External Torque Required to Raise The Load in Terms of Efficiency Calculator

Category	Physics ↺
Physics	Machine Design ↺
Machine-Design	Design of Machine Elements ↺
Design-Of-Machine-Elements	Power Screws ↺
Power-Screws

✖Axial Load is defined as applying a force on a structure directly along an axis of the structureⓘ Axial Load [P]			+10% -10%
✖Lead of Screw is the linear travel the nut makes per one screw revolution and is how ball screws are typically specified.ⓘ Lead of Screw [L]			+10% -10%
✖Overall Efficiency of Power Screw as the ratio of output work to the input work in screw tightening process. ⓘ Overall Efficiency of Power Screw [n]			+10% -10%

✖Torsional Moment is the torque applied to generate a torsion (twist) within the object.ⓘ External Torque Required to Raise The Load in Terms of Efficiency [(M _t ) _t]

⎘ Copy

👎 Report Issue!

👍 Share Now!

You are here:

Home »
Physics »
Machine Design »
Design of Machine Elements »
Power Screws »
External Torque Required to Raise The Load in Terms of Efficiency

Kumar Siddhant

Indian Institute of Information Technology, Design and Manufacturing (IIITDM), Jabalpur

Kumar Siddhant has created this Calculator and 50+ more calculators!

Kethavath Srinath

Osmania University (OU), Hyderabad

Kethavath Srinath has verified this Calculator and 500+ more calculators!

< 11 Other formulas that you can solve using the same Inputs

Maximum Bearing Pressure when Full Bearing Area of Sq and Rect Footings is Engaged

Maximum Bearing Pressure=(Axial Load/Area of Footing)*(1+(Loading Eccentricity 1*Principal Axis 1/(Radius of Gyration 1^2))+(Loading Eccentricity 2*Principal Axis 2/(Radius of Gyration 2^2))) GO

Neutral Axis to Outermost Fiber Distance when Total Unit Stress in Eccentric Loading is Given

Outermost Fiber Distance=(Total Unit Stress-(Axial Load/Cross sectional area))*Moment of Inertia about Neutral Axis/(Axial Load*Distance_from Load Applied) GO

Moment of Inertia of Cross-Section when Total Unit Stress in Eccentric Loading is Given

Moment of Inertia about Neutral Axis=(Axial Load*Outermost Fiber Distance*Distance_from Load Applied)/(Total Unit Stress-(Axial Load/Cross sectional area)) GO

Cross-Sectional Area when Total Unit Stress in Eccentric Loading is Given

Cross sectional area=Axial Load/(Total Unit Stress-((Axial Load*Outermost Fiber Distance*Distance_from Load Applied/Moment of Inertia about Neutral Axis))) GO

Total Unit Stress in Eccentric Loading

Total Unit Stress=(Axial Load/Cross sectional area)+(Axial Load*Outermost Fiber Distance*Distance_from Load Applied/Moment of Inertia about Neutral Axis) GO

Maximum Bending Moment when Maximum Stress For Short Beams is Given

Maximum Bending Moment=((Maximum stress at crack tip-(Axial Load/Cross sectional area))*Moment of Inertia)/Distance from the Neutral axis GO

Maximum Stress For Short Beams

Maximum stress at crack tip=(Axial Load/Cross sectional area)+((Maximum Bending Moment*Distance from the Neutral axis)/Moment of Inertia) GO

Cross-Sectional Area when Maximum Stress For Short Beams is Given

Cross sectional area=Axial Load/(Maximum stress at crack tip-(Maximum Bending Moment*Distance from the Neutral axis/Moment of Inertia)) GO

Total Unit Stress in Eccentric Loading when Radius of Gyration is Given

Total Unit Stress=(Axial Load/Cross sectional area)*(1+(Outermost Fiber Distance*Distance_from Load Applied/(Radius of gyration^2))) GO

Eccentricity when Deflection in Eccentric Loading is Given

Eccentricity of Loading=(pi*(1-Axial Load/Critical Buckling Load))*Deflection/(4*Axial Load/Critical Buckling Load) GO

Helix Angle

Helix Angle=atan(Lead of Screw/Circumference of Screw) GO

< 1 Other formulas that calculate the same Output

Torsional Moment When Torsional Shear Stress is Given

Torsional Moment=Torsional Shear Stress*pi*(Core Diameter^3)/16 GO

External Torque Required to Raise The Load in Terms of Efficiency Formula

Torsional Moment=Axial Load*Lead of Screw/(2*pi*Overall Efficiency of Power Screw)
(M <sub>t</sub> ) <sub> t=P*L/(2*pi*n)

More formulas

Core Diameter of Power Screw GO

Nominal Diameter of Power Screw GO

Pitch of Power Screw GO

Mean Diameter of Power Screw GO

Nominal Diameter of Power Screw When Mean DIameter is Given GO

Pitch of the Screw When Mean Diameter is Given GO

Helix Angle of Thread GO

Mean diameter of Screw When Helix Angle is Given GO

Lead of Screw When Helix angle is Given GO

Efficiency of Square Threaded Screw GO

Coefficient of Friction When Efficiency of Square Threaded Screw is Given GO

Maximum Efficiency of Square Threaded Screw GO

Lead of the Screw When Overall Efficiency is Given GO

load When Overall Efficiency is Given GO

Overall Efficiency of a Power Screw GO

Overall Efficiency of Screw

The Efficiency of a Screw refers to how well a screw converts rotary energy (torque) into linear motion. Lead screw efficiency is a pure calculated value and is calculated fro one revolution of Screw at a time.

How to Calculate External Torque Required to Raise The Load in Terms of Efficiency?

External Torque Required to Raise The Load in Terms of Efficiency calculator uses Torsional Moment=Axial Load*Lead of Screw/(2*pi*Overall Efficiency of Power Screw) to calculate the Torsional Moment, The External Torque Required to Raise The Load in Terms of Efficiency is the measure of torque to be applied for tightening of a screw/bolt to get the desired Work Output. . Torsional Moment and is denoted by (M _t ) _t symbol.

How to calculate External Torque Required to Raise The Load in Terms of Efficiency using this online calculator? To use this online calculator for External Torque Required to Raise The Load in Terms of Efficiency, enter Axial Load (P), Lead of Screw (L) and Overall Efficiency of Power Screw (n) and hit the calculate button. Here is how the External Torque Required to Raise The Load in Terms of Efficiency calculation can be explained with given input values -> 312.1554 = 98.0664999999931*10/(2*pi*0.5).

FAQ

What is External Torque Required to Raise The Load in Terms of Efficiency?

The External Torque Required to Raise The Load in Terms of Efficiency is the measure of torque to be applied for tightening of a screw/bolt to get the desired Work Output. and is represented as (M _t ) _{t=P*L/(2*pi*n)} or Torsional Moment=Axial Load*Lead of Screw/(2*pi*Overall Efficiency of Power Screw). Axial Load is defined as applying a force on a structure directly along an axis of the structure, Lead of Screw is the linear travel the nut makes per one screw revolution and is how ball screws are typically specified and Overall Efficiency of Power Screw as the ratio of output work to the input work in screw tightening process. .

How to calculate External Torque Required to Raise The Load in Terms of Efficiency?

The External Torque Required to Raise The Load in Terms of Efficiency is the measure of torque to be applied for tightening of a screw/bolt to get the desired Work Output. is calculated using Torsional Moment=Axial Load*Lead of Screw/(2*pi*Overall Efficiency of Power Screw). To calculate External Torque Required to Raise The Load in Terms of Efficiency, you need Axial Load (P), Lead of Screw (L) and Overall Efficiency of Power Screw (n). With our tool, you need to enter the respective value for Axial Load, Lead of Screw and Overall Efficiency of Power Screw 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 Torsional Moment?

In this formula, Torsional Moment uses Axial Load, Lead of Screw and Overall Efficiency of Power Screw. We can use 1 other way(s) to calculate the same, which is/are as follows -

Torsional Moment=Torsional Shear Stress*pi*(Core Diameter^3)/16

Facebook
Twitter
WhatsApp
Reddit
LinkedIn
E-Mail

Let Others Know

✖

Facebook

Twitter

Copied!