Die and Process Design for Hot Forging of a Gear Wheel – A Case Study

Thomas Henke; Markus Bambach; Gerhard Hirt

doi:10.4028/www.scientific.net/KEM.554-557.307

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Effect of Different Finish-Rolling Parameters on the Microstructure and Mechanical Properties of Twin-Roll-Cast (TRC) AZ31 Strips
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Investigation on the Influence of Manufacturing Parameters on the Fatigue Strength of Components
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Experimental & Numerical Study of the Hot Upsetting of Weld Cladded Billets
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Finite Element Simulation as a Tool to Evaluate Gear Quality after Gear Rolling
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Die and Process Design for Hot Forging of a Gear Wheel – A Case Study
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Time-Efficient and Precise FEM/BEM Simulation of a Cold Forging Process Verified by Tool Load Determination
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Methodology to Straighten the End Parts of Long Workpieces
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Speed Roll Laws Influence in a Ring Rolling Process
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Potential of Duplex Plasma Deposition Processes for the Improvement of Wear Resistance of Hot Forging Dies
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 554-557Die and Process Design for Hot Forging of a Gear...

Die and Process Design for Hot Forging of a Gear Wheel – A Case Study

Abstract:

Gearing components are an example for widely used machining parts in engines. Nowadays the development and optimization of materials and process chains are driven towards a concurrent improvement of final product properties and production efficiency. Excellent mechanical properties needed for gearing components e.g. high load capacity and high fatigue resistance depend on a fine homogeneous microstructure in the final product. Efficiency in gear manufacturing can be optimized by increasing the temperature during processing, which allows for lower forging loads and lower die stresses, thus improving die life in terms of mechanical fatigue. Additionally, increasing the temperature during case hardening reduces the process duration significantly. Hence process efficiency also increases. To meet the need of a fine homogenous microstructure, dynamic recrystallization has to be initiated during hot forging and grain growth has to be avoided during dwell times and case hardening. This grain size control can be achieved by applying micro-alloying concepts. Recently, an Nb-Ti-based alloying concept for case hardening steels was introduced, which increases fine grain stability and therefore potentially allows for higher forging and case hardening temperatures, leading to improved process efficiency [1]. In this paper a 25MoCr4-Nb-Ti steel grade is characterized in terms of flow resistance and microstructure evolution by hot compression tests and annealing experiments. The processing limits of this material in terms of abnormal grain growth are determined and a JMAK-based microstructure model considering these limits is presented and implemented in the FE-Software DEFORM 3dTM. The model is used in a case study to design a laboratory scale forging process for lowest possible die stresses and finest possible grain sizes. Experimentally measured grain sizes and forging loads from forgings at the laboratory scale are used to evaluate the process design. It is shown that considering microstructure evolution in process design is absolutely necessary to jointly optimize for process efficiency and final properties. The application of the Nb-Ti-based micro-alloying concepts allows for lower die stresses and thus seems to reduce mechanical fatigue of the dies compared to conventional case-hardening steels. [1] S. Konovalov et. al.: Testcase gearing component. In: G. J. Schmitz, U. Prahl (Ed.): Integrative Computational Materials Engineering, Wiley-VCH Verlag GmbH & Co. KGaA, 2012, ISBN 978-3-527-33081-2

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Periodical:

Key Engineering Materials (Volumes 554-557)

Pages:

307-316

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.554-557.307

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Online since:

June 2013

Authors:

Thomas Henke, Markus Bambach, Gerhard Hirt

Keywords:

3D FEA, Case-Hardening, Forging, Johnson-Mehl-Avrami-Kolmogorov Model, Microalloyed Steel, Process Chain Simulation

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References

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