Length of Top Weld given Axial Load on Weld Calculator

✖Axial Load on Weld is defined as applying a force on a structure directly along an axis of the structure.ⓘ Axial Load on Weld [P_weld]			+10% -10%
✖Shear Stress is force tending to cause deformation of a material by slippage along a plane or planes parallel to the imposed stress.ⓘ Shear Stress [𝜏]			+10% -10%
✖The thickness of plate is the state or quality of being thick. The measure of the smallest dimension of a solid figure: a board of two-inch thickness.ⓘ Thickness of Plate [t_plate]			+10% -10%
✖Length of bottom weld is the linear distance of each weld segment.ⓘ Length of Bottom Weld [L₂]			+10% -10%

✖Length of top weld is the linear distance of each weld segment.ⓘ Length of Top Weld given Axial Load on Weld [L_{top weld}]

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Formula

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Length of Top Weld given Axial Load on Weld

Formula

`"L"_{"top weld"} = "P"_{"weld"}/("𝜏"*0.707*"t"_{"plate"})-"L"_{"2"}`

Example

`"465.4757mm"="9.6kN"/("2.4MPa"*0.707*"12mm")-"6mm"`

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Length of Top Weld given Axial Load on Weld Solution

STEP 0: Pre-Calculation Summary

Formula Used

Length of Top Weld = Axial Load on Weld/(Shear Stress*0.707*Thickness of Plate)-Length of Bottom Weld
L_{top weld} = P_weld/(𝜏*0.707*t_plate)-L₂
This formula uses 5 Variables

Variables Used

Length of Top Weld - (Measured in Meter) - Length of top weld is the linear distance of each weld segment.
Axial Load on Weld - (Measured in Newton) - Axial Load on Weld is defined as applying a force on a structure directly along an axis of the structure.
Shear Stress - (Measured in Pascal) - Shear Stress is force tending to cause deformation of a material by slippage along a plane or planes parallel to the imposed stress.
Thickness of Plate - (Measured in Meter) - The thickness of plate is the state or quality of being thick. The measure of the smallest dimension of a solid figure: a board of two-inch thickness.
Length of Bottom Weld - (Measured in Meter) - Length of bottom weld is the linear distance of each weld segment.

STEP 1: Convert Input(s) to Base Unit

Axial Load on Weld: 9.6 Kilonewton --> 9600 Newton (Check conversion here)
Shear Stress: 2.4 Megapascal --> 2400000 Pascal (Check conversion here)
Thickness of Plate: 12 Millimeter --> 0.012 Meter (Check conversion here)
Length of Bottom Weld: 6 Millimeter --> 0.006 Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

L_{top weld} = P_weld/(𝜏*0.707*t_plate)-L₂ --> 9600/(2400000*0.707*0.012)-0.006

Evaluating ... ...

L_{top weld} = 0.465475719000471

STEP 3: Convert Result to Output's Unit

0.465475719000471 Meter -->465.475719000471 Millimeter (Check conversion here)

FINAL ANSWER

465.475719000471 ≈ 465.4757 Millimeter <-- Length of Top Weld

(Calculation completed in 00.020 seconds)

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Home » Physics » Strength of Materials » Welded Joints » Analysis of Unsymmetrical Welded Sections which are Loaded Axially » Top Weld » Length of Top Weld given Axial Load on Weld

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< 24 Top Weld Calculators

Resistance of Top Weld given Total Weld Length

Go Resistance of top weld = (Resistance of weld per unit length*Total length of weld*Distance of Bottom Weld from Gravity Axis)/(Distance of top weld from gravity axis+Distance of Bottom Weld from Gravity Axis)

Distance of Top Weld from Gravity Axis given Resistance of Bottom Weld and Total Weld Length

Go Distance of top weld from gravity axis = Distance of Bottom Weld from Gravity Axis/((Resistance of weld per unit length*Total length of weld)/Resistance of bottom weld-1)

Resistance of Top Weld given Total Resistance

Go Resistance of top weld = (Total resistance*Distance of Bottom Weld from Gravity Axis)/(Distance of top weld from gravity axis+Distance of Bottom Weld from Gravity Axis)

Length of Top Weld

Go Length of Top Weld = (Distance of Bottom Weld from Gravity Axis*Total length of weld)/(Distance of top weld from gravity axis+Distance of Bottom Weld from Gravity Axis)

Distance of Top Weld from Gravity Axis given Resistance of Top Weld and Total Weld Length

Go Distance of top weld from gravity axis = ((Resistance of weld per unit length*Total length of weld)/Resistance of top weld-1)*Distance of Bottom Weld from Gravity Axis

Distance of Top Weld from Gravity Axis given Resistance of Bottom Weld

Go Distance of top weld from gravity axis = Distance of Bottom Weld from Gravity Axis/((Total resistance)/Resistance of bottom weld-1)

Length of Top Weld given Axial Load on Weld

Go Length of Top Weld = Axial Load on Weld/(Shear Stress*0.707*Thickness of Plate)-Length of Bottom Weld

Distance of Top Weld from Gravity Axis given Resistance of Top Weld

Go Distance of top weld from gravity axis = ((Total resistance)/Resistance of top weld-1)*Distance of Bottom Weld from Gravity Axis

Distance of Top Weld from Gravity Axis given Length of Bottom Weld and Total Length of Weld

Go Distance of top weld from gravity axis = Distance of Bottom Weld from Gravity Axis/(Total length of weld/Length of Top Weld-1)

Distance of Top Weld from Gravity Axis given Length of Top Weld and Total Length of Weld

Go Distance of top weld from gravity axis = (Total length of weld/Length of Top Weld-1)*Distance of Bottom Weld from Gravity Axis

Distance of Top Weld from Gravity Axis given Length of Top Weld

Go Distance of top weld from gravity axis = (Length of Bottom Weld*Distance of Bottom Weld from Gravity Axis)/Length of Top Weld

Length of Top Weld given Length of Bottom Weld

Go Length of Top Weld = (Length of Bottom Weld*Distance of Bottom Weld from Gravity Axis)/Distance of top weld from gravity axis

Distance of Top Weld from Gravity Axis given Moment and Length of Top Weld

Go Distance of top weld from gravity axis = Moment of Inertia of Weld/(Resistance of weld per unit length*Length of Top Weld)

Length of Top Weld given Moment of Top Weld about Gravity Axis

Go Length of Top Weld = Moment of Inertia of Weld/(Resistance of weld per unit length*Distance of top weld from gravity axis)

Moment of Top Weld about Gravity Axis

Go Moment of force = Resistance of weld per unit length*Length of Top Weld*Distance of top weld from gravity axis

Length of Top Weld given Axial Load on Angle

Go Length of Top Weld = Axial load on angle/Resistance of weld per unit length-Length of Bottom Weld

Length of Top Weld given Area of Unsymmetrical Weld

Go Length of Top Weld = Weld Bed Area/(0.707*Thickness of Plate)-Length of Bottom Weld

Distance of Top Weld from Gravity Axis given Moment of Top Weld about Gravity Axis

Go Distance of top weld from gravity axis = Moment of Inertia of Weld/(Resistance of top weld)

Resistance of Top Weld given Moment of Top Weld about Gravity Axis

Go Resistance of top weld = Moment of Inertia of Weld/(Distance of top weld from gravity axis)

Length of Top Weld given Resistance of Top Weld

Go Length of Top Weld = Resistance of top weld/(Resistance of weld per unit length)

Moment of Top Weld about Gravity Axis given Resistance of Top Weld

Go Moment of force = Resistance of top weld*Distance of top weld from gravity axis

Resistance of Top Weld

Go Resistance of top weld = Resistance of weld per unit length*Length of Top Weld

Resistance of Top Weld given Axial Load on Angle

Go Resistance of top weld = Axial load on angle-Resistance of bottom weld

Length of Top Weld given Total Length of Weld

Go Length of Top Weld = Total length of weld-Length of Bottom Weld

Length of Top Weld given Axial Load on Weld Formula

Length of Top Weld = Axial Load on Weld/(Shear Stress*0.707*Thickness of Plate)-Length of Bottom Weld
L_{top weld} = P_weld/(𝜏*0.707*t_plate)-L₂

What is axial load and radial load?

Radial Load is defined as the maximum force that can be applied to the shaft in the radial direction (any direction perpendicular to the motor shaft axis). Axial Load is defined as the maximum force that can be applied to the shaft in the axial direction (in the same axis as or parallel to the motor shaft axis).

How to Calculate Length of Top Weld given Axial Load on Weld?

Length of Top Weld given Axial Load on Weld calculator uses Length of Top Weld = Axial Load on Weld/(Shear Stress*0.707*Thickness of Plate)-Length of Bottom Weld to calculate the Length of Top Weld, Length of top weld given axial load on weld is defined as the measurement or extent of the weld from end to end. Length of Top Weld is denoted by L_{top weld} symbol.

How to calculate Length of Top Weld given Axial Load on Weld using this online calculator? To use this online calculator for Length of Top Weld given Axial Load on Weld, enter Axial Load on Weld (P_weld), Shear Stress (𝜏), Thickness of Plate (t_plate) & Length of Bottom Weld (L₂) and hit the calculate button. Here is how the Length of Top Weld given Axial Load on Weld calculation can be explained with given input values -> 465475.7 = 9600/(2400000*0.707*0.012)-0.006.

FAQ

What is Length of Top Weld given Axial Load on Weld?

Length of top weld given axial load on weld is defined as the measurement or extent of the weld from end to end and is represented as L_{top weld} = P_weld/(𝜏*0.707*t_plate)-L₂ or Length of Top Weld = Axial Load on Weld/(Shear Stress*0.707*Thickness of Plate)-Length of Bottom Weld. Axial Load on Weld is defined as applying a force on a structure directly along an axis of the structure, Shear Stress is force tending to cause deformation of a material by slippage along a plane or planes parallel to the imposed stress, The thickness of plate is the state or quality of being thick. The measure of the smallest dimension of a solid figure: a board of two-inch thickness & Length of bottom weld is the linear distance of each weld segment.

How to calculate Length of Top Weld given Axial Load on Weld?

Length of top weld given axial load on weld is defined as the measurement or extent of the weld from end to end is calculated using Length of Top Weld = Axial Load on Weld/(Shear Stress*0.707*Thickness of Plate)-Length of Bottom Weld. To calculate Length of Top Weld given Axial Load on Weld, you need Axial Load on Weld (P_weld), Shear Stress (𝜏), Thickness of Plate (t_plate) & Length of Bottom Weld (L₂). With our tool, you need to enter the respective value for Axial Load on Weld, Shear Stress, Thickness of Plate & Length of Bottom Weld 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 Length of Top Weld?

In this formula, Length of Top Weld uses Axial Load on Weld, Shear Stress, Thickness of Plate & Length of Bottom Weld. We can use 7 other way(s) to calculate the same, which is/are as follows -

Length of Top Weld = Weld Bed Area/(0.707*Thickness of Plate)-Length of Bottom Weld
Length of Top Weld = (Distance of Bottom Weld from Gravity Axis*Total length of weld)/(Distance of top weld from gravity axis+Distance of Bottom Weld from Gravity Axis)
Length of Top Weld = Axial load on angle/Resistance of weld per unit length-Length of Bottom Weld
Length of Top Weld = (Length of Bottom Weld*Distance of Bottom Weld from Gravity Axis)/Distance of top weld from gravity axis
Length of Top Weld = Moment of Inertia of Weld/(Resistance of weld per unit length*Distance of top weld from gravity axis)
Length of Top Weld = Resistance of top weld/(Resistance of weld per unit length)
Length of Top Weld = Total length of weld-Length of Bottom Weld

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