Permeability Performance on Porous Structure of Injection Mold Fabricated by Metal Laser Sintering Combined with High Speed Milling

Hiroyuki Narahara; Sho Takeshita; Hirofumi Fukumaru; Hiroshi Koresawa; Hiroshi Suzuki

doi:10.20965/ijat.2012.p0576

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IJAT Vol.6 No.5 pp. 576-583

doi: 10.20965/ijat.2012.p0576

(2012)

Paper:

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Permeability Performance on Porous Structure of Injection Mold Fabricated by Metal Laser Sintering Combined with High Speed Milling

Hiroyuki Narahara, Sho Takeshita, Hirofumi Fukumaru,
Hiroshi Koresawa, and Hiroshi Suzuki

Department of Mechanical Information Science and Technology, Kyushu Institute of Technology, 680-4 Kawazu, Iizuka-shi, Fukuoka 820-8502, Japan

Received:

April 22, 2012

Accepted:

June 7, 2012

Published:

September 5, 2012

Keywords:

rapid prototyping, injection molding, laser sintering, layered fabrication, additive manufacturing

Abstract

Metal Laser Sintering Combined with High Speed Milling is the technology in which high speed cutting is united with the selective laser sintering process. By changing the conditions of laser beam irradiation, it is possible to build a sintered porous media which has a hole in an arbitrary part by this process. If the mold tool of this structure is used for injection molding, it is proved that the compressed air imprisoned in the mold and the gas coming out of resin are discharged from it, poor molding can be reduced. However, as sintered porous media is hard to control for the size and position of an ordered macroporous structure, it is difficult to build porous media with an ordered macroporous structure deliberately. This results in a smaller amount of airflow and a greater variation in airflow. In order to solve this problem, latticework is proposed as a new gas permeable structure in this paper. Different from a lower density sintered structure, metallic powder is sintered and fused using a laser beam with a high energy density, and fusion is carried out into the latticework structure. The fused gaps of the structure serve as a hole. Since each hole will keep the position and become the ordered macroporous structure even if lamination continues, the improvement in performance of gas permeability is expected. The airflow equation for the structural design to satisfy a required airflow rate is also examined in this paper.

Cite this article as:

H. Narahara, S. Takeshita, H. Fukumaru, H. Koresawa, and H. Suzuki, “Permeability Performance on Porous Structure of Injection Mold Fabricated by Metal Laser Sintering Combined with High Speed Milling,” Int. J. Automation Technol., Vol.6 No.5, pp. 576-583, 2012.

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References

[1] S. Abe, Y. Higashi, H. Togeyama, I. Fuwa, and N. Yoshida, “Development of milling-combined laser metal sintering methodcombination of laser-assisted metal sintering method and the milling in one machine,” J. of the Japan Society for Precision Engineering, Vol.73, No.8, pp. 912-916, 2007.
[2] M. Kojima, H. Narahara, Y. Nakao, H. Fukumaru, H. Koresawa, H. Suzuki, and S. Abe, “Permeability characteristics and applications of plastic injection molding fabricated by metal laser sintering combined with high speed milling,” Int. J. of Automation Technology, Vol.2, No.3, pp. 175-181, 2008.
[3] A. Yassin, T. Ueda, T. Furumoto, A. Hosokawa, R. Tanaka, and S. Abe, “Experimental investigation on cutting mechanism of laser sintered material using small ball end mill,” J. of Materials Processing Technology, Vol.209, Issues 15-16, pp. 5680-5689, 2009.
[4] K. M. Au and K. M. Yu, “Modeling of multi-connected porous passageway for mould cooling,” Computer-Aided Design, Vol.43, Issue 8, pp. 989-1000, 2011.
[5] K. M. Au, K. M. Yu, and W. K. Chiu, “Visibility-based conformal cooling channel generation for rapid tooling,” Computer-Aided Design, Vol.43, Issue 4, pp. 356-373, 2011.
[6] Y. Wang, K.-M. Yu, C. C. L. Wang, and Y. Zhang, “Automatic design of conformal cooling circuits for rapid tooling,” Computer-Aided Design, Vol.43, Issue 8, pp. 1001-1010, 2011.
[7] P. Regenfuss, L. Hartwig, S. Kltzer, R. Ebert, Th. Brabant, T. Petsch, and H. Exner, “Industrial freeform generation of microtools by laser micro sintering,” Rapid Prototyping J., Vol.11, Issue 1, pp. 18-25, 2005.
[8] S. J. Hollister, “Porous scaffold design for tissue engineering,” Nature Materials, Vol.4, pp. 518-524, 2005.
[9] D. F. Heaney, J. D. Gurosik, and C. Binet, “Isotropic forming of porous structures via metal injection molding,” J. of materials science, Vol.40, pp. 973-981, 2005.
[10] R. Kondo, “Porous material – The nature and use –,” Gihodo Publishing Co., Ltd., 1978.

This article is published under a Creative Commons Attribution-NoDerivatives 4.0 Internationa License.

[1] [1] S. Abe, Y. Higashi, H. Togeyama, I. Fuwa, and N. Yoshida, “Development of milling-combined laser metal sintering methodcombination of laser-assisted metal sintering method and the milling in one machine,” J. of the Japan Society for Precision Engineering, Vol.73, No.8, pp. 912-916, 2007.

[2] [2] M. Kojima, H. Narahara, Y. Nakao, H. Fukumaru, H. Koresawa, H. Suzuki, and S. Abe, “Permeability characteristics and applications of plastic injection molding fabricated by metal laser sintering combined with high speed milling,” Int. J. of Automation Technology, Vol.2, No.3, pp. 175-181, 2008.

[3] [3] A. Yassin, T. Ueda, T. Furumoto, A. Hosokawa, R. Tanaka, and S. Abe, “Experimental investigation on cutting mechanism of laser sintered material using small ball end mill,” J. of Materials Processing Technology, Vol.209, Issues 15-16, pp. 5680-5689, 2009.

[4] [4] K. M. Au and K. M. Yu, “Modeling of multi-connected porous passageway for mould cooling,” Computer-Aided Design, Vol.43, Issue 8, pp. 989-1000, 2011.

[5] [5] K. M. Au, K. M. Yu, and W. K. Chiu, “Visibility-based conformal cooling channel generation for rapid tooling,” Computer-Aided Design, Vol.43, Issue 4, pp. 356-373, 2011.

[6] [6] Y. Wang, K.-M. Yu, C. C. L. Wang, and Y. Zhang, “Automatic design of conformal cooling circuits for rapid tooling,” Computer-Aided Design, Vol.43, Issue 8, pp. 1001-1010, 2011.

[7] [7] P. Regenfuss, L. Hartwig, S. Kltzer, R. Ebert, Th. Brabant, T. Petsch, and H. Exner, “Industrial freeform generation of microtools by laser micro sintering,” Rapid Prototyping J., Vol.11, Issue 1, pp. 18-25, 2005.

[8] [8] S. J. Hollister, “Porous scaffold design for tissue engineering,” Nature Materials, Vol.4, pp. 518-524, 2005.

[9] [9] D. F. Heaney, J. D. Gurosik, and C. Binet, “Isotropic forming of porous structures via metal injection molding,” J. of materials science, Vol.40, pp. 973-981, 2005.

[10] [10] R. Kondo, “Porous material – The nature and use –,” Gihodo Publishing Co., Ltd., 1978.

Permeability Performance on Porous Structure of Injection Mold Fabricated by Metal Laser Sintering Combined with High Speed Milling

Hiroyuki Narahara, Sho Takeshita, Hirofumi Fukumaru, Hiroshi Koresawa, and Hiroshi Suzuki

Hiroyuki Narahara, Sho Takeshita, Hirofumi Fukumaru,
Hiroshi Koresawa, and Hiroshi Suzuki