Boiling of Coolant Near the Cutting Edge in High Speed Machining of Difficult-to-Cut Materials

IF 0.9 Q4 AUTOMATION & CONTROL SYSTEMS

International Journal of Automation Technology Pub Date : 2024-05-05 DOI:10.20965/ijat.2024.p0400

Toshiyuki Obikawa, Wataru Matsumoto, Mamoru Hayashi, Chikara Morigo

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Abstract

This study investigates film boiling of coolant as a cooling inhibitor in a narrow wedge-shaped space between the tool flank face and the machined surface of a workpiece, observed during high-speed turning of stainless steel SUS304 and nickel-based superalloy Inconel 718. The boiling, likely triggered by high surface temperatures at both the face and surface close to the cutting edge, impedes coolant access to the tool tip area and efficient cooling. Therefore, the impact of coolant pressure on the boiling zone size was initially explored across pressures ranging from 0.1 to 20 MPa. A burn mark band due to coolant boiling, distinctly visible on the flank face of an insert with a yellow hard coating, expanded over cutting time. The film boiling area width, or the distance from the flank wear area to the band, decreased with increasing coolant pressure, reflecting the enhanced cooling ability and tool life with high-pressure coolant. Applying Boyle–Charles’ law to film boiling indicated that vapor pressure was directly related to coolant velocity rather than pressure. In contrast, the boiling area width increased with increasing cutting speed.

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高速加工难切削材料时切削刃附近冷却液的沸腾现象

本研究调查了在高速车削不锈钢 SUS304 和镍基超合金 Inconel 718 时，在刀具侧面与工件加工表面之间的狭窄楔形空间中作为冷却抑制剂的冷却液膜沸腾现象。沸腾可能是由于靠近切削刃的刀面和表面温度过高引起的，它阻碍了冷却液进入刀尖区域并进行有效冷却。因此，我们在 0.1 至 20 兆帕的压力范围内初步探讨了冷却液压力对沸腾区大小的影响。由于冷却液沸腾而产生的烧痕带在刀片侧面清晰可见，表面有一层黄色的硬涂层，随着切削时间的推移，烧痕带不断扩大。随着冷却液压力的增加，沸腾区宽度（即从刀片侧面磨损区到烧痕带之间的距离）减小，这反映出高压冷却液具有更强的冷却能力和更长的刀具寿命。将波义耳-查尔斯定律应用于膜沸腾表明，蒸汽压力与冷却剂速度而非压力直接相关。相反，沸腾区宽度随切削速度的增加而增加。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Automation Technology AUTOMATION & CONTROL SYSTEMS-

CiteScore

2.10

自引率

36.40%

发文量