Your search keyword '"Hidebumi TAKAHASHI"' showing total 6 results

1. Internal coolant circulation-based tool design to reduce the temperature and heat spreading when turning SUS304 Stainless Steel

Author

Ilia RADCHENKO, Wataru TAKAHASHI, Hidebumi TAKAHASHI, and Hiroyuki SASAHARA

Subjects

machining processes, cutting tool design, cutting temperature, heat distribution, internal cooling, Engineering machinery, tools, and implements, TA213-215, Mechanical engineering and machinery, TJ1-1570

Abstract

The main study objective was to evaluate the influence of the perspective "Internal" (coolant is supplied to the channel inside the indexable insert body) and "Combined" (coolant is supplied to the rake and flank faces through the channel inside the indexable insert body) Cooling Schemes on the temperature of the contact point between the tool and the workpiece, on the heat distribution inside the indexable insert body, and (additionally) on the cutting forces. The contact point temperature and cutting forces were investigated during the non-orthogonal turning of SUS304 Stainless Steel at speeds of 180, 140, and 100 m/min with constant feed and depth of cut. The heat distribution was examined through 2D simulations using DEFORM 2D3D software. The evaluation of the perspective cooling schemes' influence on the selected parameters was performed by comparing the obtained data with the test results of the "traditional" external cooling and dry cutting under similar cutting modes. According to the comparison results, the perspective cooling schemes demonstrated a slight decrease (~3-7%) in the temperature of the contact point between the tool and the workpiece, a significant decrease in the heat distribution (~38-55%) inside the indexable insert body and, in some cases, a decrease of the cutting forces. Based on the study results, the authors confirmed the influence of perspective cooling schemes on the selected parameters and suggested a further positive effect of these schemes' utilization on the cutting tool life.

Published

2024

2. Introduction of Internal Circulation-Based Cooling Methods and Green Coolants in Milling via Cutting Tool and Tooling Design

Author

Ilia Radchenko, Wataru Takahashi, Hidebumi Takahashi, Taro Abe, and Hiroyuki Sasahara

Subjects

machining, milling, cutting tool, tooling, internal circulation, stress test, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

This paper describes the process of the design and verification of a milling tool and tooling that may contribute to the renouncement of the flood cooling method when mineral oils and oil-in-water emulsions are used as coolants. The proposed solutions are based on the idea of coolant supply in internal channels created inside of a cutting tool. As an alternative to the aforementioned mineral oil-based coolants, liquids with higher cooling efficiency and environmental friendliness (green coolants) were considered. Given coolants’ possible lack of lubricating properties and negative (corrosive, etc.) influence on a machine tool’s units, tooling delivers these coolants to the cutting tool and bypasses the standard machine tool’s supply system. The geometry of the milling tool (a cutting insert with an internal channel) was tested in the framework of a stress simulation. To perform it, cutting force components Fz, Fy, and Fx were determined empirically and then applied to the simulated area of contact between the tool and the workpiece. Based on the obtained principal stress values P1, P2, and P3, the factor of safety was calculated with the Mohr–Coulomb, P1 max, and P3 min failure criteria. The proposed milling tool, equipped with a novel type of labyrinth seal with no friction between its components, was experimentally tested to confirm its ability to maintain leak-tightness at different values of spindle speed (200~2000 rpm) and coolant supply volume (1.0~10.0 L/min). Based on the results of the stress simulation and the leak-tightness experiment, conclusions were drawn about further modernization and utilization prospects of the proposed milling tool and tooling design.

Published

2024

3. Precise Laser Assisted Machining of Titanium Alloys (Ti-6Al-4V)

Author

Hidebumi Takahashi, Chaoran Wei, Yusuke Ito, Zhenzhi Ying, and Naohiko Sugita

Subjects

Materials science, Machining, Metallurgy, Titanium alloy, Ti 6al 4v, Laser assisted

Published

2019

4. B022 High Speed Machining of Stainless Steel Using Low-Pressure Jet Coolant

Author

Mamoru Hayashi, Tatsumi Ohno, Takayuki Kumakiri, Hidebumi Takahashi, Ryuta Nakatsukasa, and Toshiyuki Obikawa

Subjects

Jet (fluid), Materials science, Machining, Metallurgy, General Medicine, Coolant

Published

2013

5. Friction and Wear of Sintered Mg-B Alloys

Author

Katsuhiro Nishiyama, Hidebumi Takahashi, Takayuki Sekino, and Jiro Saito

Subjects

Materials science, Carbon steel, Magnesium, Mechanical Engineering, Metallurgy, Metals and Alloys, chemistry.chemical_element, engineering.material, Industrial and Manufacturing Engineering, Wear resistance, chemistry, Powder metallurgy, Materials Chemistry, engineering, Boron, Sliding wear

Abstract

Sliding wear behavior of newly developed of magnesium base hard alloys containing magnesium borides carbon steel (SUJ2) wear studied by ring-on-block type Ogoshi wear resislance teste at sliding velocities of 3.55m/s, load of 20.6N and sliding distance of 66.6m to 600m. The new hard alloys exhibits better wear resistance and gives less than conventional magnesium alloys. The excellent wear performance of the new hard alloys are attributed to the improvement of hardness and the formation of oxides such as MgO and B2O3, which may act as lubricants during slides.

Published

1999

6. Vibration damping tool

Author

Hidebumi Takahashi and Ishikawa Yoichi

Subjects

Vibration, Chatter vibration, Materials science, Acoustics and Ultrasonics, Arts and Humanities (miscellaneous), Base (geometry), Composite material

Abstract

A vibration damping tool having the following structure is provided. In the vibration damping tool, a hollow portion is formed in the interior of the distal end portion of a tool body and one end of a weight member is connected to the inner wall surface of the distal end side of this hollow portion. A gap created between the outer peripheral surface of the weight member and the inner wall surface of the hollow portion is filled with a visco-elastic body. The one end of the weight member is formed as a narrow diameter shaft portion. The tool body can be divided into two and freely removed from and reattached at a dividing surface located on the base end side of the hollow portion. A hole portion is formed inside the other end of the weight member by hollowing out the interior thereof. Chatter vibration is thus absorbed using a simple structure without there being any effects from heat generated during cutting processing.

Published

2006