Resultant Bending moment at side crankshaft below flywheel at max torque given moments Solution

STEP 0: Pre-Calculation Summary
Formula Used
Total Bending Moment in Crankshaft Under Flywheel = sqrt(Vertical Bending Moment in Shaft Under Flywheel^2+Horizontal Bending Moment in Shaft Under Flywheel^2)
Mbr = sqrt(Mbv^2+Mbh^2)
This formula uses 1 Functions, 3 Variables
Functions Used
sqrt - A square root function is a function that takes a non-negative number as an input and returns the square root of the given input number., sqrt(Number)
Variables Used
Total Bending Moment in Crankshaft Under Flywheel - (Measured in Newton Meter) - Total Bending Moment in Crankshaft Under Flywheel is the total amount of bending moment in the part of the crankshaft under the flywheel, due to bending moments in the horizontal and vertical plane.
Vertical Bending Moment in Shaft Under Flywheel - (Measured in Newton Meter) - Vertical Bending Moment in Shaft Under Flywheel is the bending moment in the vertical plane of the part of crankshaft under the flywheel.
Horizontal Bending Moment in Shaft Under Flywheel - (Measured in Newton Meter) - Horizontal Bending Moment in Shaft under Flywheel is the bending moment in the horizontal plane of the part of the crankshaft under the flywheel.
STEP 1: Convert Input(s) to Base Unit
Vertical Bending Moment in Shaft Under Flywheel: 25000 Newton Millimeter --> 25 Newton Meter (Check conversion ​here)
Horizontal Bending Moment in Shaft Under Flywheel: 82400 Newton Millimeter --> 82.4 Newton Meter (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Mbr = sqrt(Mbv^2+Mbh^2) --> sqrt(25^2+82.4^2)
Evaluating ... ...
Mbr = 86.1090006909847
STEP 3: Convert Result to Output's Unit
86.1090006909847 Newton Meter -->86109.0006909847 Newton Millimeter (Check conversion ​here)
FINAL ANSWER
86109.0006909847 86109 Newton Millimeter <-- Total Bending Moment in Crankshaft Under Flywheel
(Calculation completed in 00.020 seconds)

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Design of Shaft Under Flywheel at Angle of Maximum Torque Calculators

Horizontal Bending Moment at Central Plane of Side Crankshaft below Flywheel at max Torque
​ LaTeX ​ Go Horizontal Bending Moment in Shaft Under Flywheel = (Tangential Force at Crank Pin*(Overhang Distance of Piston Force From Bearing1+Side Crankshaft Bearing1 Gap From Flywheel))-(Side Crankshaft Bearing1 Gap From Flywheel*(Horizontal Force at Bearing1 By Tangential Force+Horizontal Reaction at Bearing 1 Due to Belt))
Vertical bending moment at central plane of side crankshaft below flywheel at max torque
​ LaTeX ​ Go Vertical Bending Moment in Shaft Under Flywheel = (Radial Force at Crank Pin*(Overhang Distance of Piston Force From Bearing1+Side Crankshaft Bearing1 Gap From Flywheel))-(Side Crankshaft Bearing1 Gap From Flywheel*(Vertical Reaction at Bearing 1 Due to Radial Force+Vertical Reaction at Bearing 1 Due to Flywheel))
Torsional shear stress in side-crankshaft below flywheel for max torque
​ LaTeX ​ Go Shear Stress in Crankshaft Under Flywheel = 16/(pi*Diameter of Shaft Under Flywheel^3)*sqrt(Vertical Bending Moment in Shaft Under Flywheel^2+Horizontal Bending Moment in Shaft Under Flywheel^2+(Tangential Force at Crank Pin*Distance Between Crank Pin And Crankshaft)^2)
Resultant Bending moment at side crankshaft below flywheel at max torque given moments
​ LaTeX ​ Go Total Bending Moment in Crankshaft Under Flywheel = sqrt(Vertical Bending Moment in Shaft Under Flywheel^2+Horizontal Bending Moment in Shaft Under Flywheel^2)

Resultant Bending moment at side crankshaft below flywheel at max torque given moments Formula

​LaTeX ​Go
Total Bending Moment in Crankshaft Under Flywheel = sqrt(Vertical Bending Moment in Shaft Under Flywheel^2+Horizontal Bending Moment in Shaft Under Flywheel^2)
Mbr = sqrt(Mbv^2+Mbh^2)

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How to Calculate Resultant Bending moment at side crankshaft below flywheel at max torque given moments?

Resultant Bending moment at side crankshaft below flywheel at max torque given moments calculator uses Total Bending Moment in Crankshaft Under Flywheel = sqrt(Vertical Bending Moment in Shaft Under Flywheel^2+Horizontal Bending Moment in Shaft Under Flywheel^2) to calculate the Total Bending Moment in Crankshaft Under Flywheel, Resultant Bending moment at side crankshaft below flywheel at max torque given moments is the total amount of bending moment in the part of the side crankshaft under the flywheel, resultant of the bending moments in the horizontal and vertical plane, designed for when the crank is at the maximum torque position and subjected to maximum torsional moment. Total Bending Moment in Crankshaft Under Flywheel is denoted by Mbr symbol.

How to calculate Resultant Bending moment at side crankshaft below flywheel at max torque given moments using this online calculator? To use this online calculator for Resultant Bending moment at side crankshaft below flywheel at max torque given moments, enter Vertical Bending Moment in Shaft Under Flywheel (Mbv) & Horizontal Bending Moment in Shaft Under Flywheel (Mbh) and hit the calculate button. Here is how the Resultant Bending moment at side crankshaft below flywheel at max torque given moments calculation can be explained with given input values -> 6E+7 = sqrt(25^2+82.4^2).

FAQ

What is Resultant Bending moment at side crankshaft below flywheel at max torque given moments?
Resultant Bending moment at side crankshaft below flywheel at max torque given moments is the total amount of bending moment in the part of the side crankshaft under the flywheel, resultant of the bending moments in the horizontal and vertical plane, designed for when the crank is at the maximum torque position and subjected to maximum torsional moment and is represented as Mbr = sqrt(Mbv^2+Mbh^2) or Total Bending Moment in Crankshaft Under Flywheel = sqrt(Vertical Bending Moment in Shaft Under Flywheel^2+Horizontal Bending Moment in Shaft Under Flywheel^2). Vertical Bending Moment in Shaft Under Flywheel is the bending moment in the vertical plane of the part of crankshaft under the flywheel & Horizontal Bending Moment in Shaft under Flywheel is the bending moment in the horizontal plane of the part of the crankshaft under the flywheel.
How to calculate Resultant Bending moment at side crankshaft below flywheel at max torque given moments?
Resultant Bending moment at side crankshaft below flywheel at max torque given moments is the total amount of bending moment in the part of the side crankshaft under the flywheel, resultant of the bending moments in the horizontal and vertical plane, designed for when the crank is at the maximum torque position and subjected to maximum torsional moment is calculated using Total Bending Moment in Crankshaft Under Flywheel = sqrt(Vertical Bending Moment in Shaft Under Flywheel^2+Horizontal Bending Moment in Shaft Under Flywheel^2). To calculate Resultant Bending moment at side crankshaft below flywheel at max torque given moments, you need Vertical Bending Moment in Shaft Under Flywheel (Mbv) & Horizontal Bending Moment in Shaft Under Flywheel (Mbh). With our tool, you need to enter the respective value for Vertical Bending Moment in Shaft Under Flywheel & Horizontal Bending Moment in Shaft Under Flywheel 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 Total Bending Moment in Crankshaft Under Flywheel?
In this formula, Total Bending Moment in Crankshaft Under Flywheel uses Vertical Bending Moment in Shaft Under Flywheel & Horizontal Bending Moment in Shaft Under Flywheel. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Total Bending Moment in Crankshaft Under Flywheel = (sqrt((((Radial Force at Crank Pin*(Overhang Distance of Piston Force From Bearing1+Side Crankshaft Bearing1 Gap From Flywheel))-(Side Crankshaft Bearing1 Gap From Flywheel*(Vertical Reaction at Bearing 1 Due to Radial Force+Vertical Reaction at Bearing 1 Due to Flywheel)))^2)+(((Tangential Force at Crank Pin*(Overhang Distance of Piston Force From Bearing1+Side Crankshaft Bearing1 Gap From Flywheel))-(Side Crankshaft Bearing1 Gap From Flywheel*(Horizontal Force at Bearing1 By Tangential Force+Horizontal Reaction at Bearing 1 Due to Belt)))^2)))
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