Maximum Load inside Pressurized Cylinder when Joint is on verge of opening Calculator

✖Initial preload due to bolt tightening value is the tension created in a fastener when it is tightened.ⓘ Initial Preload Due to Bolt Tightening [P_l]			+10% -10%
✖Combined stiffness for gasket joint is the combined values of stiffness of cylinder cover, cylinder flange, and gasket.ⓘ Combined stiffness for gasket joint [k_c]			+10% -10%
✖Stiffness of pressurized cylinder bolt is the extent to which the bolt resists deformation in response to an applied force.ⓘ Stiffness of pressurized cylinder bolt [k_b]			+10% -10%

✖Maximum force inside pressurized cylinder is the maximum load (force) inside the cylinder when the joint is on the verge of opening or the capacity of the cylinder to bear the load (N).ⓘ Maximum Load inside Pressurized Cylinder when Joint is on verge of opening [P_max]

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Formula

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Maximum Load inside Pressurized Cylinder when Joint is on verge of opening

Formula

`"P"_{"max"} = "P"_{"l"}*(("k"_{"c"}+"k"_{"b"})/"k"_{"b"})`

Example

`"96271.19N"="20000N"*(("4500kN/mm"+"1180kN/mm")/"1180kN/mm")`

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Maximum Load inside Pressurized Cylinder when Joint is on verge of opening Solution

STEP 0: Pre-Calculation Summary

Formula Used

Maximum force inside pressurized cylinder = Initial Preload Due to Bolt Tightening*((Combined stiffness for gasket joint+Stiffness of pressurized cylinder bolt)/Stiffness of pressurized cylinder bolt)
P_max = P_l*((k_c+k_b)/k_b)
This formula uses 4 Variables

Variables Used

Maximum force inside pressurized cylinder - (Measured in Newton) - Maximum force inside pressurized cylinder is the maximum load (force) inside the cylinder when the joint is on the verge of opening or the capacity of the cylinder to bear the load (N).
Initial Preload Due to Bolt Tightening - (Measured in Newton) - Initial preload due to bolt tightening value is the tension created in a fastener when it is tightened.
Combined stiffness for gasket joint - (Measured in Newton per Meter) - Combined stiffness for gasket joint is the combined values of stiffness of cylinder cover, cylinder flange, and gasket.
Stiffness of pressurized cylinder bolt - (Measured in Newton per Meter) - Stiffness of pressurized cylinder bolt is the extent to which the bolt resists deformation in response to an applied force.

STEP 1: Convert Input(s) to Base Unit

Initial Preload Due to Bolt Tightening: 20000 Newton --> 20000 Newton No Conversion Required
Combined stiffness for gasket joint: 4500 Kilonewton per Millimeter --> 4500000000 Newton per Meter (Check conversion here)
Stiffness of pressurized cylinder bolt: 1180 Kilonewton per Millimeter --> 1180000000 Newton per Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

P_max = P_l*((k_c+k_b)/k_b) --> 20000*((4500000000+1180000000)/1180000000)

Evaluating ... ...

P_max = 96271.186440678

STEP 3: Convert Result to Output's Unit

96271.186440678 Newton --> No Conversion Required

FINAL ANSWER

96271.186440678 ≈ 96271.19 Newton <-- Maximum force inside pressurized cylinder

(Calculation completed in 00.004 seconds)

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Created by Vaibhav Malani

National Institute of Technology (NIT), Tiruchirapalli

Vaibhav Malani has created this Calculator and 600+ more calculators!

Verified by Anshika Arya

National Institute Of Technology (NIT), Hamirpur

Anshika Arya has verified this Calculator and 2500+ more calculators!

< 10+ Bolt of Pressurized Cylinder Calculators

Thickness of Pressurized Cylinder

Go Thickness of pressurized cylinder wall = (Inner diameter of pressurized cylinder/2)*((((Permissible Tensile stress in pressurized cylinder+Internal pressure on cylinder)/(Permissible Tensile stress in pressurized cylinder-Internal pressure on cylinder))^(1/2))-1)

Internal Diameter of Pressurized Cylinder

Go Inner diameter of pressurized cylinder = 2*Thickness of pressurized cylinder wall/((((Permissible Tensile stress in pressurized cylinder+Internal pressure on cylinder)/(Permissible Tensile stress in pressurized cylinder-Internal pressure on cylinder))^(1/2))-1)

Maximum Load inside Pressurized Cylinder when Joint is on verge of opening

Go Maximum force inside pressurized cylinder = Initial Preload Due to Bolt Tightening*((Combined stiffness for gasket joint+Stiffness of pressurized cylinder bolt)/Stiffness of pressurized cylinder bolt)

Initial Preload due to Bolt tightening given kb and kc

Go Initial Preload Due to Bolt Tightening = Maximum force inside pressurized cylinder*(Stiffness of pressurized cylinder bolt/(Combined stiffness for gasket joint+Stiffness of pressurized cylinder bolt))

Change in External Load due to Pressure Inside Cylinder given kb and kc

Go Increase in Bolt Load of Cylinder = External load on pressurized cylinder bolt*(Stiffness of pressurized cylinder bolt/(Combined stiffness for gasket joint+Stiffness of pressurized cylinder bolt))

External Load on Bolt due to Internal Pressure given kb and kc

Go External load on pressurized cylinder bolt = Increase in Bolt Load of Cylinder*((Combined stiffness for gasket joint+Stiffness of pressurized cylinder bolt)/Stiffness of pressurized cylinder bolt)

Change in External Load on Bolt due to Pressure Inside Cylinder

Go Increase in Bolt Load of Cylinder = Resultant load on pressurized cylinder bolt-Initial Preload Due to Bolt Tightening

Initial Preload due to Bolt tightening

Go Initial Preload Due to Bolt Tightening = Resultant load on pressurized cylinder bolt-Increase in Bolt Load of Cylinder

Resultant Load on Bolt given Pre load

Go Resultant load on pressurized cylinder bolt = Initial Preload Due to Bolt Tightening+Increase in Bolt Load of Cylinder

Decrease in Outer Diameter of Cylinder given Total deformation in Pressure Vessel

Go Decrease in Outer Diameter of Cylinder = Total Deformation of Pressure Vessel-Increase in Inner Diameter of Jacket

Maximum Load inside Pressurized Cylinder when Joint is on verge of opening Formula

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 Pressurized Cylinder when Joint is on verge of opening?

Maximum Load inside Pressurized Cylinder when Joint is on verge of opening calculator uses Maximum force inside pressurized cylinder = Initial Preload Due to Bolt Tightening*((Combined stiffness for gasket joint+Stiffness of pressurized cylinder bolt)/Stiffness of pressurized cylinder bolt) to calculate the Maximum force inside pressurized cylinder, Maximum Load inside Pressurized Cylinder when Joint is on verge of opening formula is defined as the maximum load inside the pressurized cylindrical vessel. Maximum force inside pressurized cylinder is denoted by P_max symbol.

How to calculate Maximum Load inside Pressurized Cylinder when Joint is on verge of opening using this online calculator? To use this online calculator for Maximum Load inside Pressurized Cylinder when Joint is on verge of opening, enter Initial Preload Due to Bolt Tightening (P_l), Combined stiffness for gasket joint (k_c) & Stiffness of pressurized cylinder bolt (k_b) and hit the calculate button. Here is how the Maximum Load inside Pressurized Cylinder when Joint is on verge of opening calculation can be explained with given input values -> 96271.19 = 20000*((4500000000+1180000000)/1180000000).

FAQ

What is Maximum Load inside Pressurized Cylinder when Joint is on verge of opening?

Maximum Load inside Pressurized Cylinder when Joint is on verge of opening formula is defined as the maximum load inside the pressurized cylindrical vessel and is represented as P_max = P_l*((k_c+k_b)/k_b) or Maximum force inside pressurized cylinder = Initial Preload Due to Bolt Tightening*((Combined stiffness for gasket joint+Stiffness of pressurized cylinder bolt)/Stiffness of pressurized cylinder bolt). Initial preload due to bolt tightening value is the tension created in a fastener when it is tightened, Combined stiffness for gasket joint is the combined values of stiffness of cylinder cover, cylinder flange, and gasket & Stiffness of pressurized cylinder bolt is the extent to which the bolt resists deformation in response to an applied force.

How to calculate Maximum Load inside Pressurized Cylinder when Joint is on verge of opening?

Maximum Load inside Pressurized Cylinder when Joint is on verge of opening formula is defined as the maximum load inside the pressurized cylindrical vessel is calculated using Maximum force inside pressurized cylinder = Initial Preload Due to Bolt Tightening*((Combined stiffness for gasket joint+Stiffness of pressurized cylinder bolt)/Stiffness of pressurized cylinder bolt). To calculate Maximum Load inside Pressurized Cylinder when Joint is on verge of opening, you need Initial Preload Due to Bolt Tightening (P_l), Combined stiffness for gasket joint (k_c) & Stiffness of pressurized cylinder bolt (k_b). With our tool, you need to enter the respective value for Initial Preload Due to Bolt Tightening, Combined stiffness for gasket joint & Stiffness of pressurized cylinder bolt and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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