PCD刀具微细铣削硬质合金刀具磨损研究

使用PCD刀具进行微细铣削硬质合金的刀具磨损试验,研究了PCD微细铣刀的磨损形态和磨损机理。结果表明,PCD微细铣刀的磨损主要集中在刀尖和底刃上,造成刀具磨损的原因主要包括粘结磨损、磨料磨损以及微崩刃。刀具磨损导致硬质合金加工表面粗糙度逐渐增大。     

TiAlN涂层硬质合金刀具铣削35CrMoSiV钢的切削性能研究

采用有和无PVD TiAlN涂层的细晶硬质合金铣刀对35CrMoSiV合金钢进行了干式端面铣削试验。分别测量了有、无涂层情况下铣刀后刀面径向磨损量和加工槽的表面粗糙度,通过光学显微镜观察了切屑,利用扫描电子显微镜(SEM)和电子能谱(EDX)分析了后刀面的磨损形态。研究结果表明:TiAlN涂层明显提高了硬质合金刀具的切削性能;硬质合金刀具后刀面磨损机制主要为粘着磨损和磨粒磨损,而涂层损伤是粘着磨损、剥层和氧化磨损共同作用的结果;在正常工作区内,提高铣削的转速和进给量,有利于减轻刀具的粘着,提高切削效率和质量。     

微铣刀几何参数对脆性微细等静压石墨件高速精密铣削的影响研究

等静压各向同性石墨是目前太阳能光伏业、模具制造业和国防科技应用的重要基础材料,提升脆性微细等静压石墨零件的高速精密加工技术是关键。通过高速铣削试验研究刀具几何参数(包括前角、后角和螺旋角)对切削力、刀具磨损和切削振动的影响规律。结果表明,合理选择微铣刀的几何参数可有效降低切削力、后刀面磨损量和振动加速度,为微细石墨零件高速精密制造用涂层硬质合金微铣刀的几何参数优化提供了理论依据。     

基于刀具磨损映射关系的微细铣削力理论建模与试验研究

微细铣削加工过程中,刀具直径小且磨损较快,刀具磨损对微细铣削力有着明显的非线性影响,同时刀具跳动又对刀具每齿的磨损表现出不同的影响效应,这些影响因素会导致加工过程的不稳定性和精度。然而,目前缺乏考虑具有刀具跳动和磨损效应的通用微细铣削力模型,研究了刀具跳动与刀具每齿磨损量之间的变化规律,提出了一种同时包括刀具跳动和刀具磨损效应的新型的微细铣削力模型。该模型中,根据刀具每齿磨损量与切削位置的几何关系,改进了瞬时切削厚度模型,基于不同切削刃所对应的受力情况,同时将刀具直径方向上磨损变化量与力模型系数相关联,从而来提高力模型的精确度。最后,通过不同铣削参数下的铣削试验,论证了所提出模型的准确性和有效性。利用所提出的模型,可以通过监测铣削力的大小来辨别刀具尺寸是否在可持续铣削的范围内,从而提高微铣削的加工精度和效率。     

高速面铣加工的动态铣削力和刀具振动研究

基于力学式切削力预测方法建立了面铣刀动态铣削模型,该模型充分考虑切削厚度、刀具前角和刀具后刀面磨损对铣削力的影响.在Matlab/Simulink环境下,进行了动态铣削力和刀具振动仿真及其频谱分析,并根据仿真结果对转速、齿数、刀具磨损量等影响因素进行了分析验证,该模型有利于揭示各切削参数对动态铣削力和刀具振动的影响规律,从而为实现切削加工参数优化提供理论支持.     

后刀面磨损对加工表面残余应力的影响研究

残余应力是衡量加工表面质量的一项重要指标,切削过程中刀具后刀面磨损会对加工表面残余应力产生重要影响。以弱刚度高精度件齿圈为研究对象,研究后刀面磨损对残余应力的影响。设计了刀具磨损几何模型,建立了齿圈切削二维仿真有限元模型,通过仿真分析了不同后刀面磨损量条件下齿圈加工表面残余应力,得到了残余应力随后刀面磨损量的变化规律,并利用钻孔法测试了残余应力,结果表明,仿真数据可靠。     

硬质合金立铣刀铣削Cr12MoV淬硬钢的刀具使用寿命研究

针对模具高硬材料Cr12Mo V淬硬钢台阶面铣削过程中刀具磨损、破损严重的问题,使用硬质合金立铣刀进行了Cr12Mo V淬硬钢的铣削正交试验。采用二次元影像测量仪观察刀具的主要磨损形态与破损形式,得出刀具的磨损形态主要是前刀面磨损和后刀面磨损,破损形式主要是刀尖崩碎;通过多元线性回归方法建立了刀具使用寿命的经验公式,运用极差法分析了各铣削参数对刀具使用寿命的影响程度,同时应用F检验方法分析了模型的拟合程度,在综合考虑刀具使用寿命和加工效率的前提下进行了铣削参数优选,研究结果为提高硬质合金立铣刀刀具使用寿命的研究提供了理论依据。     

高速铣削时钛合金刀具的磨损及对工件表面粗糙度的影响

观察高速铣削钛合金刀具时后刀面及被加工表面的形貌,通过对刀具后刀面磨损量和被加工表面粗糙度值的测量研究了刀具磨损对被加工表面粗糙度的影响,揭示了钛合金铣削加工时提高表面质量的规律。     

铣削碳纤维复合材料刀具磨损试验研究

采用未涂层和CVD金刚石薄膜涂层两种硬质合金铣刀,对碳纤维复合材料进行铣削试验,使用3D激光扫描镜对刀具磨损形貌和磨损量进行测量,分析了刀具的磨损机理和切削用量对刀具磨损的影响。试验结果表明：后刀面磨损是两种刀具的主要磨损形式,磨损机理为磨料磨损,未涂层硬质合金铣刀同时存在着刀具破损现象;切削速率和背吃刀量对刀具后刀面的磨损影响较为显著;未涂层与CVD金刚石薄膜涂层硬质合金铣刀相比较,后刀面的磨损量保持在2．3—3．8倍之间,从刀具的耐磨性考虑,CVD金刚石薄膜涂层硬质合金铣刀可以用于碳纤维复合材料的生产加工。     

基于高斯过程回归方法的钛合金铣削刀具磨损预测

通过钛合金材料切削试验,对铣削加工中切削参数对高进给铣刀刀齿后刀面最大磨损量的影响规律进行分析。采用高斯过程回归法建立了刀齿后刀面最大磨损宽度的预测模型,并进行试验验证。预测结果与试验结果吻合程度较高,验证了预测模型的有效性,为钛合金铣削刀具的磨损预测提供了理论方法和试验依据。     

Experimental Study on Wear Characteristics of PCBN Tool with Variable Chamfered Edge

Owing to heavy dynamic and thermal loads, PCBN tools are seriously worn during hard cutting, which largely constrains the improvement of their machining performance. Therein, the chamfered structure of a cutting edge has a notable influence on the tool wear. Thus, a comparative study was carried out on the wear morphology and wear mechanism of PCBN tools with either a variable chamfered edge or an invariable chamfered edge. The results indicate that, for a PCBN tool with a variable chamfered edge, the rake wear area is far from the cutting edge and slowly extends toward it. A shallow large-area crater wear occurs on the rake face, and the flank wear area has a long triangular shape with a smaller wear area and width, and the cutting edge remains in a good state during the cutting process. In contrast, for a PCBN tool with an invariable chamfered edge, a deep small-area crater appears on the rake face,and the wear area is close to the cutting edge and quickly extends toward it. Thus, it is easy for chips to accumulate in the crater, resulting in large-area and high-speed wear on the flank face. In addition, the tool shows a weak wear resistance. In the initial wear stage, the rake wear mechanism of the two cutting tools is a mixture of abrasive, oxidation, and other types of wear, whereas their flank wear mechanism is dominated by abrasive wear. With an aggravation of the tool wear, the oxidation and di usion wear mechanism are both increasingly strengthened. The rake wear of the cutter with a variable chamfered edge showed an obvious increase in the oxidation and di usion wear, as did the flank wear of the cutter with an invariable chamfered edge. This study revealed the wear mechanism of the PCBN tool with a variable chamfered edge and provided theoretical and technological support for its popularization and application in the machining of high-hardness materials.     

钛合金铣削过程刀具前刀面磨损解析建模

钛合金Ti6Al4V作为典型的航空航天难加工材料,在其铣削过程中硬质合金刀具的磨损会降低加工过程稳定性,进而影响加工效率和已加工表面表面质量。刀具前刀面磨损会导致刀具刃口强度降低,并影响切屑的流向和折断情况。针对前刀面磨损机理进行分析并构建了月牙洼磨损深度预测模型。首先运用解析方法构建了前刀面应力场模型,得到切屑在前刀面滑动过程中的刀具前刀面应力分布情况及磨损位置。基于刀-屑接触关系的基础上建立了前刀面温度场模型。然后,基于所得刀具前刀面应力与温度分布,构建综合考虑磨粒磨损、粘结磨损与扩散磨损的铣刀月牙洼磨损深度预测模型,获得月牙洼磨损预测曲线;结合铣刀月牙洼磨损带沿切削刃方向分布的特点,建立了随时间变化的铣刀前刀面磨损体积预测模型。最后通过试验验证了切削宽度对前刀面磨损的影响规律,预测结果与试验测量值具有较好的吻合性。结果表明随着切削宽度的增加,月牙洼磨损深度及前刀面磨损体积都随之增加。研究结果为钛合金铣削用刀具的设计和切削参数的合理选择提供了理论基础。     

Cutting performance of nano-crystalline diamond (NCD) coating in micro-milling of Ti6Al4V alloy

Hard coatings are an important factor affecting the cutting performance of tools. In particular, they directly affect tool life, cutting forces, surface quality and burr formation in the micro-milling process. In this study, the performance of nano-crystalline diamond (NCD) coated tools was evaluated by comparing it with TiN-coated, AlCrN-coated and uncoated carbide tools in micro-milling of Ti₆Al₄V alloy. A series of micro-milling tests was carried out to determine the effects of coating type and machining conditions on tool wear, cutting force, surface roughness and burr size. Flat end-mill tools with two flutes and a diameter of 0.5 mm were used in the micro-milling process. The minimum chip thickness depending on both the cutting force and the surface roughness were determined. The results showed that the minimum chip thickness is about 0.3 times that of the cutter corner radius for Ti₆Al₄V alloy and changes very little with coating type. It was observed from wear tests that the dominant wear mechanism was abrasion. Maximum wear occurred on NCD-coated and uncoated tools. In addition, maximum burr size was obtained in the cutting process with the uncoated tool.     

The effects of progressive tool wear and tool restricted contact on chip breakability in machining

Chip breakability plays an essential role in automated machining systems. This paper presents an experimental investigation of the effects of progressive tool wear and the resulting formation of the tool restricted contact on chip breakability in a turning operation. Six parameters of tool wear, namely, major flank wear (VB), crater wear depth (KT), crater wear length (KK), crater wear width (KB), wear retract of cutting edge (KS) and nose wear (N), are shown to contribute to the variations of chip breakability with tool wear progression. The results show that the chip breakability varies significantly with tool wear progression, especially with the combined crater and flank wear progression, and contributes to the development of a restricted rake face land, making the tool behave like a restricted contact grooved tool. The chip curling and breaking action is largely influenced by the nature and magnitude of the restricted contact and the groove profile being developed on the tool face. The results presented in this paper are also intended to provide guidelines for designing effective chip grooves on the tool face.     

Wear of CBN Tools in Ultra-Precision Machining of STAVAX

CBN cutting tools are widely used in ultra-precision machining of STAVAX (specialized stainless steel) mould inserts for injection moulding of optical lenses. This paper will report on experiments carried out to investigate the wear of CBN tools with different grain sizes and various CBN/TiN ratios in ultra-precision machining of STAVAX. The tool-wear characteristics were observed to be greatly dependent on the tool type, hardness of the STAVAX and cutting parameters used. In the machining of STAVAX with a hardness of 55 HRC, fine-scale cavities were formed on the rake face and as such the surface damage acted like a chip breaker resulting in formation of cracks. While the flank faces of all tool types showed a similar wear resistance, it was observed that a combination of a higher percentage of TiN binder and smaller grain size led to greater wear resistance on the rake face. It was found that the formation of cracks on the rake faces could be prevented by means of either increasing the cutting speed or reducing the hardness of the machined workpiece.     

基于车铣技术的刀具磨损和破损分析

在车铣加工中心上，分别采用硬质合金和TiN涂层硬质合金刀片，对铝合金和不锈钢工件进行了车铣加工的刀具磨损试验，研究分析了车铣刀具的磨损和破损特征。研究表明，车铣铝合金的刀具磨损机理主要以刀具表层材料的黏结磨损为主，而车铣不锈钢的刀具磨损机理主要以刀具表层材料的疲劳-剥落磨损为主。车铣不锈钢时，刀具的损坏形式常常以微崩刃、前刀面的剥落和碎断等破损形态为主。     

S形刃口球头铣刀加工的误差分析

文章探讨了研制S形球头铣刀的意义，在加工刀具的前刀面和后刀面的数学模型基础上，研究了误差数学模型，并探讨了工业实现的可行性机构，给出了相关的数学公式和加工数据，最后给出加工可行的各参数误差范围，得出结论用2轴可以实现在传统上用4轴数控机床才能加工的S形球头铣刀，并可以保证加工精度。     

Wear of Ceramic Cutting Tools in Ni-Based Superalloy Machining

The machining performance of monolithic and composite silicon nitride and Al₂O₃-based cutting tools in continuous turning of Inconel 718 was examined. The character of tool wear has been found to vary, depending on the feed rate and cutting speeds. At a lower cutting speed, of 120 m/min, tool life is restricted by depth-of-cut notching, while at high cutting speeds (300 m/min), tools fail due to nose wear and fracture. The sensitivity of monolithic Si₃N₄ and Al₂O₃ to depth-of-cut notching was found to he significantly reduced with the addition of SiC whiskers, and to a lesser extent with TiC particulates. The ceramic composites also exhibited resistance to nose and flank wear that was higher than that of the monoliths. The internal stress distribution for the cutting tool has been calculated using the finite element method and is the basis for explaining fracture beneath the rake face. Cutting tool wear results are discussed in terms of chemical and mechanical properties of the ceramic tool material, abrasive wear, thermal shock resistance, and metal cutting conditions.     

高速干切削铁基粉末冶金零件时细晶粒硬质合金刀具的切削性能研究

用细晶粒硬质合金刀具进行了铁基粉末冶金零件的高速干切削试验。研究了切削参数与刀具耐用度以及加工表面粗糙度的关系,给出了刀具的主要磨损形态,通过能谱分析研究了刀具的磨损机理。结果表明:所选用细晶粒硬质合金刀具具有较高的刀具耐用度和较好的加工表面粗糙度,适合于铁基粉末冶金的加工;细晶粒硬质合金的主要磨损形态是前刀面的月牙洼磨损;主要磨损机理是扩散磨损、粘结磨损。     

Blend of sharpness and strength on a ball nose endmill geometry for high speed machining of Ti6Al4V

The applications of titanium alloys are increasingly common at marine, aerospace, bio-medical and precision engineering due to its high strength to weight ratio and high temperature-withstanding properties. However, whilst machining the titanium alloys using the solid carbide tools, even with application of high pressure coolant, reduced tool life was widely reported. The generation of high temperatures at the tool–work interface causes adhesion of work material on the cutting edges, and hence, shorter tool life was reported. In order to reduce the high tool–work interface temperature-positive rake angle, higher primary relief and higher secondary relief were configured on the ball nose endmill cutting edges. Despite of careful consideration of tool geometry, after an initial working period, the growth of flank wear accelerates the high cutting forces followed by work material adhesion on the cutting edges. Hence, it is important to blend the strength, sharpness, geometry and surface integrity on the cutting edges so that the ball nose endmill would exhibit an extended tool life. This paper illustrates the effect of ball nose endmill geometry on high speed machining of Ti6Al4V. Three different ball nose endmill geometries were configured, and high speed machining experiments were conducted to study the influence of cutting tool geometry on the metal cutting mechanism of Ti-6Al-4V alloy. The high speed machining results predominantly emphasize the significance of cutting edge features such as K-land, rake angle and cutting edge radius. The ball nose endmills featured with a short negative rake angle of value ?5° for 0.05～0.06 mm, i.e. K-land followed by positive rake angle of value 8°, has produced lower cutting forces signatures for Ti-6Al-4V alloy.