Stress due to Internal Pressure Solution

STEP 0: Pre-Calculation Summary
Formula Used
Stress due to Internal Pressure = (Internal Design Pressure*Vessel Diameter)/(2*Shell Thickness)
fcs1 = (p*D)/(2*t)
This formula uses 4 Variables
Variables Used
Stress due to Internal Pressure - (Measured in Newton per Square Millimeter) - Stress due to Internal Pressure refers to the amount of pressure-induced stress exerted on the walls of a container or vessel due to the presence of fluids or gases inside.
Internal Design Pressure - (Measured in Newton per Square Millimeter) - Internal Design Pressure is a measure of how the internal energy of a system changes when it expands or contracts at constant temperature.
Vessel Diameter - (Measured in Millimeter) - Vessel diameter refers to the width or the cross-sectional dimension of a vessel, typically measured at its widest point.
Shell Thickness - (Measured in Millimeter) - Shell thickness is the the distance through the shell.
STEP 1: Convert Input(s) to Base Unit
Internal Design Pressure: 0.7 Newton per Square Millimeter --> 0.7 Newton per Square Millimeter No Conversion Required
Vessel Diameter: 80000000 Millimeter --> 80000000 Millimeter No Conversion Required
Shell Thickness: 200 Millimeter --> 200 Millimeter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
fcs1 = (p*D)/(2*t) --> (0.7*80000000)/(2*200)
Evaluating ... ...
fcs1 = 140000
STEP 3: Convert Result to Output's Unit
140000000000 Pascal -->140000 Newton per Square Millimeter (Check conversion here)
FINAL ANSWER
140000 Newton per Square Millimeter <-- Stress due to Internal Pressure
(Calculation completed in 00.004 seconds)

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14 Design of Anchor Bolt & Bolting Chair Calculators

Maximum Stress in Horizontal Plate fixed at Edges
Go Maximum Stress in Horizontal Plate fixed at Edges = 0.7*Maximum Pressure on Horizontal Plate*((Length of Horizontal Plate)^(2)/(Thickness of Horizontal Plate)^(2))*((Effective Width of Horizontal Plate)^(4)/((Length of Horizontal Plate)^(4)+(Effective Width of Horizontal Plate))^(4))
Wind Pressure acting on Upper Part of Vessel
Go Wind Pressure acting on Upper Part of Vessel = Wind Load acting on Upper Part of Vessel/(Coefficient depending on Shape Factor*Coefficient Period of One Cycle of Vibration*Height of Upper Part of Vessel*Outside Diameter of Vessel)
Wind Pressure acting on Lower Part of Vessel
Go Wind Pressure acting on Lower Part of Vessel = Wind Load acting on Lower Part of Vessel/(Coefficient depending on Shape Factor*Coefficient Period of One Cycle of Vibration*Height of Lower Part of Vessel*Outside Diameter of Vessel)
Height of Lower Part of Vessel
Go Height of Lower Part of Vessel = Wind Load acting on Lower Part of Vessel/(Coefficient depending on Shape Factor*Coefficient Period of One Cycle of Vibration*Wind Pressure acting on Lower Part of Vessel*Outside Diameter of Vessel)
Height of Upper Part of Vessel
Go Height of Upper Part of Vessel = Wind Load acting on Upper Part of Vessel/(Coefficient depending on Shape Factor*Coefficient Period of One Cycle of Vibration*Wind Pressure acting on Upper Part of Vessel*Outside Diameter of Vessel)
Diameter of Anchor Bolt Circle
Go Diameter of Anchor Bolt Circle = ((4*(Total Wind Force acting on Vessel))*(Height of Vessel above Foundation-Clearance between Vessel Bottom and Foundation))/(Number of Brackets*Maximum Compressive Load on Remote Bracket)
Mean Diameter of Skirt in Vessel
Go Mean Diameter of Skirt = ((4*Maximum Wind Moment)/((pi*(Axial Bending Stress at Base of Vessel)*Thickness of Skirt)))^(0.5)
Maximum Compressive Load
Go Maximum Compressive Load on Remote Bracket = Maximum Pressure on Horizontal Plate*(Length of Horizontal Plate*Effective Width of Horizontal Plate)
Load on Each Bolt
Go Load on Each Bolt = Stress in Bearing Plate and Concrete Foundation*(Area of Contact in Bearing Plate and Foundation/Number of Bolts)
Maximum Seismic Moment
Go Maximum Seismic Moment = ((2/3)*Seismic Coefficient*Total Weight of Vessel*Total Height of Vessel)
Stress due to Internal Pressure
Go Stress due to Internal Pressure = (Internal Design Pressure*Vessel Diameter)/(2*Shell Thickness)
Cross Sectional Area of Bolt
Go Cross Sectional Area of Bolt = Load on Each Bolt/Permissible Stress for Bolt Materials
Diameter of Bolt given Cross Sectional Area
Go Diameter of Bolt = (Cross Sectional Area of Bolt*(4/pi))^(0.5)
Number of Bolts
Go Number of Bolts = (pi*Mean Diameter of Skirt)/600

Stress due to Internal Pressure Formula

Stress due to Internal Pressure = (Internal Design Pressure*Vessel Diameter)/(2*Shell Thickness)
fcs1 = (p*D)/(2*t)

What is Design Pressure?

Design pressure refers to the maximum allowable pressure that a vessel, pipeline, or other pressure-containing component can withstand under certain design conditions without experiencing deformation or failure. It is a crucial factor in the design and construction of pressure vessels and piping systems in various industries, including oil and gas, chemical, and manufacturing. Design pressure is typically determined based on several factors, including the type of fluid or gas being transported, the temperature and pressure of the fluid or gas, and the materials used in the construction of the vessel or pipeline. The design pressure is also influenced by other factors such as the design life of the component, the frequency and severity of pressure cycles, and the potential for external loads such as wind or seismic activity.

How to Calculate Stress due to Internal Pressure?

Stress due to Internal Pressure calculator uses Stress due to Internal Pressure = (Internal Design Pressure*Vessel Diameter)/(2*Shell Thickness) to calculate the Stress due to Internal Pressure, Stress due to Internal Pressure refers to the amount of pressure-induced stress exerted on the walls of a container or vessel due to the presence of fluids or gases inside. Stress due to Internal Pressure is denoted by fcs1 symbol.

How to calculate Stress due to Internal Pressure using this online calculator? To use this online calculator for Stress due to Internal Pressure, enter Internal Design Pressure (p), Vessel Diameter (D) & Shell Thickness (t) and hit the calculate button. Here is how the Stress due to Internal Pressure calculation can be explained with given input values -> 0.14 = (700000*80000)/(2*0.2).

FAQ

What is Stress due to Internal Pressure?
Stress due to Internal Pressure refers to the amount of pressure-induced stress exerted on the walls of a container or vessel due to the presence of fluids or gases inside and is represented as fcs1 = (p*D)/(2*t) or Stress due to Internal Pressure = (Internal Design Pressure*Vessel Diameter)/(2*Shell Thickness). Internal Design Pressure is a measure of how the internal energy of a system changes when it expands or contracts at constant temperature, Vessel diameter refers to the width or the cross-sectional dimension of a vessel, typically measured at its widest point & Shell thickness is the the distance through the shell.
How to calculate Stress due to Internal Pressure?
Stress due to Internal Pressure refers to the amount of pressure-induced stress exerted on the walls of a container or vessel due to the presence of fluids or gases inside is calculated using Stress due to Internal Pressure = (Internal Design Pressure*Vessel Diameter)/(2*Shell Thickness). To calculate Stress due to Internal Pressure, you need Internal Design Pressure (p), Vessel Diameter (D) & Shell Thickness (t). With our tool, you need to enter the respective value for Internal Design Pressure, Vessel Diameter & Shell Thickness 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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