基于多颗磨粒随机分布的虚拟砂轮建模及磨削力预测

利用VHX-600E型超景深显微镜测量了金刚石砂轮表面的磨粒分布情况,计算得到了砂轮表面的磨粒密度、真实接触弧长以及砂轮总的磨粒数和有效磨粒数。基于磨粒间隔分布假设和虚拟格子方法在虚拟砂轮端面随机分布等磨粒密度的多颗正六面体磨粒,并随机分配磨粒的位姿以模拟砂轮的真实形貌。将1/4虚拟砂轮模型导入Deform-3D软件中,建立三维虚拟磨削仿真模型,采用Lagrangian Incremental算法获得多颗磨粒的仿真磨削力值,并建立了基于多颗磨粒磨削仿真的磨削力预测模型。通过金刚石砂轮端面磨削硬质合金刀片的实验,比较了实测磨削力与预测磨削力;仿真与实验结果具有一致性,证明了采用本方法建立的多颗磨粒虚拟磨削仿真模型可以用于磨削力预测,为多颗磨粒共同磨削的磨削力研究提供了新的思路。     

新型刚玉砂轮磨削GH4169镍基高温合金的性能评价研究

镍基高温合金是航空发动机部件的常用材料,其磨削加工存在工具损耗严重、寿命短等难题。针对3种新研制的刚玉砂轮(分别为粒度60#的微晶和单晶混合磨料砂轮、粒度60#的单晶刚玉砂轮,以及粒度70#的单晶刚玉砂轮),开展了GH4169镍基高温合金材料的磨削试验,从磨削力、磨削温度、砂轮磨损以及表面粗糙度等方面对3种砂轮的磨削性能进行了评价。结果表明,3种砂轮磨削GH4169材料在砂轮磨损和表面粗糙度方面未表现出明显差异,而通过对磨削力和磨削温度的综合评价发现粒度60#的单晶刚玉砂轮的磨削性能更优。3种砂轮磨削GH4169材料的磨削比在0.5~3之间。在正常磨削条件下,3种砂轮的磨削表面粗糙度Ra小于0.4μm。同时发现,砂轮磨损(主要包括磨粒的破碎和脱落)是造成磨削表面缺陷形成的重要原因。     

电镀砂轮磨损对GH4169磨削表面完整性的影响

电镀砂轮具有优异的成型性和形状保持能力,越来越广泛地应用于复杂曲面的加工,但是磨损对零件表面完整性影响的研究并不充分.在深入分析利用圆环型砂轮在插磨方式下加工GH4169试件所产生的表面形貌形成规律的基础上,对高刚度矩形试件的磨削表面粗糙度随砂轮磨削量的变化进行了详细记录,并对某型号发动机静子叶片进行实际磨削验证.试验结果表明,精磨时适当的砂轮磨损可以使高刚度试件表面粗糙度下降35％,对表面硬度和残余应力影响不大;而叶片的弱刚度会大幅提高磨削粗糙度,但适当的砂轮磨损可以使叶片端部粗糙度下降64％,并降低刚度对粗糙度的影响,进而提高叶片表面磨削质量的一致性.因此,通过磨削粗糙度对砂轮的磨损状况进行大致评估,选择合适磨损量的砂轮用于精加工,以充分降低工件的表面粗糙度并提高磨削质量的一致性.     

镍基高温合金GH4169磨削参数对表面完整性影响

研究了用单晶刚玉砂轮磨削镍基高温合金GH4169时,磨削参数对表面完整性中的表面特征(表面粗糙度、表面形貌、表面显微硬度和表面残余应力)的影响,以期优化磨削参数.砂轮速度依次选择15,20,25m/s,磨削深度分别选择50,100,150μm,工件速度分别选择5,10,15m/min.研究结果表明:表面粗糙度对工件速度的变化最敏感,表面显微硬度对砂轮速度变化最敏感,表面残余应力对砂轮速度变化最敏感;同时表明了磨削参数对磨削表面形貌、显微硬度梯度、微观组织、残余应力梯度的影响,揭示了表面完整性中的变质层形成规律.其塑性变形层在5～10μm,显微硬度变化影响层为80～100μm,残余应力影响层厚度为80～200μm,其为磨削镍基高温合金表面完整性控制研究提供相关的实验数据基础.      

原位自生TiB_2/Al复合材料磨削表面质量研究

原位自生TiB_2/Al复合材料具有密度小,比强度高,比模量大等特点,在航空航天领域具有广泛的应用前景。为探索原位自生TiB_2/Al复合材料的磨削加工性能,选用单晶刚玉SA砂轮、白刚玉WA砂轮和CBN砂轮在不同磨削参数下对TiB_2/Al复合材料进行磨削试验。首先研究了砂轮材质、转速、工件速度、磨削深度对工件表面粗糙度的影响规律;其次通过对工件表面形貌、磨屑形态、砂轮磨损的观测分析,探索了原位自生TiB_2/Al复合材料磨削表面成形机制;最后基于试验数据,给出了TiB_2/Al复合材料磨削工艺参数优选域。本研究可为颗粒增强金属基复合材料磨削加工提供基础理论支撑。     

非圆等距型面轮廓X-C轴联动高速磨削试验北大核心CSCD

针对非圆等距型面轮廓磨削加工存在表面质量差的问题,建立基于恒磨除率X-C轴联动磨削理论模型。选用陶瓷CBN砂轮进行三弧段非圆等距型面轮廓的高速磨削正交试验,探究砂轮线速度、工件速度和磨削深度对磨削比能、切向磨削力、磨削温度、表面粗糙度的影响规律。分析表明,砂轮线速度对切向磨削力、表面形貌的影响最大,磨削深度对磨削比能、磨削温度、表面粗糙度的影响最大。进行表面形貌观测未探测到明显的磨削烧伤区域,证明恒磨除率X-C轴联动磨削方式可用于非圆等距型面轮廓磨削加工。     

超声振动磨削C/SiC复合材料的试验研究

采用电镀金刚石砂轮对CVI+PIP综合工艺制备的2.5D正交编织C/SiC陶瓷基复合材料进行了轴向超声振动平面磨削加工试验.通过对超声振动磨削与普通磨削的磨削力、磨削表面三维形貌及粗糙度的分析与测量,对C/SiC复合材料的加工工艺进行了研究.结果表明,磨削过程中材料去除方式以脆性去除为主,碳纤维损伤形式以纤维拉断、剥离...     

激光修锐树脂结合剂砂轮的试验研究

使用脉冲ＹＮＧ激光对树脂结合剂砂轮进行了修锐试验研究,并采用激光三维扫描方法对修锐前后砂轮的表面形貌进行测量．通过考察砂轮磨粒突出高度及有效磨粒数等表面形貌特征,比较了在不同的激光修锐参数下所获得的不同的修锐效果．试验结果表明激光修锐树脂结合剂砂轮是可行的,并指出了进行激光修锐工艺参数优化研究的重要性．     

激光功率谱在砂轮检测中的应用

首先从理论上分析了砂轮工作面形貌的夫琅浩费衍射图像，然后通过试验分析了其实际功率谱型。试验结果表明，激光功率谱法能检测砂轮工作面形貌的特征参数及磨耗磨粒切刃的分布图形，定量而直观地评价砂轮的磨削性能，实现砂轮工作面形貌的在线检测与控制。     

TC4-DT钛合金磨削表面特性及其摩擦磨损性能

钛合金是一种典型难磨削加工材料,磨削表面易出现烧伤、裂纹等热损伤。本文开展了TC4-DT钛合金磨削实验,通过扫描电镜（SEM）、能谱（EDS）、X射线衍射（XRD）、显微硬度仪、金相显微镜及球-盘摩擦磨损实验仪研究了其表面特性及摩擦磨损性能。结果表明：低速磨削表面质量好,摩擦磨损性能较基体略提高;当砂轮线速度为80 m/s时,磨削表面质量良好,摩擦系数为0.38,较基体降低40%;而砂轮线速度为100 m/s时,磨削表面出现严重烧伤、网状裂纹。因此选择合理的高速磨削工艺可避免烧伤、裂纹等热损伤缺陷,并可有效改善表面摩擦磨损性能;磨削表面干摩擦磨损机制为磨粒磨损、粘着磨损和剥层磨损。     

Performance evaluation of creep feed grinding of γ-TiAl intermetallics with electroplated diamond wheels

This paper evaluates the performance of creep feed grinding γ-TiAl intermetallic (Ti-45Al-2Mn-2Nb) using electroplated diamond wheels. Firstly, a comparative analysis with the grinding results by using electroplated CBN wheels was conducted, mainly involving abrasive wheel wear behavior and maximum material removal rate below surface burn limit. It was found that the diamond wheel would produce much better grinding results including lower wheel wear rate and higher maximum material removal rate. Then the surface integrity obtained at different level of material removal rate was characterized with the utilization of the diamond wheel. The poor ductility of this γ-TiAl intermetallic material was found to have a marginal effect on the surface integrity, as no severe surface defects such as material pullout were generated during the stable wheel wear stage. For the involved operating parameters, a deformation layer was produced with ∼10 μm or more in thickness depending on the material removal rate used. Meanwhile, a work-hardened layer extending to more than 100 μm was produced with a maximum microhardness of above 520 HV_0.05 (bulk value 360 HV_0.05). The residual stress remained compressive, with a value of above −100 MPa and even up to −500 MPa for an elevated material removal rate. Shearing chip was the main chip type, indicating good wheel sharpness in the grinding process.     

高纯钨磨削加工试验研究

为探究适用于高纯钨磨削加工的砂轮,使用80~#绿碳化硅砂轮和金刚石砂轮开展磨削对比试验,从工件表面粗糙度角度评价上述两种砂料对高纯钨磨削加工表面的影响。试验结果表明,绿碳化硅砂轮对应的工件得到了更理想的表面粗糙度。使用绿碳化硅砂轮开展工艺试验,分析在不同磨削参数下加工表面粗糙度的变化趋势,以此为依据对高纯钨磨削加工工艺参数进行评价与优化。综合考虑加工表面粗糙度以及加工效率,得出适合于钨磨削加工的参数为砂轮线速度v_s=23m/s、磨削深度a_p=8μm、工作台进给速度v_w=10m/min,该参数下得到的表面粗糙度均值为0.336μm。     

磁流变弹性体砂轮抛光镍基高温合金表面完整性研究

为了改善磨削后镍基高温合金GH4169的表面完整性,本文采用磁流变弹性体砂轮对镍基高温合金GH4169进行抛光试验研究。首先,通过模压成型的方法制备了磁流变弹性体砂轮,并对其表面微观形貌及不同磁场强度下的硬度进行了表征。其次将制备出的磁流变弹性体砂轮用于对镍基高温合金GH4169的抛光工艺试验中,并讨论抛光工艺参数中磁场强度对镍基高温合金表面完整性的影响。试验结果表明：在一定的磁场强度范围内,零件抛光后的表面粗糙度和显微硬度随着磁场强度的增大而减小,同时增大磁场强度也有利于改善零件的表面形貌,减少砂轮的磨损量,降低零件磨削后的亚表面损伤层厚度。     

Research on Ultrasonic Vibration Grinding of the Hard and Brittle Materials

It is well known that grinding techniques are main methods to machine hard and brittle materials such as engineering ceramics. But the conventional grinding has many shortcomings such as poorer surface finish,quicker wear and tear of grinding tools,lower effi-ciency and so on. Ultrasonic vibration grinding (UVG) which combines ultrasonic machining and grinding emerged as a developing and promising technique in recent years. In this paper,experimental studies on UVG were conducted on several kinds of hard and brittle material by altering processing parameters such as vibration frequency and its amplitude,diamond abrasive grit size,cutting depth,feeding speed and rotary speed of tools. The experimental results show that alteration in any of above mentioned parameters will bring effects on the processed surface finish of these materials. Of them,the diamond abrasive grit size has the greatest. Moreover,conven-tional grinding experiments were also carried out on these materials. By comparison,it was found that the UVG is superior to the con-ventional method in terms of the ground surface quality,the working efficiency and the wear rate of tools.     

硅微晶玻璃超精密磨削技术的研究

介绍了应用铸铁结合剂金刚石微粉砂轮和在线电解修整（ＥｌｅｃｔｒｏｌｙｔｉｃＩｎ－ｐｒｏｃｅｓＤｒｅｓｉｎｇ,简称ＥＬＩＤ）磨削技术对硅微晶玻璃材料零件进行的超精密磨削实验。通过改变磨削参数并用力和声发射信号对磨削过程进行在线检测,对硅微晶玻璃材料的磨削进行了分析研究。实验结果表明用ＥＬＩＤ磨削方法磨削硅微晶玻璃可以达到良好的镜面磨削效果     

Development of a new high-shear and low-pressure grinding wheel and its grinding characteristics for Inconel718 alloy

Nickel-based alloy has been widely used due to its outstanding mechanical properties. However, Nickel-based alloy is a typical difficult-to-machine material, which is a great constrain for its application in the manufacturing field. To improve the surface quality of the ground workpiece, a new high-shear and low-pressure grinding wheel, with high ratio of tangential grinding force to normal grinding force, was fabricated for the grinding of selective laser melting (SLM) manufactured Inconel718 alloy. The principle of high-shear and low-pressure grinding process was introduced in detail, which was quite different from the conventional grinding process. The fabrication process of the new grinding wheel was illustrated. A serial of experiments with different processing parameters were carried out to investigate the grinding performance of the developed grinding wheel via analyzing surface roughness and surface morphology of the ground workpiece. The optimal processing parameters of high-shear and low-pressure grinding were obtained. The surface roughness of ground workpiece was reduced to 0.232 μm from the initial value of 0.490 μm under the optimal grinding conditions. It was found that the initial scratches on the ground workpiece were almost completely removed after the observations with the metalloscopy and the field-emission scanning electron microscopy (FE-SEM). The capability of the newly developed high-shear and low-pressure grinding wheel was validated.     

氩气保护条件下钎焊单层金刚石砂轮的研究

 利用氩气作为保护气体,以 Ni-Cr合金粉末做钎料,适当控制钎焊温度、保温时间和冷却速度,实现了金刚石与钢基体的牢固的化学冶金结合。利用扫描电镜和 X射线能谱,结合 X射线衍射结构分析,发现在钎焊过程中 Ni-Cr合金中的 Cr元素分离在金刚石界面形成富 Cr层并与金刚石表面的 C元素反应生成Cr₃C₂ 和 Cr₇C₃,在钢基体结合界面上 Ni-Cr合金和钢基体中的元素相互扩散形成冶金结合,这是实现合金层与金刚石及钢基体之间都有较高结合强度的主要因素。并通过重负荷磨削实验进行验证取得较好的结果。     

多光谱CVD硫化锌材料的磨削去除机理

为了探究红外光学材料多光谱CVD硫化锌的磨削加工去除机理,对抛光后的多光谱CVD硫化锌材料进行显微压痕和金刚石单颗粒刻划实验研究,并采用金刚石砂轮对材料进行磨削加工。实验研究表明,多光谱CVD硫化锌材料在机械去除过程中出现了弹性和塑性变形现象,萌生的裂纹和破碎主要沿晶界、刻划方向、磨削纹理方向扩展,小的压力可抑制裂纹的萌生和扩展,采用尖头金刚石颗粒可获得破碎和裂纹更少的表面,采用垂直磨削法,磨削后形成了自中心至外缘呈周期性、散射状的磨削纹理。本研究可为多光谱CVD硫化锌红外透镜的精密、超精密加工提供技术依据。