Axial Bending Stress due to Wind Load at Base of Vessel Calculator

✖Maximum Wind Moment is calculated based on a number of factors, including the wind speed and direction, the size and shape of the building or structure, the materials used in construction.ⓘ Maximum Wind Moment [M_w]			+10% -10%
✖Mean Diameter of Skirt in a vessel will depend on the size and design of the vessel.ⓘ Mean Diameter of Skirt [D_sk]			+10% -10%
✖Thickness of Skirt is typically determined by calculating the maximum stress that the skirt is likely to experience and their must be sufficient to resist the weight of the vessel.ⓘ Thickness of Skirt [t_sk]			+10% -10%

✖Axial Bending Stress at Base of Vessel refers to the stress that occurs when wind exerts a force on the vessel, causing it to bend or deform.ⓘ Axial Bending Stress due to Wind Load at Base of Vessel [f_wb]

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Axial Bending Stress due to Wind Load at Base of Vessel Solution

STEP 0: Pre-Calculation Summary

Formula Used

Axial Bending Stress at Base of Vessel = (4*Maximum Wind Moment)/(pi*(Mean Diameter of Skirt)^(2)*Thickness of Skirt)
f_wb = (4*M_w)/(pi*(D_sk)^(2)*t_sk)
This formula uses 1 Constants, 4 Variables

Constants Used

pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288

Variables Used

Axial Bending Stress at Base of Vessel - (Measured in Newton per Square Millimeter) - Axial Bending Stress at Base of Vessel refers to the stress that occurs when wind exerts a force on the vessel, causing it to bend or deform.
Maximum Wind Moment - (Measured in Newton Meter) - Maximum Wind Moment is calculated based on a number of factors, including the wind speed and direction, the size and shape of the building or structure, the materials used in construction.
Mean Diameter of Skirt - (Measured in Millimeter) - Mean Diameter of Skirt in a vessel will depend on the size and design of the vessel.
Thickness of Skirt - (Measured in Millimeter) - Thickness of Skirt is typically determined by calculating the maximum stress that the skirt is likely to experience and their must be sufficient to resist the weight of the vessel.

STEP 1: Convert Input(s) to Base Unit

Maximum Wind Moment: 370440000 Newton Millimeter --> 370440 Newton Meter (Check conversion here)
Mean Diameter of Skirt: 19893.55 Millimeter --> 19893.55 Millimeter No Conversion Required
Thickness of Skirt: 1.18 Millimeter --> 1.18 Millimeter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

f_wb = (4*M_w)/(pi*(D_sk)^(2)*t_sk) --> (4*370440)/(pi*(19893.55)^(2)*1.18)

Evaluating ... ...

f_wb = 0.00101000007783447

STEP 3: Convert Result to Output's Unit

1010.00007783447 Pascal -->0.00101000007783447 Newton per Square Millimeter (Check conversion here)

FINAL ANSWER

0.00101000007783447 ≈ 0.00101 Newton per Square Millimeter <-- Axial Bending Stress at Base of Vessel

(Calculation completed in 00.004 seconds)

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< Design Thickness of Skirt Calculators

Wind Load acting on Lower Part of Vessel

LaTeX Go 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*Height of Lower Part of Vessel*Outside Diameter of Vessel

Wind Load acting on Upper Part of Vessel

LaTeX Go 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*Height of Upper Part of Vessel*Outside Diameter of Vessel

Axial Bending Stress due to Wind Load at Base of Vessel

LaTeX Go Axial Bending Stress at Base of Vessel = (4*Maximum Wind Moment)/(pi*(Mean Diameter of Skirt)^(2)*Thickness of Skirt)

Maximum Bending Stress in Base Ring Plate

LaTeX Go Maximum Bending Stress in Base Ring Plate = (6*Maximum Bending Moment)/(Circumferential Length of Bearing Plate*Thickness of Base Bearing Plate^(2))

Axial Bending Stress due to Wind Load at Base of Vessel Formula

LaTeX Go

Axial Bending Stress at Base of Vessel = (4*Maximum Wind Moment)/(pi*(Mean Diameter of Skirt)^(2)*Thickness of Skirt)
f_wb = (4*M_w)/(pi*(D_sk)^(2)*t_sk)

What is Design Stress?

Design stress is a term used in engineering to refer to the maximum amount of stress that a material or structure is designed to withstand without failing or experiencing deformation beyond acceptable limits. It is a critical parameter in the design process of any structure or machine, as exceeding the design stress can lead to failure or catastrophic consequences. To determine the design stress for a particular material or structure, engineers consider a variety of factors such as the material's properties, the anticipated loads and forces that will be applied, and the safety factors required to ensure that the structure can withstand unexpected events such as earthquakes or extreme weather conditions. In general, the design stress is calculated to be lower than the material's ultimate strength, which is the maximum stress the material can withstand before it fails completely.

How to Calculate Axial Bending Stress due to Wind Load at Base of Vessel?

Axial Bending Stress due to Wind Load at Base of Vessel calculator uses Axial Bending Stress at Base of Vessel = (4*Maximum Wind Moment)/(pi*(Mean Diameter of Skirt)^(2)*Thickness of Skirt) to calculate the Axial Bending Stress at Base of Vessel, Axial Bending Stress due to Wind Load at Base of Vessel refers to the stress that occurs when wind exerts a force on the vessel, causing it to bend or deform. Axial Bending Stress at Base of Vessel is denoted by f_wb symbol.

How to calculate Axial Bending Stress due to Wind Load at Base of Vessel using this online calculator? To use this online calculator for Axial Bending Stress due to Wind Load at Base of Vessel, enter Maximum Wind Moment (M_w), Mean Diameter of Skirt (D_sk) & Thickness of Skirt (t_sk) and hit the calculate button. Here is how the Axial Bending Stress due to Wind Load at Base of Vessel calculation can be explained with given input values -> 1E-9 = (4*370440)/(pi*(19.89355)^(2)*0.00118).

FAQ

What is Axial Bending Stress due to Wind Load at Base of Vessel?

Axial Bending Stress due to Wind Load at Base of Vessel refers to the stress that occurs when wind exerts a force on the vessel, causing it to bend or deform and is represented as f_wb = (4*M_w)/(pi*(D_sk)^(2)*t_sk) or Axial Bending Stress at Base of Vessel = (4*Maximum Wind Moment)/(pi*(Mean Diameter of Skirt)^(2)*Thickness of Skirt). Maximum Wind Moment is calculated based on a number of factors, including the wind speed and direction, the size and shape of the building or structure, the materials used in construction, Mean Diameter of Skirt in a vessel will depend on the size and design of the vessel & Thickness of Skirt is typically determined by calculating the maximum stress that the skirt is likely to experience and their must be sufficient to resist the weight of the vessel.

How to calculate Axial Bending Stress due to Wind Load at Base of Vessel?

Axial Bending Stress due to Wind Load at Base of Vessel refers to the stress that occurs when wind exerts a force on the vessel, causing it to bend or deform is calculated using Axial Bending Stress at Base of Vessel = (4*Maximum Wind Moment)/(pi*(Mean Diameter of Skirt)^(2)*Thickness of Skirt). To calculate Axial Bending Stress due to Wind Load at Base of Vessel, you need Maximum Wind Moment (M_w), Mean Diameter of Skirt (D_sk) & Thickness of Skirt (t_sk). With our tool, you need to enter the respective value for Maximum Wind Moment, Mean Diameter of Skirt & Thickness of Skirt 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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