stress in Socket
Go
Created
Thickness of Cotter given Compressive Stress in Spigot
Go
Created
Thickness of Cotter given Shear Stress in Cotter
Go
Created
Thickness of Cotter given Tensile Stress in Socket
Go
Created
Thickness of Cotter Joint given Bending Stress in Cotter
Go
Created
Thickness of Spigot Collar when Rod Diameter is Available
Go
1 More Thickness of Cotter and Spigot Collar Calculators
Go
Thickness of Engine Cylinder Wall
(2)
Created
Outer Diameter of Engine Cylinder
Go
Created
Thickness of Engine Cylinder Wall
Go
Thickness of Eye End of Knuckle Joint
(5)
Created
Thickness of Eye End of Knuckle Joint given Bending Moment in Pin
Go
Created
Thickness of Eye End of Knuckle Joint given Bending Stress in Pin
Go
Created
Thickness of Eye End of Knuckle Joint given Shear Stress in Eye
Go
Created
Thickness of Eye End of Knuckle Joint given Tensile Stress in Eye
Go
Created
Thickness of Eye of Knuckle Joint given Rod Diameter
Go
Thickness of Fork Eye of Knuckle Joint
(6)
Created
Thickness of Fork Eye of Knuckle Joint given Bending Moment in Pin
Go
Created
Thickness of Fork Eye of Knuckle Joint given Bending Stress in Pin
Go
Created
Thickness of Fork Eye of Knuckle Joint given Compressive Stress in Pin Inside Fork End
Go
Created
Thickness of Fork Eye of Knuckle Joint given Rod Diameter
Go
Created
Thickness of Fork Eye of Knuckle Joint given Shear Stress in Fork
Go
Created
Thickness of Fork Eye of Knuckle Joint given Tensile Stress in Fork
Go
Thickness of Piston Head
(7)
Created
Amount of Heat Conducted through Piston Head
Go
Created
Amount of Heat Conducted through Piston Head given Higher Calorific Value of Fuel
Go
Created
Maximum Gas Force on Piston Head
Go
Created
Permissible Bending Stress for Piston
Go
Created
Thickness of Piston Head According to Grashoff's Formula
Go
Created
Thickness of Piston Head Considering Heat Dissipation
Go
Created
Thickness of piston head given cylinder inner diameter
Go
Total Number of Turns
(3)
Created
Total Number of Turns of Engine Valve Spring given Maximum Compression in Spring
Go
Created
Total Number of Turns of Engine Valve Spring given Pitch of Spring
Go
Created
Total Turns of Engine Valve Spring given Number of Active Turns
Go
Valve Disk
(8)
Created
Bending Stress in Valve Disk
Go
Created
Diameter of Port given Thickness of Valve Disk
Go
Created
Maximum Thickness of Valve Disk at Edges
Go
Created
Minimum Thickness of Valve Disk at Edges
Go
Created
Thickness of Valve Disk
Go
Created
Thickness of Valve Disk given Projected Width of Valve Seat
Go
Created
Thickness of Valve Disk Made of Cast Iron
Go
Created
Thickness of Valve Disk Made of Steel
Go
Valve Head
(12)
Created
Diameter of Port given Diameter of Valve Head and Projected Width of Valve Seat
Go
Created
Diameter of Port given Projected Width of Valve Seat
Go
Created
Diameter of Valve Head given Diameter of Port and Projected Width of Valve Seat
Go
Created
Diameter of Valve Head given Load on Exhaust Valve and Back Pressure
Go
Created
Diameter of Valve Head given Port Diameter
Go
Created
Diameter of Valve Head given Projected Width of Valve Seat
Go
Created
Maximum Projected Width of Valve Seat given Port Diameter
Go
Created
Minimum Projected Width of Valve Seat given Port Diameter
Go
Created
Port Diameter given Diameter of Valve Head
Go
Created
Projected Width of Valve Seat given Diameter of Port and Diameter of Valve Head
Go
Created
Projected Width of Valve Seat given Diameter of Valve Head
Go
Created
Projected Width of Valve Seat given Port Diameter
Go
Valve Lift
(6)
Created
Diameter of Port given Maximum Lift of Valve
Go
Created
Force Required to Lift Engine Valve
Go
Created
Lift of Engine Valve
Go
Created
Maximum Lift of Valve for Flat Headed Valves
Go
Created
Maximum Lift of Valve given Diameter of Port and Valve Seat Angle
Go
Created
Valve Seat Angle given Maximum Lift of Valve
Go
Valve Port
(11)
Created
Acceleration of Exhaust Valve
Go
Created
Area of IC Engine Port given Cross-Section Area of Piston
Go
Created
Cross-Section Area of IC Engine Piston given Area of Port
Go
Created
Diameter of IC Engine Port
Go
Created
Diameter of IC Engine Port given Area of Port
Go
Created
Engine Speed given Mean Velocity of Piston and Stroke Length
Go
Created
Mean Velocity of Gas through IC Engine Port given Engine Speed, Stroke, Area of Piston and Port
Go
Created
Mean Velocity of Gas through IC Engine Port given Velocity of Piston
Go
Created
Mean Velocity of IC Engine Piston given Engine Speed and Stroke Length
Go
Created
Mean Velocity of IC Engine Piston given Velocity of Gas through Port
Go
Created
Stroke Length of Piston given Mean Velocity of Piston and Engine Speed
Go
Valve Stem
(7)
Created
Diameter of Port given Diameter of Valve Stem
Go
Created
Diameter of Valve Stem
Go
Created
Maximum Diameter of Valve Stem
Go
Created
Minimum Diameter of Valve Stem
Go
Created
Spring Force on Valve when Seated
Go
Created
Tensile Stress in Valve Stem due to Spring Force on Valve
Go
Created
Thickness of Valve Disk given Force of Spring on Valve
Go
Velocity Ratio
(2)
Verified
Peripheral Velocity of Driving Pulley
Go
Verified
Peripheral Velocity of Follower Pulley
Go
8 More Velocity Ratio Calculators
Go
Weight Fraction
(1)
Created
Loiter weight Fraction for Jet Aircraft
Go
4 More Weight Fraction Calculators
Go
Width of Cotter
(2)
Created
Width of Cotter by Bending Consideration
Go
Created
Width of Cotter by Shear Consideration
Go
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