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Maximum Load inside Cylinder when the Joint is on Verge of Opening Solution

STEP 0: Pre-Calculation Summary
Formula Used
maximum_force = Initial Preload Due to Bolt Tightening*((Combined stiffness+stiffness of the bolt)/stiffness of the bolt)
Pmax = Pl*((Kc+kb)/kb)
This formula uses 3 Variables
Variables Used
Initial Preload Due to Bolt Tightening - The Initial Preload Due to Bolt Tightening value (Measured in Newton)
Combined stiffness- Combined stiffness is the combined values of stiffness of two springs
stiffness of the bolt - stiffness of the bolt is the extent to which bolt resists deformation in response to an applied force. (Measured in Newton per Meter)
STEP 1: Convert Input(s) to Base Unit
Initial Preload Due to Bolt Tightening: 1 Newton --> 1 Newton No Conversion Required
Combined stiffness: 10 --> No Conversion Required
stiffness of the bolt: 1 Newton per Meter --> 1 Newton per Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Pmax = Pl*((Kc+kb)/kb) --> 1*((10+1)/1)
Evaluating ... ...
Pmax = 11
STEP 3: Convert Result to Output's Unit
11 Newton --> No Conversion Required
FINAL ANSWER
11 Newton <-- Maximum Force
(Calculation completed in 00.030 seconds)

10+ Design of Pressure Vessels Calculators

Longitudinal Stress in a Thin Cylinder in Terms of Internal Pressure
longitudinal_stress = Internal Pressure*Inner Diameter/(4*Thickness of Cylinder Wall) Go
Cylinder Wall Thickness of a Thin Cylinder in Terms of Longitudinal Stress
thickness_of_cylinder_wall = Internal Pressure*Inner Diameter/(4*Tangential stress) Go
Cylinder Wall Thickness of a Thin Cylinder in Terms of Tangential Stress
thickness_of_cylinder_wall = Internal Pressure*Inner Diameter/(2*Tangential stress) Go
Tangential Stress in a Thin Cylinder in Terms of Internal Pressure
tangential_stress = Internal Pressure*Inner Diameter/(2*Thickness of Cylinder Wall) Go
Internal Pressure of a Thin Cylinder in Terms of Longitudinal Stress
internal_pressure = 4*Thickness of Cylinder Wall*Tangential stress/Inner Diameter Go
Internal Pressure of a Thin Cylinder in Terms of Tangential Stress
internal_pressure = 2*Thickness of Cylinder Wall*Tangential stress/Inner Diameter Go
Inner Diameter of a Thin Cylinder in Terms of Longitudinal Stress
inner_diameter = 4*Thickness of Cylinder Wall*Tangential stress/Internal Pressure Go
Inner Diameter of a Thin Cylinder in Terms of Tangential Stress
inner_diameter = 2*Thickness of Cylinder Wall*Tangential stress/Internal Pressure Go
Permissible Tensile Stress of a Thin Spherical Shell
permissible_tensile_stress = Internal Pressure*Inner Diameter/(4*Thickness) Go
Internal Pressure of a Thin Spherical Shell in Terms of Permissible Tensile Stress
internal_pressure = 4*Thickness*Permissible Tensile Stress/Inner Diameter Go

Maximum Load inside Cylinder when the Joint is on Verge of Opening Formula

maximum_force = Initial Preload Due to Bolt Tightening*((Combined stiffness+stiffness of the bolt)/stiffness of the bolt)
Pmax = Pl*((Kc+kb)/kb)

What is a Pressure Vessel?

A pressure vessel is a container designed to hold gases or liquids at a pressure substantially different from the ambient pressure.

How to Calculate Maximum Load inside Cylinder when the Joint is on Verge of Opening?

Maximum Load inside Cylinder when the Joint is on Verge of Opening calculator uses maximum_force = Initial Preload Due to Bolt Tightening*((Combined stiffness+stiffness of the bolt)/stiffness of the bolt) to calculate the Maximum Force, The Maximum Load inside Cylinder when the Joint is on Verge of Opening formula is defined as the product of the initial preload due to the bolt tightening and the ratio of the sum of combined stiffness and stiffness of the bolt to the stiffness of the bolt. Maximum Force and is denoted by Pmax symbol.

How to calculate Maximum Load inside Cylinder when the Joint is on Verge of Opening using this online calculator? To use this online calculator for Maximum Load inside Cylinder when the Joint is on Verge of Opening, enter Initial Preload Due to Bolt Tightening (Pl), Combined stiffness (Kc) and stiffness of the bolt (kb) and hit the calculate button. Here is how the Maximum Load inside Cylinder when the Joint is on Verge of Opening calculation can be explained with given input values -> 11 = 1*((10+1)/1).

FAQ

What is Maximum Load inside Cylinder when the Joint is on Verge of Opening?
The Maximum Load inside Cylinder when the Joint is on Verge of Opening formula is defined as the product of the initial preload due to the bolt tightening and the ratio of the sum of combined stiffness and stiffness of the bolt to the stiffness of the bolt and is represented as Pmax = Pl*((Kc+kb)/kb) or maximum_force = Initial Preload Due to Bolt Tightening*((Combined stiffness+stiffness of the bolt)/stiffness of the bolt). The Initial Preload Due to Bolt Tightening value, Combined stiffness is the combined values of stiffness of two springs and stiffness of the bolt is the extent to which bolt resists deformation in response to an applied force.
How to calculate Maximum Load inside Cylinder when the Joint is on Verge of Opening?
The Maximum Load inside Cylinder when the Joint is on Verge of Opening formula is defined as the product of the initial preload due to the bolt tightening and the ratio of the sum of combined stiffness and stiffness of the bolt to the stiffness of the bolt is calculated using maximum_force = Initial Preload Due to Bolt Tightening*((Combined stiffness+stiffness of the bolt)/stiffness of the bolt). To calculate Maximum Load inside Cylinder when the Joint is on Verge of Opening, you need Initial Preload Due to Bolt Tightening (Pl), Combined stiffness (Kc) and stiffness of the bolt (kb). With our tool, you need to enter the respective value for Initial Preload Due to Bolt Tightening, Combined stiffness and stiffness of the bolt 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?
In this formula, Maximum Force uses Initial Preload Due to Bolt Tightening, Combined stiffness and stiffness of the bolt. We can use 10 other way(s) to calculate the same, which is/are as follows -
  • tangential_stress = Internal Pressure*Inner Diameter/(2*Thickness of Cylinder Wall)
  • internal_pressure = 2*Thickness of Cylinder Wall*Tangential stress/Inner Diameter
  • inner_diameter = 2*Thickness of Cylinder Wall*Tangential stress/Internal Pressure
  • thickness_of_cylinder_wall = Internal Pressure*Inner Diameter/(2*Tangential stress)
  • longitudinal_stress = Internal Pressure*Inner Diameter/(4*Thickness of Cylinder Wall)
  • internal_pressure = 4*Thickness of Cylinder Wall*Tangential stress/Inner Diameter
  • inner_diameter = 4*Thickness of Cylinder Wall*Tangential stress/Internal Pressure
  • thickness_of_cylinder_wall = Internal Pressure*Inner Diameter/(4*Tangential stress)
  • permissible_tensile_stress = Internal Pressure*Inner Diameter/(4*Thickness)
  • internal_pressure = 4*Thickness*Permissible Tensile Stress/Inner Diameter
Where is the Maximum Load inside Cylinder when the Joint is on Verge of Opening calculator used?
Among many, Maximum Load inside Cylinder when the Joint is on Verge of Opening calculator is widely used in real life applications like {FormulaUses}. Here are few more real life examples -
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