Development of Desktop Machine Tool with Pipe Frame Structure

Naohiko Suzuki; Yoshitaka Morimoto; Keigo Takasugi; Ryo Kobashi; Ryo Hirono; Yoshiyuki Kaneko; Yutaka Tokuno

doi:10.20965/ijat.2015.p0720

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IJAT Vol.9 No.6 pp. 720-730

doi: 10.20965/ijat.2015.p0720

(2015)

Paper:

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Development of Desktop Machine Tool with Pipe Frame Structure

Naohiko Suzuki^*, Yoshitaka Morimoto^, Keigo Takasugi^, Ryo Kobashi^**, Ryo Hirono^, Yoshiyuki Kaneko^, and Yutaka Tokuno^*

^*Takamatsu Machinery CO.,LTD.
1-8 Asahigaoka hakusan, Isikawa, Japan

^**Kanazawa Institute of Technology
7-1 Ohgigaoka Nonoichi, Ishikawa, Japan

Received:

June 5, 2015

Accepted:

September 9, 2015

Published:

November 5, 2015

Keywords:

machine tool, milling, pipe frame, truss structure, desktop

Abstract

While many components used in automobiles, household electric appliances, etc., are becoming more compact, the size of most machine tools used to work on such components remains unchanged. Therefore, to improve the efficient use of factory space and economical use of energy, machine tools that are comparable in size to workpieces are required. Thus far, we have focused our developmental efforts on the miniaturization of machine tools, e.g., a lathe with a width ten times the machining diameter of a workpiece and a lathe with a bed made of a pipe frame truss structure. Based on these past study results, we have newly developed a desktop machine tool with a pipe frame structure. This paper reports on the developmental background and overview of the developed machine tool, its characteristics, its evaluation results, and our future plans.

Cite this article as:

N. Suzuki, Y. Morimoto, K. Takasugi, R. Kobashi, R. Hirono, Y. Kaneko, and Y. Tokuno, “Development of Desktop Machine Tool with Pipe Frame Structure,” Int. J. Automation Technol., Vol.9 No.6, pp. 720-730, 2015.

Data files:

References

[1] “Mizuho Industry Focus – The current state and problem of Japanese Machine tool,” Industrial Morgue of Mizuho Corporate Bank, pp. 17, 2010 (in Japanese).
[2] Y. Okazaki, “Microfactories – A New Methodology for Sustainable Manufacturing –,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 82-87, 2010.
[3] H. Ohmori and Y. Uehara, “Development of a Desktop Machine Tool for Mirror Surface Grinding,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 88-96, 2010.
[4] H. Kato, K. Shintani, and K Iwata, “High-Speed Milling Using a Developed Desktop Machine Tool,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 103-109, 2010.
[5] K. Ashida, S. Nakano, J. Park, and J Akedo, “On-Demand MEMS Device Production System by Module-Based Microfactory,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 110-116, 2010.
[6] R. Heikkila, E Jarvenpaak, and R. Tuokko, “Advances in the TUT Microfactory Concept Development,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 117-126, 2010.
[7] J. Park, S. Ro, B. Kim, W. Shin, and H. Lee, “Precision Component Technologies for Microfactory Systems Developed at KIMM,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 127-137, 2010.
[8] T. Ogawa, “Building of Efficient, Energy-Saving Lines with an Extremely-Compact Machining Center and CNC Lathe,” Int. Journal of Automation Technology, Vol.4 No.2, pp. 150-154, 2010.
[9] Y. Kaneko, N. Suzuki, K. Kanahira, H. Wada, and M. Yamano, “Development of Ultra Slim Utility Type CNC Lathe Adapted to Automation – An Approach to Energy Conservation from Machine Shops –,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 138-149, 2010.
[10] I. Tanabe and Y. Kawasaki, “Development of Ceramic Resin Concrete for Precision Machine Tool Structures(1^st Report, Yong’s Modulus and the Compressive Strength of THE Ceramics Resin Concrete),” Japan Society of Mechanical Engineers, Vol.57C, No.543, pp. 314-319, 1991.
[11] C. Endo, “Small Processing Machinery Effectiveness in Micropart Processing and Factory Construction with Desktop Production Equipment,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 155-160, 2010.
[12] https://visai.jp/ [accessed April 22, 2015]
[13] N. Suzuki and Y. Morimoto, “Development of Ultra Small Size CNC Lathe by pipe frame structure,” Proc. of 4^th CIRP Int. Conf. on High Performance Cutting, Vol.2, pp. 183, 2010.
[14] N. Suzuki and Y. Morimoto, “Development of Pipe Structure Frame for CNC lathe,” Emerging Technology in Precision Engineering, pp. 502, 2012.
[15] Y. Morimoto and N. Suzuki, “Vibration Control of CNC Lathe with Pipe Structure Frame – Evaluation of Vibration suppression by Adopting of Active Vibration Control –,” JSPE, Vol.78, No.5, pp. 420-425, 2012.
[16] N. Suzuki and Y. Morimoto, “Development of Ultra Small Size CNC Lathe USL Series (3^rd report) – The characteristic evaluation that a pipe frame bed is fundamental –,” The Japan Society for Precision Engineering, pp. 511-512, 2008.

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

[1] [1] “Mizuho Industry Focus – The current state and problem of Japanese Machine tool,” Industrial Morgue of Mizuho Corporate Bank, pp. 17, 2010 (in Japanese).

[2] [2] Y. Okazaki, “Microfactories – A New Methodology for Sustainable Manufacturing –,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 82-87, 2010.

[3] [3] H. Ohmori and Y. Uehara, “Development of a Desktop Machine Tool for Mirror Surface Grinding,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 88-96, 2010.

[4] [4] H. Kato, K. Shintani, and K Iwata, “High-Speed Milling Using a Developed Desktop Machine Tool,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 103-109, 2010.

[5] [5] K. Ashida, S. Nakano, J. Park, and J Akedo, “On-Demand MEMS Device Production System by Module-Based Microfactory,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 110-116, 2010.

[6] [6] R. Heikkila, E Jarvenpaak, and R. Tuokko, “Advances in the TUT Microfactory Concept Development,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 117-126, 2010.

[7] [7] J. Park, S. Ro, B. Kim, W. Shin, and H. Lee, “Precision Component Technologies for Microfactory Systems Developed at KIMM,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 127-137, 2010.

[8] [8] T. Ogawa, “Building of Efficient, Energy-Saving Lines with an Extremely-Compact Machining Center and CNC Lathe,” Int. Journal of Automation Technology, Vol.4 No.2, pp. 150-154, 2010.

[9] [9] Y. Kaneko, N. Suzuki, K. Kanahira, H. Wada, and M. Yamano, “Development of Ultra Slim Utility Type CNC Lathe Adapted to Automation – An Approach to Energy Conservation from Machine Shops –,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 138-149, 2010.

[10] [10] I. Tanabe and Y. Kawasaki, “Development of Ceramic Resin Concrete for Precision Machine Tool Structures(1^st Report, Yong’s Modulus and the Compressive Strength of THE Ceramics Resin Concrete),” Japan Society of Mechanical Engineers, Vol.57C, No.543, pp. 314-319, 1991.

[11] [11] C. Endo, “Small Processing Machinery Effectiveness in Micropart Processing and Factory Construction with Desktop Production Equipment,” Int. Journal of Automation Technology, Vol.4, No.2, pp. 155-160, 2010.

[12] [12] https://visai.jp/ [accessed April 22, 2015]

[13] [13] N. Suzuki and Y. Morimoto, “Development of Ultra Small Size CNC Lathe by pipe frame structure,” Proc. of 4^th CIRP Int. Conf. on High Performance Cutting, Vol.2, pp. 183, 2010.

[14] [14] N. Suzuki and Y. Morimoto, “Development of Pipe Structure Frame for CNC lathe,” Emerging Technology in Precision Engineering, pp. 502, 2012.

[15] [15] Y. Morimoto and N. Suzuki, “Vibration Control of CNC Lathe with Pipe Structure Frame – Evaluation of Vibration suppression by Adopting of Active Vibration Control –,” JSPE, Vol.78, No.5, pp. 420-425, 2012.

[16] [16] N. Suzuki and Y. Morimoto, “Development of Ultra Small Size CNC Lathe USL Series (3^rd report) – The characteristic evaluation that a pipe frame bed is fundamental –,” The Japan Society for Precision Engineering, pp. 511-512, 2008.

Development of Desktop Machine Tool with Pipe Frame Structure

Naohiko Suzuki*, Yoshitaka Morimoto**, Keigo Takasugi**, Ryo Kobashi**, Ryo Hirono*, Yoshiyuki Kaneko*, and Yutaka Tokuno*

Naohiko Suzuki^*, Yoshitaka Morimoto^, Keigo Takasugi^, Ryo Kobashi^**, Ryo Hirono^, Yoshiyuki Kaneko^, and Yutaka Tokuno^*