Flat Spiral Spring Controlling Torque Calculator

✖Youngs Modulus is a mechanical property of linear elastic solid substances. It describes the relationship between longitudinal stress and longitudinal strain.ⓘ Youngs Modulus [E]			+10% -10%
✖Width of Spring is defined as the total width of the spring when measured in the extended form.ⓘ Width of Spring [b]			+10% -10%
✖Thickness of Spring is an important as Springs made of fat material are stiffer than those made of thin material.ⓘ Thickness of Spring [t]			+10% -10%
✖Length is the measurement or extent of something from end to end.ⓘ Length [l]			+10% -10%

✖Flat Spiral Spring Controlling Torque is defined as the controlling torque is provided by two phosphorous bronze flat coiled helical springs.ⓘ Flat Spiral Spring Controlling Torque [T_ci]

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Formula

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Flat Spiral Spring Controlling Torque

Formula

`"T"_{"ci"} = ("E"*"b"*("t"^3))/(12*"l")`

Example

`"123117.5"=("1000Pa"*"2.22m"*(("5.5")^3))/(12*"0.25m")`

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Flat Spiral Spring Controlling Torque Solution

STEP 0: Pre-Calculation Summary

Formula Used

Flat Spiral Spring Controlling Torque = (Youngs Modulus*Width of Spring*(Thickness of Spring^3))/(12*Length)
T_ci = (E*b*(t^3))/(12*l)
This formula uses 5 Variables

Variables Used

Flat Spiral Spring Controlling Torque - Flat Spiral Spring Controlling Torque is defined as the controlling torque is provided by two phosphorous bronze flat coiled helical springs.
Youngs Modulus - (Measured in Pascal) - Youngs Modulus is a mechanical property of linear elastic solid substances. It describes the relationship between longitudinal stress and longitudinal strain.
Width of Spring - (Measured in Meter) - Width of Spring is defined as the total width of the spring when measured in the extended form.
Thickness of Spring - Thickness of Spring is an important as Springs made of fat material are stiffer than those made of thin material.
Length - (Measured in Meter) - Length is the measurement or extent of something from end to end.

STEP 1: Convert Input(s) to Base Unit

Youngs Modulus: 1000 Pascal --> 1000 Pascal No Conversion Required
Width of Spring: 2.22 Meter --> 2.22 Meter No Conversion Required
Thickness of Spring: 5.5 --> No Conversion Required
Length: 0.25 Meter --> 0.25 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

T_ci = (E*b*(t^3))/(12*l) --> (1000*2.22*(5.5^3))/(12*0.25)

Evaluating ... ...

T_ci = 123117.5

STEP 3: Convert Result to Output's Unit

123117.5 --> No Conversion Required

FINAL ANSWER

123117.5 <-- Flat Spiral Spring Controlling Torque

(Calculation completed in 00.004 seconds)

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< 25 Fundamental Parameters Calculators

Length of Pipe

Go Length = Diameter of Pipe*(2*Head Loss due to Friction*Earth’s Geocentric Gravitational Constant)/(Friction Factor*(Average Velocity^2))

Head Loss

Go Head Loss due to Friction = (Friction Factor*Length*(Average Velocity^2))/(2*Diameter of Pipe*Earth’s Geocentric Gravitational Constant)

Height of plates

Go Height = Difference in Liquid Level*(Capacitance with No Liquid*Magnetic Permeability)/(Capacitance-Capacitance with No Liquid)

Thickness of Spring

Go Thickness of Spring = (Flat Spiral Spring Controlling Torque*(12*Length)/(Youngs Modulus*Width of Spring)^-1/3)

Width of Spring

Go Width of Spring = (Flat Spiral Spring Controlling Torque*(12*Length)/(Youngs Modulus*Thickness of Spring^3))

Flat Spiral Spring Controlling Torque

Go Flat Spiral Spring Controlling Torque = (Youngs Modulus*Width of Spring*(Thickness of Spring^3))/(12*Length)

Youngs Modulus of Flat Spring

Go Youngs Modulus = Flat Spiral Spring Controlling Torque*(12*Length)/(Width of Spring*(Thickness of Spring^3))

Length of Spring

Go Length = Youngs Modulus*(Width of Spring*(Thickness of Spring^3))/Flat Spiral Spring Controlling Torque*12

Distance between boundaries

Go Distance = (Coefficient of Velocity*Area of Cross-Section*Speed of Body)/Resisting Motion in fluid

Boundary area being moved

Go Area of Cross-Section = Resisting Motion in fluid*Distance/(Coefficient of Velocity*Speed of Body)

Torque of moving Coil

Go Torque on Coil = Flux Density*Current*Number of Turns in Coil*Area of Cross-Section*0.001

Weight of Air

Go Weight of Air = (Immersed Depth*Specific Weight*Area of Cross-Section)+Weight of Material

Heat Transfer Coefficient

Go Heat Transfer Coefficient = (Specific Heat*Mass)/(Area of Cross-Section*Time Constant)

Area of thermal contact

Go Area of Cross-Section = (Specific Heat*Mass)/(Heat Transfer Coefficient*Time Constant)

Thermal time constant

Go Time Constant = (Specific Heat*Mass)/(Area of Cross-Section*Heat Transfer Coefficient)

Head Loss Due to Fitting

Go Head Loss due to Friction = (Eddy Loss Coefficient*Average Velocity)/(2*Earth’s Geocentric Gravitational Constant)

Maximum Fiber Stress in Flat Spring

Go Maximum Fiber Stress = (6*Flat Spiral Spring Controlling Torque)/(Width of Spring*Thickness of Spring^2)

Controlling Torque

Go Flat Spiral Spring Controlling Torque = Deflection of Pointer/Angle of Deflection of Galvanometer

Length of weighing platform

Go Length = (Weight of Material*Speed of Body)/Flow Rate

Angular Speed of Former

Go Angular Speed of Former = Linear Velocity of Former/(Breadth Of Former/2)

Angular Speed of Disc

Go Angular Speed of Disc = Damping Constant/Damping Torque

Average Velocity of System

Go Average Velocity = Flow Rate/Area of Cross-Section

Couple

Go Couple Moment = Force*Dynamic Viscosity of a Fluid

Weight on Force Sensor

Go Weight on Force Sensor = Weight of Material-Force

Weight of Displacer

Go Weight of Material = Weight on Force Sensor+Force

Flat Spiral Spring Controlling Torque Formula

Flat Spiral Spring Controlling Torque = (Youngs Modulus*Width of Spring*(Thickness of Spring^3))/(12*Length)
T_ci = (E*b*(t^3))/(12*l)

What is the spring constant k?

The letter k represents the “spring constant,” a number that essentially tells us how “stiff” a spring is. If you have a large value of k, that means more force is required to stretch it a certain length than you would need to stretch a less stiff spring the same length.

How to Calculate Flat Spiral Spring Controlling Torque?

Flat Spiral Spring Controlling Torque calculator uses Flat Spiral Spring Controlling Torque = (Youngs Modulus*Width of Spring*(Thickness of Spring^3))/(12*Length) to calculate the Flat Spiral Spring Controlling Torque, The Flat Spiral Spring Controlling Torque formula is defined as the controlling torque is provided by two phosphorous bronze flat coiled helical springs. These springs serve as a flexible connection to the coil conductors. Damping is caused by the eddy current set up in the aluminum coil which prevents the oscillation of the coil. Flat Spiral Spring Controlling Torque is denoted by T_ci symbol.

How to calculate Flat Spiral Spring Controlling Torque using this online calculator? To use this online calculator for Flat Spiral Spring Controlling Torque, enter Youngs Modulus (E), Width of Spring (b), Thickness of Spring (t) & Length (l) and hit the calculate button. Here is how the Flat Spiral Spring Controlling Torque calculation can be explained with given input values -> 1231.175 = (1000*2.22*(5.5^3))/(12*0.25).

FAQ

What is Flat Spiral Spring Controlling Torque?

The Flat Spiral Spring Controlling Torque formula is defined as the controlling torque is provided by two phosphorous bronze flat coiled helical springs. These springs serve as a flexible connection to the coil conductors. Damping is caused by the eddy current set up in the aluminum coil which prevents the oscillation of the coil and is represented as T_ci = (E*b*(t^3))/(12*l) or Flat Spiral Spring Controlling Torque = (Youngs Modulus*Width of Spring*(Thickness of Spring^3))/(12*Length). Youngs Modulus is a mechanical property of linear elastic solid substances. It describes the relationship between longitudinal stress and longitudinal strain, Width of Spring is defined as the total width of the spring when measured in the extended form, Thickness of Spring is an important as Springs made of fat material are stiffer than those made of thin material & Length is the measurement or extent of something from end to end.

How to calculate Flat Spiral Spring Controlling Torque?

The Flat Spiral Spring Controlling Torque formula is defined as the controlling torque is provided by two phosphorous bronze flat coiled helical springs. These springs serve as a flexible connection to the coil conductors. Damping is caused by the eddy current set up in the aluminum coil which prevents the oscillation of the coil is calculated using Flat Spiral Spring Controlling Torque = (Youngs Modulus*Width of Spring*(Thickness of Spring^3))/(12*Length). To calculate Flat Spiral Spring Controlling Torque, you need Youngs Modulus (E), Width of Spring (b), Thickness of Spring (t) & Length (l). With our tool, you need to enter the respective value for Youngs Modulus, Width of Spring, Thickness of Spring & Length and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

How many ways are there to calculate Flat Spiral Spring Controlling Torque?

In this formula, Flat Spiral Spring Controlling Torque uses Youngs Modulus, Width of Spring, Thickness of Spring & Length. We can use 1 other way(s) to calculate the same, which is/are as follows -

Flat Spiral Spring Controlling Torque = Deflection of Pointer/Angle of Deflection of Galvanometer

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