Application Research of Hot Stamping Base on the Forming History-Reference-Cited by-同舟云学术

Application Research of Hot Stamping Base on the Forming History

Published:2015-03 Issue: Volume:1095 Page:698-703
ISSN:1662-8985
Container-title:Advanced Materials Research
language:
Short-container-title:AMR

Author:

Ma Ning¹,Liu Ke Su²,Liu Quan Kun²,Ma Yu Jie¹

Affiliation:

1. Fuzhou University

2. Hefei University of Technology

Abstract

The hot stamping process and process parameters are investigated for a model of a B-pillar outer plate by numerical simulation. The feasibility of hot stamping forming process and its parameters are analyzed. The effectiveness of numerical simulation and the accuracy of hot stamping forming process and its parameters for B-pillar outer plate are proved by the hot stamping experiment and tensile tests. Three models are designed to analyze the effect of B-pillar in the vehicle side impact. It shows that hot stamping technology has the advantages in the field of lightweight and improving impact resistance. Through the research of the historical process of hot forming part, the residual strain characteristics of hot stamping parts is analyzed, the produce and mechanism of residual strain is explained, and the application method based on the forming history of hot stamping technology is provided.

Publisher

Trans Tech Publications, Ltd.

Subject

General Engineering

Link

https://www.scientific.net/AMR.1095.698.pdf

Reference20 articles.

1. Ma Ning, Hu Ping, Guo Wei, et al. Feasible methods applied to the design and manufacturing process of hot forming [J]. IDDRG2009 conference, Golden, CO USA, 2009, 835-843.

2. Ma Ning, Hu Ping, Guo Wei. Technology and equipment of hot forming for ultra high strength steel [J]. Automobile & Parts, 2009(45): 28-30. (in Chinese).

3. Altan T. Hot-stamping boron-alloyed steels for automotive parts [J]. Stamping Journal, December 2006, 40-41.

4. Makinouchi A. Sheet metal forming simulation in industry. Journal of Material Processing Technology [J]. 1996, 60: 19-26.

5. Hu Ping, Rate-dependent quasi-flow corner theory for elastic/visco-plastic materials, Int. J. Solids & Struct., 2004, 41: 1263-1284.