Study on Internal Helical Gear Worm Forging by Finite Element Analysis

Tung Sheng Yang; Jia Yu Deng; Jie Chang

doi:10.4028/www.scientific.net/AMM.465-466.1361

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Maximum Torque of Combinations Threat for Spur Gear Based on AGMA Standard
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Verification of Fully Developed Flow Entering Diffuser and Particle Image Velocimetry Procedures
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Current Trend in the Oil and Gas Industry on Subsea Processing Equipment
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Study on Internal Helical Gear Worm Forging by Finite Element Analysis
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Investigation of Loading-Unloading Curve and Stress Distribution of Thin Hard Coating by Finite Element Analysis during Nanoindentation Process
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Effect of GMAW-CMT Heat Input on Weld Bead Profile Geometry for Freeform Fabrication of Aluminium Parts
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Tactile Slippage Analysis in Optical Three-Axis Tactile Sensor for Robotic Hand
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Performance Enhancement of Coal Classifier on the Effect of the Geometry
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 465-466Study on Internal Helical Gear Worm Forging by...

Study on Internal Helical Gear Worm Forging by Finite Element Analysis

Abstract:

This study applies the finite element method (FEM) to predict maximum forging load and effective strain in internal helical gear forging. Maximum forging load and effective strain are determined for different process parameters, such as modules, number of teeth, and die temperature of the internal helical gear forging, using the FEM. Finally, the prediction of the power requirement for the internal helical gear warm forging is determined. Therefore, the maximum forming force and strain distribution will be prediction for the different parameters of helical gear worm forging.