Maximum Force on Spring given Mean Force Solution

STEP 0: Pre-Calculation Summary
Formula Used
Maximum Force of Spring = 2*Mean Spring Force-Minimum Force of Spring
Pmax = 2*Pm-Pmin
This formula uses 3 Variables
Variables Used
Maximum Force of Spring - (Measured in Newton) - The Maximum Force of Spring is defined as the maximum of the fluctuating Forces acting onto or exerted by the spring.
Mean Spring Force - (Measured in Newton) - Mean Spring Force is defined as the average of the maximum force and the minimum force of the fluctuating forces on the spring or by the spring.
Minimum Force of Spring - (Measured in Newton) - Minimum Force of Spring is defined as the minimum force of the Fluctuating forces onto a spring or by a spring.
STEP 1: Convert Input(s) to Base Unit
Mean Spring Force: 101.2 Newton --> 101.2 Newton No Conversion Required
Minimum Force of Spring: 49.8 Newton --> 49.8 Newton No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Pmax = 2*Pm-Pmin --> 2*101.2-49.8
Evaluating ... ...
Pmax = 152.6
STEP 3: Convert Result to Output's Unit
152.6 Newton --> No Conversion Required
FINAL ANSWER
152.6 Newton <-- Maximum Force of Spring
(Calculation completed in 00.004 seconds)

Credits

Created by Kethavath Srinath
Osmania University (OU), Hyderabad
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Vishwakarma Government Engineering College (VGEC), Ahmedabad
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22 Design Against Fluctuating Load Calculators

Diameter of Spring Wire given Torsional Stress Amplitude
Go Diameter of spring wire = (8*Shear Stress Correction Factor of Spring*Spring Force Amplitude*Mean Coil Diameter of Spring/(pi*Torsional Stress Amplitude in Spring))^(1/3)
Mean Coil Diameter of Spring given Torsional Stress Amplitude
Go Mean Coil Diameter of Spring = Torsional Stress Amplitude in Spring*(pi*Diameter of spring wire^3)/(8*Shear Stress Correction Factor of Spring*Spring Force Amplitude)
Force Amplitude on Spring given Torsional Stress Amplitude
Go Spring Force Amplitude = Torsional Stress Amplitude in Spring*(pi*Diameter of spring wire^3)/(8*Shear Stress Correction Factor of Spring*Mean Coil Diameter of Spring)
Torsional Stress Amplitude in Spring
Go Torsional Stress Amplitude in Spring = 8*Shear Stress Correction Factor of Spring*Spring Force Amplitude*Mean Coil Diameter of Spring/(pi*Diameter of spring wire^3)
Diameter of Spring Wire given Mean Stress in Spring
Go Diameter of spring wire = (8*Shear Stress Correction Factor of Spring*Mean Spring Force*Mean Coil Diameter of Spring/(pi*Mean Shear Stress in Spring))^(1/3)
Mean Diameter of Spring coil given Mean Stress on Spring
Go Mean Coil Diameter of Spring = (Mean Shear Stress in Spring*(pi*Diameter of spring wire^3)/(8*Shear Stress Correction Factor of Spring*Mean Spring Force))
Shear Stress Correction Factor for Spring given Mean Stress
Go Shear Stress Correction Factor of Spring = Mean Shear Stress in Spring*(pi*Diameter of spring wire^3)/(8*Mean Spring Force*Mean Coil Diameter of Spring)
Mean Force on Spring given Mean Stress
Go Mean Spring Force = Mean Shear Stress in Spring*(pi*Diameter of spring wire^3)/(8*Shear Stress Correction Factor of Spring*Mean Coil Diameter of Spring)
Spring Index given Torsional Stress Amplitude
Go Spring Index = Torsional Stress Amplitude in Spring*(pi*Diameter of spring wire^2)/(8*Shear Stress Correction Factor of Spring*Spring Force Amplitude)
Mean Stress on Spring
Go Mean Shear Stress in Spring = 8*Shear Stress Correction Factor of Spring*Mean Spring Force*Mean Coil Diameter of Spring/(pi*Diameter of spring wire^3)
Shear Stress Factor for Spring given Torsional stress amplitude
Go Wahl Factor of Spring = Mean Shear Stress in Spring*(pi*Diameter of spring wire^3)/(8*Spring Force Amplitude*Mean Coil Diameter of Spring)
Spring Index given Mean Stress on spring
Go Spring Index = Mean Shear Stress in Spring*(pi*Diameter of spring wire^2)/(8*Shear Stress Correction Factor of Spring*Mean Spring Force)
Force Amplitude of Spring
Go Spring Force Amplitude = .5*(Maximum Force of Spring-Minimum Force of Spring)
Minimum Force on Spring given Force Amplitude
Go Minimum Force of Spring = Maximum Force of Spring-(2*Spring Force Amplitude)
Maximum Force on Spring given Force Amplitude
Go Maximum Force of Spring = 2*Spring Force Amplitude+Minimum Force of Spring
Mean Force on spring
Go Mean Spring Force = (Minimum Force of Spring+Maximum Force of Spring)/2
Maximum Force on Spring given Mean Force
Go Maximum Force of Spring = 2*Mean Spring Force-Minimum Force of Spring
Minimum Force on Spring given Mean Force
Go Minimum Force of Spring = 2*Mean Spring Force-Maximum Force of Spring
Ultimate Tensile Stress of Patented and Cold drawn Steel wires
Go Ultimate tensile strength of spring = Shear yield strength of spring wire/0.42
Shear Yield Strength of Patented and Cold-drawn Steel Wires
Go Shear yield strength of spring wire = 0.42*Ultimate tensile strength of spring
Ultimate Tensile Stress of Ol hardened tempered Steel wires
Go Ultimate tensile strength of spring = Shear yield strength of spring wire/0.45
Shear Yield Strength of Oil-hardened Tempered Steel Wires
Go Shear yield strength of spring wire = 0.45*Ultimate tensile strength of spring

Maximum Force on Spring given Mean Force Formula

Maximum Force of Spring = 2*Mean Spring Force-Minimum Force of Spring
Pmax = 2*Pm-Pmin

Define a Fluctuating Force?

If an object is moving through a fluid, it experiences drag (air resistance or fluid resistance). Drag dissipates kinetic energy, turning it into heat. The corresponding fluctuation is Brownian motion. Brownian motion converts heat energy into kinetic energy—the reverse of drag.

How to Calculate Maximum Force on Spring given Mean Force?

Maximum Force on Spring given Mean Force calculator uses Maximum Force of Spring = 2*Mean Spring Force-Minimum Force of Spring to calculate the Maximum Force of Spring, The Maximum Force on Spring given Mean Force formula is defined as the maximum force among all the fluctuating forces. Maximum Force of Spring is denoted by Pmax symbol.

How to calculate Maximum Force on Spring given Mean Force using this online calculator? To use this online calculator for Maximum Force on Spring given Mean Force, enter Mean Spring Force (Pm) & Minimum Force of Spring (Pmin) and hit the calculate button. Here is how the Maximum Force on Spring given Mean Force calculation can be explained with given input values -> 152.6 = 2*101.2-49.8.

FAQ

What is Maximum Force on Spring given Mean Force?
The Maximum Force on Spring given Mean Force formula is defined as the maximum force among all the fluctuating forces and is represented as Pmax = 2*Pm-Pmin or Maximum Force of Spring = 2*Mean Spring Force-Minimum Force of Spring. Mean Spring Force is defined as the average of the maximum force and the minimum force of the fluctuating forces on the spring or by the spring & Minimum Force of Spring is defined as the minimum force of the Fluctuating forces onto a spring or by a spring.
How to calculate Maximum Force on Spring given Mean Force?
The Maximum Force on Spring given Mean Force formula is defined as the maximum force among all the fluctuating forces is calculated using Maximum Force of Spring = 2*Mean Spring Force-Minimum Force of Spring. To calculate Maximum Force on Spring given Mean Force, you need Mean Spring Force (Pm) & Minimum Force of Spring (Pmin). With our tool, you need to enter the respective value for Mean Spring Force & Minimum Force of Spring 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 Maximum Force of Spring?
In this formula, Maximum Force of Spring uses Mean Spring Force & Minimum Force of Spring. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Maximum Force of Spring = 2*Spring Force Amplitude+Minimum Force of Spring
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