Greatest Safe Load for Hollow Rectangle when Load is Distributed Calculator

✖Cross Sectional Area of Beam the area of a two-dimensional shape that is obtained when a three-dimensional shape is sliced perpendicular to some specified axis at a point.ⓘ Cross Sectional Area of Beam [A_cs]			+10% -10%
✖Depth of Beam is the overall depth of the cross-section of the beam perpendicular to the axis of the beam.ⓘ Depth of Beam [d_b]			+10% -10%
✖Interior Cross-Sectional Area of Beam is the hollow area of a two-dimensional shape that is obtained when a three-dimensional object is sliced perpendicular to the axis at a point.ⓘ Interior Cross-Sectional Area of Beam [a]			+10% -10%
✖Interior Depth of Beam is the depth of the hollow cross section of the beam perpendicular to the axis of the beam.ⓘ Interior Depth of Beam [d]			+10% -10%
✖Distance between Supports is the distance between two intermediate supports for a structure.ⓘ Distance between Supports [L_c]			+10% -10%

✖Greatest Safe Distributed Load is that load which acts over a considerable length or over a length which is measurable. Distributed load is measured as per unit length.ⓘ Greatest Safe Load for Hollow Rectangle when Load is Distributed [W_d]

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Formula

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Greatest Safe Load for Hollow Rectangle when Load is Distributed

Formula

`"W"_{"d"} = 1780*("A"_{"cs"}*"d"_{"b"}-"a"*"d")/"L"_{"c"}`

Example

`"2.672964kN"=1780*("13m²"*"10.01in"-"10in²"*"10in")/"2.2m"`

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Greatest Safe Load for Hollow Rectangle when Load is Distributed Solution

STEP 0: Pre-Calculation Summary

Formula Used

Greatest Safe Distributed Load = 1780*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam)/Distance between Supports
W_d = 1780*(A_cs*d_b-a*d)/L_c
This formula uses 6 Variables

Variables Used

Greatest Safe Distributed Load - (Measured in Newton) - Greatest Safe Distributed Load is that load which acts over a considerable length or over a length which is measurable. Distributed load is measured as per unit length.
Cross Sectional Area of Beam - (Measured in Square Meter) - Cross Sectional Area of Beam the area of a two-dimensional shape that is obtained when a three-dimensional shape is sliced perpendicular to some specified axis at a point.
Depth of Beam - (Measured in Meter) - Depth of Beam is the overall depth of the cross-section of the beam perpendicular to the axis of the beam.
Interior Cross-Sectional Area of Beam - (Measured in Square Meter) - Interior Cross-Sectional Area of Beam is the hollow area of a two-dimensional shape that is obtained when a three-dimensional object is sliced perpendicular to the axis at a point.
Interior Depth of Beam - (Measured in Meter) - Interior Depth of Beam is the depth of the hollow cross section of the beam perpendicular to the axis of the beam.
Distance between Supports - (Measured in Meter) - Distance between Supports is the distance between two intermediate supports for a structure.

STEP 1: Convert Input(s) to Base Unit

Cross Sectional Area of Beam: 13 Square Meter --> 13 Square Meter No Conversion Required
Depth of Beam: 10.01 Inch --> 0.254254000001017 Meter (Check conversion here)
Interior Cross-Sectional Area of Beam: 10 Square Inch --> 0.00645160000005161 Square Meter (Check conversion here)
Interior Depth of Beam: 10 Inch --> 0.254000000001016 Meter (Check conversion here)
Distance between Supports: 2.2 Meter --> 2.2 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

W_d = 1780*(A_cs*d_b-a*d)/L_c --> 1780*(13*0.254254000001017-0.00645160000005161*0.254000000001016)/2.2

Evaluating ... ...

W_d = 2672.96393755977

STEP 3: Convert Result to Output's Unit

2672.96393755977 Newton -->2.67296393755977 Kilonewton (Check conversion here)

FINAL ANSWER

2.67296393755977 ≈ 2.672964 Kilonewton <-- Greatest Safe Distributed Load

(Calculation completed in 00.004 seconds)

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Home » Engineering » Civil » Structural Engineering » Structural Analysis » Moving Loads and Influence Lines for Beams » Safe Loads » Greatest Safe Load for Hollow Rectangle when Load is Distributed

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Created by Rudrani Tidke

Cummins College of Engineering for Women (CCEW), Pune

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Osmania University (OU), Hyderabad

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< 16 Safe Loads Calculators

Greatest Safe Load for Hollow Rectangle when Load is Distributed

Go Greatest Safe Distributed Load = 1780*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam)/Distance between Supports

Greatest Safe Load for Hollow Cylinder when Load is Distributed

Go Greatest Safe Distributed Load = (1333*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam))/Length of Beam

Greatest Safe Load for Hollow Rectangle when Load in Middle

Go Greatest Safe Point Load = (890*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam))/Length of Beam

Greatest Safe Load for Hollow Cylinder when Load in Middle

Go Greatest Safe Point Load = (667*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam))/Length of Beam

Greatest Safe Load for Even Legged Angle when Load is Distributed

Go Greatest Safe Distributed Load = (1.77*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

Greatest Safe Load for Channel or Z Bar when Load is Distributed

Go Greatest Safe Distributed Load = (3050*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

Greatest Safe Load for Solid Cylinder when Load is Distributed

Go Greatest Safe Distributed Load = 1333*(Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

Greatest Safe Load for Deck Beam when Load is Distributed

Go Greatest Safe Distributed Load = (2760*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

Greatest Safe Load for I Beam when Load is Distributed

Go Greatest Safe Distributed Load = (3390*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

Greatest Safe Load for Solid Rectangle when Load is Distributed

Go Greatest Safe Distributed Load = 1780*Cross Sectional Area of Beam*Depth of Beam/Length of Beam

Greatest Safe Load for Channel or Z Bar when Load is at Middle

Go Greatest Safe Point Load = (1525*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

Greatest Safe Load for Deck Beam when Load in Middle

Go Greatest Safe Point Load = (1380*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

Greatest Safe Load for I Beam when Load in Middle

Go Greatest Safe Point Load = (1795*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

Greatest Safe Load for Solid Cylinder when Load in Middle

Go Greatest Safe Point Load = (667*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

Greatest Safe Load for Even Legged Angle when Load is in Middle

Go Greatest Safe Point Load = 885*Cross Sectional Area of Beam*Depth of Beam/Length of Beam

Greatest Safe Load for Solid Rectangle given Load in Middle

Go Greatest Safe Point Load = 890*Cross Sectional Area of Beam*Depth of Beam/Length of Beam

Greatest Safe Load for Hollow Rectangle when Load is Distributed Formula

Greatest Safe Distributed Load = 1780*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam)/Distance between Supports
W_d = 1780*(A_cs*d_b-a*d)/L_c

What is Safe Load?

Safe Load is the manufacturer's recommended maximum weight load for a line, rope, crane, or any other lifting device or component of a lifting device. Safe Load (SWL) sometimes stated as the Normal Working Load (NWL) is the mass or force that a piece of lifting equipment, lifting device or accessory can safely use to lift, suspend, or lower a mass without fear of breaking.

How to Calculate Greatest Safe Load for Hollow Rectangle when Load is Distributed?

Greatest Safe Load for Hollow Rectangle when Load is Distributed calculator uses Greatest Safe Distributed Load = 1780*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam)/Distance between Supports to calculate the Greatest Safe Distributed Load, The Greatest Safe Load for Hollow Rectangle when Load is Distributed formula is defined as a distributed load on a hallow rectangular structure which does not produce stresses in excess of allowable stresses. Greatest Safe Distributed Load is denoted by W_d symbol.

How to calculate Greatest Safe Load for Hollow Rectangle when Load is Distributed using this online calculator? To use this online calculator for Greatest Safe Load for Hollow Rectangle when Load is Distributed, enter Cross Sectional Area of Beam (A_cs), Depth of Beam (d_b), Interior Cross-Sectional Area of Beam (a), Interior Depth of Beam (d) & Distance between Supports (L_c) and hit the calculate button. Here is how the Greatest Safe Load for Hollow Rectangle when Load is Distributed calculation can be explained with given input values -> 0.002673 = 1780*(13*0.254254000001017-0.00645160000005161*0.254000000001016)/2.2.

FAQ

What is Greatest Safe Load for Hollow Rectangle when Load is Distributed?

The Greatest Safe Load for Hollow Rectangle when Load is Distributed formula is defined as a distributed load on a hallow rectangular structure which does not produce stresses in excess of allowable stresses and is represented as W_d = 1780*(A_cs*d_b-a*d)/L_c or Greatest Safe Distributed Load = 1780*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam)/Distance between Supports. Cross Sectional Area of Beam the area of a two-dimensional shape that is obtained when a three-dimensional shape is sliced perpendicular to some specified axis at a point, Depth of Beam is the overall depth of the cross-section of the beam perpendicular to the axis of the beam, Interior Cross-Sectional Area of Beam is the hollow area of a two-dimensional shape that is obtained when a three-dimensional object is sliced perpendicular to the axis at a point, Interior Depth of Beam is the depth of the hollow cross section of the beam perpendicular to the axis of the beam & Distance between Supports is the distance between two intermediate supports for a structure.

How to calculate Greatest Safe Load for Hollow Rectangle when Load is Distributed?

The Greatest Safe Load for Hollow Rectangle when Load is Distributed formula is defined as a distributed load on a hallow rectangular structure which does not produce stresses in excess of allowable stresses is calculated using Greatest Safe Distributed Load = 1780*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam)/Distance between Supports. To calculate Greatest Safe Load for Hollow Rectangle when Load is Distributed, you need Cross Sectional Area of Beam (A_cs), Depth of Beam (d_b), Interior Cross-Sectional Area of Beam (a), Interior Depth of Beam (d) & Distance between Supports (L_c). With our tool, you need to enter the respective value for Cross Sectional Area of Beam, Depth of Beam, Interior Cross-Sectional Area of Beam, Interior Depth of Beam & Distance between Supports 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 Greatest Safe Distributed Load?

In this formula, Greatest Safe Distributed Load uses Cross Sectional Area of Beam, Depth of Beam, Interior Cross-Sectional Area of Beam, Interior Depth of Beam & Distance between Supports. We can use 7 other way(s) to calculate the same, which is/are as follows -

Greatest Safe Distributed Load = 1780*Cross Sectional Area of Beam*Depth of Beam/Length of Beam
Greatest Safe Distributed Load = 1333*(Cross Sectional Area of Beam*Depth of Beam)/Length of Beam
Greatest Safe Distributed Load = (1333*(Cross Sectional Area of Beam*Depth of Beam-Interior Cross-Sectional Area of Beam*Interior Depth of Beam))/Length of Beam
Greatest Safe Distributed Load = (1.77*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam
Greatest Safe Distributed Load = (3050*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam
Greatest Safe Distributed Load = (2760*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam
Greatest Safe Distributed Load = (3390*Cross Sectional Area of Beam*Depth of Beam)/Length of Beam

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