切削SiCp/6005Al复合材料的PCD刀具磨损

为研究SiCp/6005Al切削时的刀具磨损机制及刀具磨损对切削力、切削温度、工件表面质量的影响，进行不同转速V和不同进给速度f下的切削试验，观察每组试验刀具切削后的磨损形貌，并通过监测动态切削力和切削温度来探究刀具的磨损机制。结果表明：工件转速提高使切削温度明显升高，但对切削力的影响很小；进给速度提高使切削力明显升高，而切削温度的变化范围较小。改变进给速度带来的力载荷变化是影响前刀面磨损的主要因素，改变工件转速带来的切削温度变化是影响后刀面磨损的主要因素。此外，刀具磨损是磨粒磨损、黏结磨损的综合作用结果，且刀具磨损会对切削力、切削温度和加工表面质量产生不利影响。     

工程陶瓷小砂轮轴向大切深缓进给磨削加工的砂轮磨损分析

小砂轮轴向大切深缓进给磨削以较大切深实现了较高的材料去除率,且使用的砂轮直径比常规磨削用砂轮小很多,我们针对这一特点开展了研究。实验通过改变砂轮转速、工件转速和磨削深度等加工参数,对轴向大切深缓进给磨削加工后的砂轮表面进行了形貌观测和磨损分析。分析表明,砂轮各部分的磨损形式与其在磨削过程中所起的作用有关:砂轮端面是磨削加工的主磨削区,磨粒和结合剂主要发生较大程度的磨损;砂轮圆周面主要对已加工表面进行修磨,因而结合剂和磨粒磨损为主要磨损形式;砂轮拐角作为过渡磨削区,承受的磨削力也比较大,而且由于磨粒与结合剂的结合力相对较小,因此易发生磨粒和结合剂的脱落。     

圆盘锯齿刀超声切削Nomex蜂窝芯力热分析

为探究Nomex蜂窝芯圆盘锯齿刀超声切削过程中切削参数与切削力热的映射关系,开展圆盘锯齿刀超声切削Nomex蜂窝芯复合材料仿真及试验研究,分析主轴转速、进给速度、切削宽度和切削深度对切削过程中切削力热的影响,建立了切削温度随进给速度、主轴转速的一次回归模型。结果表明:所建立仿真模型最大误差为11.2%,可有效预测切削力与切削温度;三向切削力随着切削宽度,切削深度,进给速度的增大而增大,随着主轴转速的增大而减小;进给速度与主轴转速对切削温度影响显著;实际加工中,应采用大切削深度与切削宽度增加切削效率,采用小进给速度和主轴转速以降低切削温度,减少刀具磨损。     

微沟槽织构对切削力和表面粗糙度的影响

为研究微织构对切削过程中产生的切削力和已加工表面粗糙度的影响,在聚晶立方氮化硼(PCBN)刀片前刀面制备与主切削刃平行的宽度为32.6μm的微沟槽织构。分别用微沟槽刀具和无织构刀具在主轴转速为450、500、600 r/min的条件下切削淬硬钢GCr15,分析切削力和已加工表面粗糙度。试验结果表明:微沟槽改善了刀具的切削性能,主切削力、进给力和切深力均小于无织构刀具;进给力、切深力随着主轴转速的增加均变大,主切削力表现为先减小再增大;用微沟槽织构刀具切削的已加工表面粗糙度大于无织构刀具,表明微沟槽不利于获得表面质量较好的工件;随着主轴转速增加,微沟槽刀具和无织构刀具切削的表面粗糙度均减小。     

小直径砂轮超声振动磨削SiC陶瓷的表面质量研究

用小直径砂轮超声振动磨削和普通磨削加工SiC陶瓷零件,对比研究砂轮线速度、工件进给速度、磨削深度和超声振幅对其磨削表面质量的影响。结果表明:与普通磨削相比,超声振动磨削的磨粒轨迹相互交叉叠加,工件表面形貌更均匀,表面质量更好。由于超声振动时的磨粒划痕交叉会使磨粒产生空切削,因而降低了其磨削力,使磨削过程更加稳定。超声振动磨削的表面粗糙度和磨削力随砂轮线速度和超声振幅的增加而降低,随工件进给速度和磨削深度的减小而降低。且砂轮线速度、工件进给速度较小时,超声振动磨削的效果更明显。      

钻削B4C颗粒增强铝合金工艺参数对刀具磨损和孔尺寸精度影响的分析和优化

基于刀具磨损和钻孔尺寸误差等多个性能指标,对B4C颗粒增强铝合金切削加工参数进行评估和优化。通过Taguchi的L27,3水平4因子正交阵列进行实验设计。研究结果表明：磨粒磨损和积屑瘤一般在刀具磨损时形成,同时,边角磨损也具有重大意义。影响切削刀具的侧面磨损主要决定因素是合金中的颗粒质量分数,其次分别是进给速率、钻头的硬度和主轴转速。在所有使用的刀具中,有TiAlN涂层的硬质合金钻头在刀具磨损以及孔尺寸方面具有最佳性能。灰关系分析表明：钻头材料的影响比进给速度和主轴转速的影响更大。在最佳的钻探参数下可以得到最小的刀具磨损和孔直径误差。     

PCD刀具切削天然大理石的磨损特性研究

通过PCD刀具切削天然大理石的试验研究,分析了在不同加工参数条件下对PCD刀具切削性能的影响以及刀具的磨损机理。试验结果表明:PCD刀具在加工过程中的磨损机理主要表现为磨粒的磨损、剥落,聚晶层的破损与结合剂破坏等;刀具主轴转速为12 000 r/min、进给速度为1 000 mm/min、切削深度为0.5 mm时,刀具的磨损量最小;且磨损量随刀具主轴转速的增加而降低,随刀具的进给速度和切削深度的增加而增加。     

基于立式圆台磨削的Si3N4套圈磨削机理与工艺研究

轴承套圈端面形位公差直接影响轴承的精度,为提高氮化硅套圈的加工精度,对套圈端面的宽度变动量进行研究。在立式圆台磨削方式下,采用正交试验,确定各因素对套圈宽度变动量影响的主次顺序,优化获得套圈端面的最佳加工工艺参数;后通过单因素试验,探究单一磨削参数对宽度变动量的影响规律。主轴进给速度对氮化硅套圈宽度变动量影响最为显著,砂轮转速次之,工件转速影响最小;氮化硅套圈宽度变动量随进给速度的增大而增大,随工件转速和砂轮转速的增大先减小后增大;降低进给速度,有利于减小裂纹及凹坑缺陷的产生,提高套圈端面表面质量。在最佳加工工艺参数砂轮转速为800 r/min、进给速度为5μm/min、工件转速为55 r/min下,可获得氮化硅套圈宽度变动量≤6μm,实现氮化硅轴承套圈高效精密加工。     

钎焊金刚石工具磨削CFRP的试验研究

为改善碳纤维增强树脂基复合材料(CFRP)的磨边质量及提高刀具的使用寿命,本研究基于"以磨代切"的思想,制备了钎焊金刚石磨头并对CFRP进行了磨边试验。为了评价CFRP磨边的加工质量,定义了CFRP磨边质量的评价参数——毛边因子,分析了主轴转速以及金刚石粒度对CFRP磨边质量的影响。试验结果表明:在相同的磨削深度、工件进给速度下,主轴转速的增加有助于提高CFRP磨边质量;金刚石粒径越小加工质量越好,细颗粒磨头的加工表面粗糙度更低。     

钎焊金刚石铣磨刀具磨粒粒度尺寸与排布间距对CFRP磨削质量的影响

碳纤维增强复合材料（carbon fiber reinforced plastics,CFRP）由于其低层间结合力和各向异性导致其加工过程中易出现分层、毛刺、撕裂等加工缺陷和刀具耐用度低等问题。采用有序排布钎焊金刚石磨削刀具及"以磨代切"加工工艺能够有效减轻分层缺陷。为制备出适合CFRP磨边加工的钎焊金刚石刀具,本试验制备了不同磨粒排布间距与不同磨粒粒度尺寸的5种刀具,对比分析了刀具结构变化对CFRP磨边加工磨削力与加工表面质量的影响。试验结果表明:在一定范围内,在相同磨粒排布间距和加工参数下,随着磨粒粒度尺寸变大,磨削力变化很小,加工表面质量变差;在相同磨粒粒度尺寸与加工参数下,随着磨粒排布间距减小,磨削力先增大后减小,加工表面质量变好。      

PCD和HTi10刀具铣削CFRP试验研究

针对碳纤维复合材料(CFRP)难加工的特性,文中采用PCD和HTi10刀具进行了CFRP铣削试验,对加工过程中的铣削力、刀具磨损和表面粗糙度进行了分析。结果表明:PCD和HTi10刀具的铣削力和表面粗糙度变化规律一致,均随转速的增大而减小,随进给速度的增大而增大,但PCD刀具的铣削力更小,加工质量更好;与HTi10相比,PCD刀具的铣削力对刀具磨损更加敏感,更适合应用在加工环境较好的条件下。在CFRP加工过程中,粗加工时优选HTi10刀具,精加工时优选PCD刀具,宜选用高转速、低进给的切削参数。     

基于MQL的碳纤维复合材料制孔表面质量及切削力试验

目的 减少碳纤维增强复合材料(CFRP)制孔表面毛刺及边缘凸起等缺陷。方法 对比研究在干切削和微量润滑(MQL)2种加工条件下碳纤维增强复合材料(CFRP)的制孔,在切削速度一定时,探究切削方式、进给速度对制孔尺寸精度、表面质量、切削力的影响。采用方差分析对各影响因素及其权重进行分析。结果 得出了切削方式和工艺参数对制孔尺寸精度、切削力、表面质量的影响规律。试验结果表明,在微量润滑条件下,由于润滑和降温的影响,表面毛刺得到有效去除,纤维断面平整,剪切作用明显,抑制了由温升所引起的边缘隆起膨胀现象,试样的表面质量得到显著提高,切削力整体降低。在干切削和微量润滑条件下对制孔尺寸精度影响最大的是切削方式。对于切削力,在干切削时受到切削方式的影响最大,在微量润滑条件下受到进给速度的影响最大,随着进给速度的增大而增大。结论 在现有试验条件下,微量润滑的加工质量总体上优于干切削的加工质量,其制孔尺寸的精度整体更高,其切削力最大降低了84.26%。     

An experimental investigation on effect of minimum quantity lubrication in machining AISI 1040 steel

The growing demands for high productivity of machining need use of high cutting velocity and feed rate. Such machining inherently produces high cutting temperature, which not only reduces tool life but also impairs the product quality. Application of cutting fluids changes the performance of machining operations because of their lubrication, cooling, and chip flushing functions. But the conventional cutting fluids are not that effective in such high production machining, particularly in continuous cutting of materials likes steels. Minimum quantity lubrication (MQL) presents itself as a viable alternative for turning with respect to tool wear, heat dissipation, and machined surface quality. This study compares the mechanical performance of MQL to completely dry lubrication for the turning of AISI-1040 steel based on experimental measurement of cutting temperature, chip reduction coefficient, cutting forces, tool wears, surface finish, and dimensional deviation. Results indicated that the use of near dry lubrication leads to lower cutting temperature and cutting force, favorable chip–tool interaction, reduced tool wears, surface roughness, and dimensional deviation.     

New tool concept for grinding a plateau-like surface for tribological applications

One of the most important factors for energy efficiency is the reduction of friction in machine elements. The grinding process is often the final machining process in machining hardened steel parts and the resulting surface finish influences the tribological behavior. The combination of grinding with a honing process can generate a plateau-like surface to reduce friction and create an oil reservoir to decrease abrasive wear and improve the fluid film stability. Additional processes like laser machining, micro milling or etching are able to generate micro dimples to improve the reduction of friction. Today, grinding processes are limited to machine plateau-like surfaces. Within this paper, a new tool concept will be presented, composed of a grinding tool with two different grain sizes and a metallic bonding. The use of small abrasive grains generates a smooth surface with low roughness values. A few additional larger grains induce stochastic scratches and create the plateau-like surface. Grinding experiments are conducted to analyze the effect of feed rate, feed angle and ratio between small and large grains on the resulting surface.     

Performance evaluation of solid lubricants in terms of machining parameters in turning

High speed machining of steel inherently generates large cutting temperatures, which not only reduce tool life but also impair the product quality. Application of cutting fluids influences the performance of machining because of its lubrication and cooling actions. Due to the hazards posed by conventional cutting fluids to ecology and health of the workers, there is a greater need to identify eco-friendly and user-friendly alternatives. Modern tribology has facilitated the use of effective unconventional methods like dry cutting, cryogenic cooling, minimum quantity lubrication and the use of solid lubricants. The present work features a specific study on the application of a solid lubricant mixture like Graphite in SAE 40 oil and boric acid in SAE 40 oil in turning of EN8 steel. Experimental results are encouraging with reduction in tool wear and surface roughness as compared to dry and wet machining.     

CVD金刚石刀具微铣削AA356铝合金的磨损分析

AA356铝合金已广泛应用于航空航天等领域,但其在微细加工过程中刀具磨损严重且相关机理尚不明晰.为揭示工艺参数对CVD金刚石刀具微铣削AA356铝合金的刀具磨损影响机制,基于正交试验和响应曲面法开展了微细加工试验,采用最小二乘法和粒子群优化算法建立刀具磨损的预测方程,分析刀具的磨损形貌和切削用量对刀具磨损的影响规律.结...     

Cutting performance of diamond tools during ultra-precision turning of electroless-nickel plated die materials

This study is an attempt (a) to observe the wear characteristic of diamond tool with 200 km cutting distance and to study the effects of wear on the surface roughness and cutting forces and (b) to optimize various cutting parameters such as depth of cut, feed rate, spindle speed and phosphorus content. The experimental results showed that tool wear was not so significant although some defects on rake face were observed after cutting 15.6 km. Further cutting showed that the surface roughness increases with cutting distance, and that the cutting forces were larger than thrust force at the beginning of cutting, but after cutting 130 km, thrust force became larger and increased rapidly. It was also observed that forces increase with the increase of depth of cut, spindle speed and feed rate, and decrease with the increase of phosphorus content of the plating. Depth of cut has no significant effect on surface roughness, while it increases with increase of feed rate and decreases with the increase of percentage of phosphorus content in the workpieces. In case of spindle speed, surface roughness decreases with the increase of spindle speed up to a certain value and then starts to increase with the increase of spindle speed.     

An experimental investigation of the effects of workpiece and grinding parameters on minimum quantity lubrication—MQL grinding

Coolant is a term generally used to describe grinding fluids used for cooling and lubricating in grinding process. The main purposes of a grinding fluid can be categorized into lubrication, cooling, transportation of chips, cleaning of the grinding wheel and minimizing the corrosion. On the other hand, grinding fluids have negative influences on the working environment in terms of the health of the machine operator, pollution and the possibility of explosion (for oil). Furthermore, the cost of the grinding fluid, filtering and waste disposal of the metal working fluids is even higher than the tool cost and constitutes a great part of the total cost. Additionally, grinding fluids can not effectively penetrate into the contact zone, are health hazard and their consumption must be restricted. Generally, compared to other machining processes, grinding involves high specific energy. Major fraction of this energy is changed into heat, which makes harmful effect on the surface quality as well as the tool wear. Since there is no coolant lubricant to transfer the heat from the contact zone in dry grinding, surface damages are not preventable. Alternatives to current practices are getting more serious consideration in response to environmental and operational cost pressures. One attractive alternative is the minimum quantity lubrication (MQL) grinding or the near dry grinding (NDG). In near dry grinding an air–oil mixture called an aerosol is fed into the wheel-work contact zone. Compared to dry grinding, MQL grinding substantially enhances cutting performance in terms of increasing wheel life and improving the quality of the ground parts. In this research, the influences of workpiece hardness and grinding parameters including wheel speed, feed rate and depth of cut have been studied on the basis of the grinding forces and surface quality properties to develop optimum grinding performances such as cooling, lubrication, high ecological and environmental safety.     

石墨烯涂层刀具车削6061铝合金有限元仿真

针对高效干切削和微量润滑加工中润滑能力不足的难题,通过引入石墨烯涂层自组装及界面优化,降低刀具表面自由能,提高刀具的耐磨性和寿命.采用DEFORM软件模拟不同切削速度下石墨烯涂层和非涂层硬质合金刀具切削加工6061铝合金,提取分析试验的切削力和切削热等数据后表明:在一定的切削条件下,石墨烯涂层能有效提高刀具的润滑性能,...     

SiCf/SiC陶瓷基复合材料超声振动辅助切削试验研究

开展了SiCf/SiC陶瓷基复合材料的超声振动辅助切削试验研究,对比研究超声振动辅助切削及普通切削条件下切削参数对切削力的影响规律.结果表明:SiCf/SiC陶瓷基复合材料超声振动辅助切削时优选钎焊金刚石磨头,超声振动辅助切削相较于普通切削的切削力降低了10％～20％,主轴转速、进给速度、切削深度都会影响超声振动辅助切...