Characterisation on the effects of workpiece microstructure and process parameters on resiudal stresses generated during machining

表征工件显微组织和工艺参数对加工过程中产生的残余应力的影响

• 批准号: 355712-2008
• 负责人: Ng, EuGene
• 金额: $ 1.46万
• 依托单位: McMaster University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2011
• 资助国家: 加拿大
• 起止时间: 2011-01-01 至 2012-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=482826
• 关键词: Characterisation; effects; workpiece; microstructure; process

The long term objective is to numerically model the effects of workpiece micro structure and process parameters on residual stresses generate in the machined surface after single point turning. Short term research is comprised of studies on a) develop a combine numerical and experimental method to determine the friction coefficient along the tool-chip interface and investigate the operating boundary for this method, b) design using the Arbitrary Lagrangian Eulerian formulation technique to simulate the effects of sequential cut, cutting edge radius and feed on residual stresses, c) develop a numerical model to simulate the effects of workpiece microstructure and phase transformation on residual stresses and d) numerically and experimentally investigate the effects of flank wear length, cutting edge radius to feed ratio, tool coating, and process parameters on residual stresses. This research will develop a unique methodology to acquire actual friction coefficient induced during machining by using both numerical and experimental approaches. The effect of tool holder on tool deflection during the cutting process will also be modeled. Influence of sequential cut on the final residual stress profile will also be analyzed. The F.E. model developed to predict residual stresses will be based on either an implicit solver or analytical approach, which will reduced computational time substantially. Models will also be developed to predict the highly complex effects of phase transformation and workpiece micro structure on residual stresses. The significant of this research is to enhance the knowledge on modeling of residual stresses, which will enable researchers to optimize machining parameters for fatigue loaded components in the aerospace, medical and automotive sectors in terms of maximization of compressive residual stresses in both magnitude and penetration depth. Furthermore, this technology will assist design for manufacture protocol in reduction of post machining stages like shot peening, improved fatigue performance and reduce part distortion induced by residual stresses. Residual stress seminar will be organised at McMaster for Mechanical, Materials & Manufacturing engineers to present research discovery from this grant.

长期目标是数值模拟工件微观结构和工艺参数对单点车削加工表面残余应力的影响。短期研究包括以下研究a）开发一种联合收割机数值和实验方法来确定沿着刀具-切屑界面的摩擦系数并研究该方法的操作边界，B）使用任意拉格朗日欧拉公式技术进行设计，以模拟连续切削、切削刃半径和进给对残余应力的影响，c）开发数值模型以模拟工件微观结构和相变对残余应力的影响，以及d）数值地和实验地研究后刀面磨损长度、切削刃半径与进给比、刀具涂层和工艺参数对残余应力的影响。本研究将发展一种独特的方法，以获得实际的摩擦系数在加工过程中，通过使用数值和实验的方法。在切削过程中，刀具保持器对刀具偏转的影响也将被建模。还将分析连续切割对最终残余应力分布的影响。联邦调查局预测残余应力的模型将基于隐式求解器或解析方法，这将大大减少计算时间。还将开发模型来预测相变和工件微观结构对残余应力的高度复杂的影响。这项研究的意义在于提高对残余应力建模的认识，这将使研究人员能够优化航空航天，医疗和汽车行业中疲劳载荷部件的加工参数，以最大限度地提高残余压应力的大小和穿透深度。此外，该技术将有助于制造方案的设计，减少后加工阶段，如喷丸，提高疲劳性能，减少由残余应力引起的零件变形。残余应力研讨会将在麦克马斯特为机械，材料和制造工程师举办，以介绍这项资助的研究发现。