An overview of high thermal conductive hot press forming die material development

Authors

  • A.R. Zulhishamuddin Faculty of Mechanical Engineering, University Malaysia Pahang 26600 Pekan, Pahang, Malaysia
  • S.N. Aqida Faculty of Mechanical Engineering, University Malaysia Pahang 26600 Pekan, Pahang, Malaysia

DOI:

https://doi.org/10.15282/jmes.9.2015.14.0162

Keywords:

Hot press forming; thermal conductivity; tool steel; die; carbide.

Abstract

Most of the automotive industries are using high strength steel components, which are produced via hot press forming process. This process requires die material with high thermal conductivity that increases cooling rate during simultaneous quenching and forming stage. Due to the benefit of high quenching rate, thermal conductive die materials were produced by adding carbide former elements. This paper presents an overview of the modification of alloying elements in tool steel for high thermal conductivity properties by transition metal elements addition. Different types of manufacturing processes involved in producing high thermal conductive materials were discussed. Methods reported were powder metallurgy hot press, direct metal deposition, selective laser melting, direct metal laser sintering and spray forming. Elements likes manganese, nickel, molybdenum, tungsten and chromium were proven to increase thermal conductivity properties. Thermal conductivity properties resulted from carbide network presence in the steel microstructure. To develop feasible and low cost hot press forming die material, casting of Fe-based alloy with carbide former composition can be an option. Current thermal conductivity properties of hot press forming die material range between 25 and 66 W/m.K. The wide range of thermal conductivity varies the mechanical properties of the resulting components and lifetime of HPF dies.

References

Steinbeiss H, So H, Michelitsch T, Hoffmann H. Method for optimizing the cooling design of hot stamping tools. Production Engineering. 2007;1:149-55.

Zhong-de S, Mi-lan Z, Chao J, Ying X, Wen-juan R. Basic study on die cooling system of hot stamping process. Advanced Technology of Design and Manufacture (ATDM 2010), International Conference on: IET; 2010. p. 1-4.

Abdulhay B, Bourouga B, Dessain C. Experimental and theoretical study of thermal aspects of the hot stamping process. Applied Thermal Engineering. 2011;31:674-85.

Ghiotti A, Sgarabotto F, Bruschi S. A novel approach to wear testing in hot stamping of high strength boron steel sheets. Wear. 2013;302:1319-26.

Karbasian H, Tekkaya AE. A review on hot stamping. J Mater Process Tech. 2010;210:2103-18.

Casas B, Latre D, Rodriguez N, Valls I. Tailor made tool materials for the present and upcoming tooling solutions in hot sheet metal forming. 1st International Conference on Hot Sheet Metal Forming of High Performance Steels, Luleå, Sweden, October2008. p. 22-4.

Naganathan A, Penter L. Hot stamping. Sheet metal forming–Processes and applications, ASM international. 2012:134-56.

Hu P, Ma N, Liu L-z, Zhu Y-g. Theories, methods and numerical technology of sheet metal cold and hot forming: analysis, simulation and engineering applications: Springer Science & Business Media; 2012.

Tisza M. MATERIAL DEVELOPMENTS IN SHEET METAL FORMING. 2013;6:79–88.

Jhavar S, Paul C, Jain N. Causes of failure and repairing options for dies and molds: a review. Engineering Failure Analysis. 2013;34:519-35.

Sandberg N. On the Machinability of High Performance Tool Steels. Acta Universitatis Upsaliensis Uppsala. 2012.

Davis JR. Metals Handbook Desk Edition, 2nd Edition: ASM International; 1998.

Cubberly WH, Baker H, Benjamin D, Unterweiser P, Kirkpatrick C, Knoll V, et al. Properties and selection: nonferrous alloys and pure metals. Metals Handbook. 1979;2:75.

Peet M, Hasan H, Bhadeshia H. Prediction of thermal conductivity of steel. Int J Heat Mass Tran. 2011;54:2602-8.

Fuchs K. Hot-work tool steels with improved properties for die-casting applications. 6th International Tooling Conference2002. p. 15-22.

Kheirandish S, Noorian A. Effect of niobium on microstructure of cast AISI H13 hot work tool steel. Journal of Iron and Steel Research, International. 2008;15:61- 6.

Angles IV. Process for setting the thermal conductivity of a steel, tool steel, in particular hot-work steel, and steel object. Google Patents; 2013.

Sinha V, Spowart J. Influence of interfacial carbide layer characteristics on thermal properties of copper–diamond composites. J Mater Sci. 2013;48:1330-41.

Shen X-Y, He X-B, Ren S-B, Zhang H-M, Qu X-H. Effect of molybdenum as interfacial element on the thermal conductivity of diamond/Cu composites. Journal of Alloys and Compounds. 2012;529:134-9.

Yang X, SONG Y-q, LIN C-g, Shun C, FANG Z-z. Effect of carbide formers on microstructure and thermal conductivity of diamond-Cu composites for heat sink materials. Transactions of Nonferrous Metals Society of China. 2009;19:1161-6.

Angles IV. Method and device for producing a workpiece, particularly a shaping tool or a part of a shaping tool. Google Patents; 2009.

Dourandish M, Simchi A. Study the sintering behavior of nanocrystalline 3Y- TZP/430L stainless-steel composite layers for co-powder injection molding. J Mater Sci. 2009;44:1264-74.

Imran MK, Masood S, Brandt M, Bhattacharya S, Gulizia S, Jahedi M, et al. Thermal fatigue behavior of direct metal deposited H13 tool steel coating on copper alloy substrate. Surface and Coatings Technology. 2012;206:2572-80.

Yuan J, Zhang K, Zhang X, Li X, Li T, Li Y, et al. Thermal characteristics of Mg– Zn–Mn alloys with high specific strength and high thermal conductivity. Journal of Alloys and Compounds. 2013;578:32-6.

Al-Jamal O, Hinduja S, Li L. Characteristics of the bond in Cu–H13 tool steel parts fabricated using SLM. CIRP Annals-Manufacturing Technology. 2008;57:239-42.

Jae-Ho L, Jeong-Hwan J, Byeong-Don J, Hong-Sup Y, Young-Hoon M. Application of direct laser metal tooling for AISI H13 tool steel. Transactions of Nonferrous Metals Society of China. 2009;19:s284-s7.

Schruff I, Schüler V, Spiegelhauer C. Advanced tool steels produced via spray forming. The Use of Tool Steels: Experience and Research. 2002;2:10-3.

Balla VK, Bose S, Bandyopadhyay A. Laser surface modification of Al–4Cu– 1Mg alloy for enhanced thermal conductivity. Opt Laser Eng. 2009;47:651-5.

Spiegelhauer C. Industrial production of tool steels using the spray forming technology. The use of tool steels: Experience and research. 2002;2:1101-9.

Downloads

Published

2015-12-31

How to Cite

[1]
A. . Zulhishamuddin and S. . Aqida, “An overview of high thermal conductive hot press forming die material development”, J. Mech. Eng. Sci., vol. 9, pp. 1686–1694, Dec. 2015.

Issue

Section

Review

Similar Articles

<< < 12 13 14 15 16 17 18 19 20 21 > >> 

You may also start an advanced similarity search for this article.