单层钎焊金刚石砂轮的机械化学修整

单层钎焊金刚石砂轮的应用因其磨粒等高性不一致而在硬脆材料的精密加工中受到一定限制。本文采用机械化学复合法对80/100单层钎焊金刚石砂轮进行了修整试验研究。在修整实验前后,测量了砂轮工作面圆跳动,跟踪了磨粒的形貌变化,进行了砂轮磨削K9玻璃实验,观察并分析了工件磨削后的粗糙度值的变化。研究结果表明：机械化学复合法对单层钎焊金刚石砂轮的修整是有效的,磨粒的磨损以化学腐蚀为主,砂轮修整后磨粒等高性较好,磨削K9玻璃工件表面粗糙度明显降低。     

钎焊金刚石砂轮修整实验研究

单层钎焊金刚石砂轮的圆度轮廓精度由于受磨料粒径和钎焊结合剂层高度不均匀等因素的影响而使其难以在工程陶瓷等硬脆材料精密磨削中应用.然而单层钎焊金刚石砂轮的修整是直接对金刚石磨粒进行微量的磨损,修整难度大、效率低,因此,探讨快捷且精密的整形方法就成了解决其应用问题的关键技术之一.在本文研究中,分别采用铁基金刚石烧结磨块、钎焊细粒度金刚石板和氧化铝磨块三种整形工具对钎焊金刚石砂轮进行了磨削法整形实验研究,实验结果表明利用氧化铝磨块进行磨削修整效率极低;钎焊金刚石板磨削修整虽然效率高,但是对砂轮表面金刚石磨粒造成大量破碎磨损;铁基金刚石烧结磨块在整形过程中可稳定地以磨平方式磨损砂轮表面金刚石磨粒,经精密整形后的砂轮圆度轮廓精度较高,用其磨削工程陶瓷时工件表面的犁沟和裂纹明显减少.     

金刚石砂轮V形尖端的数控对磨微细修整技术

针对金刚石砂轮V形尖端的微细修整困难的问题,开发出一种对磨成型的V形尖端修整技术。在数控修整中,砂轮作V形的直线插补运动与修整工具对磨,逐渐被修整成V形尖端。本实验中修整工具分别是#600和#180绿碳化硅(GC)油石,砂轮分别为SD 400和SD 600金刚石砂轮。实验结果表明,较细粒度的修整工具不仅可以将砂轮V形尖端修整出更小的圆弧半径,而且也能够将微小磨粒修锐得更锋利,从而使加工的单晶硅微沟槽形状更加整齐。此外,采用修整后的圆弧半径小于20μm的SD 600金刚石砂轮V形尖端可以实现光纤石英微阵列沟槽的微细加工,也可以在SiC陶瓷和WC合金基板上加工出微锥塔阵列空间的功能表面。因此,数控对磨在位修整的工艺可以用于金刚石砂轮V形尖端的微细修整,实现硬脆性基板的微细磨削加工。     

On-machine dry electric discharge truing of diamond wheels for micro-structured surfaces grinding

Precision grinding with diamond wheels gives a promising alternative to achieve high quality micro-structured surfaces on optical molds. However, it is difficult to true these diamond wheels efficiently, because of the remarkable resistance property and the geometrical limitation of small wheel profile. In this paper, an on-machine dry-EDT method to precision shape and prepare diamond wheels with various profiles was proposed for micro-structured surface grinding. Firstly, the fundamental truing errors were analyzed based on the dry-EDT kinematics. And then the capabilities of dry-EDT truing for high abrasive concentration metal bonded diamond wheels were presented. Next, the effects of kinematic parameters variables on trued wheel profile accuracy were investigated. Finally, the micro-structured surfaces on SiC ceramic and tungsten carbide WC were ground by these trued diamond wheels. The experiments results showed that the arc-shaped diamond wheel (diameter of 200 mm) with 4 μm profile error (PV) and 1.0023 mm profile radius, and the V-shaped diamond wheel with 22.5 μm V-tip radius and 120.03° profile angle could be obtained by on-machine dry EDT. The kinematic parameters of dry-EDT have an important influence on truing profile accuracy of diamond wheels, especially for the tip of V-shaped wheel. The subsequent grinding show that the edge radius of V groove array on SiC is less than 2 μm, while the radius of included corner is around 55 μm. The PV error of ground arc groove array on WC is less than 5 μm. The surface roughness of ground micro-structured surface R_a is 142 nm and 97 nm for SiC and WC, respectively.     

陶瓷零件精密成形磨削新工艺研究

本研究开发采用金刚石磨料砂轮精密成形磨削陶瓷材料新工艺,实现采用金刚石磨料砂轮精密(微米级)成形磨削复杂形状陶瓷零件.文章介绍了磨削工艺中采用的提高成形磨削砂轮工作形面精度保持性、金刚石磨料砂轮的高效精密成形修整、砂轮修锐等关键技术.采用的砂轮是1A1 305×20×127×10 MBD 150 B 100,其特别之处是采用了新型树脂结合剂,具有良好的高温强度性能,磨削速度为40 m/s,新的砂轮修正方法将金刚石砂轮修整过程分为修形、修磨和修锐几个阶段.采用切入式成形磨削,磨削余量约1 mm,磨削得到的陶瓷零件形面圆弧精度可达到:0.005 mm,齿距误差:0.0025 mm;此外还进行了磨削陶瓷轴承环试验,磨削后获得的陶瓷零件圆弧精度达0.005 mm,沟道形位精度:0.003 mm,尺寸分散度在微米级.采用本方法可以成形磨削几乎任意形面的陶瓷或其他适合金刚石磨料砂轮加工的材料零件.     

An experimental investigation of dry-electrical discharge assisted truing and dressing of metal bonded diamond wheel

Metal-bonded diamond wheels have superior qualities such as high bond strength, long wheel life, wear-resistant ability and high grinding efficiency. But it is very difficult to true and dress diamond wheel because of its highest hardness. Traditional mechanical truing does not guarantee truing accuracy of diamond wheel because of single diamond dresser wears out very quickly. To reduce wear of diamond dresser and hence guarantee a desired wheel surface, a novel truing and dressing method, namely, dry electrical discharge (dry-ECD) assisted truing and dressing, is proposed and tested to achieve good dressing quality and efficiency. Because the diamond wheel is mounted on the MK9025 optical profile grinder, dielectric liquid is forbidden. The new dry-ECD dressing/truing method basically eliminates the use of dielectric liquid. Therefore, it is free from the serious problem of electrolytic corrosion caused by electrolytic current flowing through water encountered in conventional ECD. The FE analysis of temperature distribution in dry-ECD assisted truing and dressing diamond wheel using ANSYS is performed in this study. Temperature field simulation helps to select optimized parameters under certain conditions. Energy dispersive X-ray (EDAX) analysis was used to measure the composition of diamond wheel before and after dry-ECD assisted truing and dressing. Further, hard alloy grinding experimental results proves that a little variation in material composition of diamond wheel after dry-ECD assisted truing and dressing does not influence grinding result. A series of experiments of dry-ECD assisted truing and dressing of metal bonded diamond wheel are conducted to investigate truing efficiency, truing accuracy, dresser wear, dressed wheel profiles and three-dimensional truing/dressing forces in comparison with those of the conventional single diamond methods. Experimental results show that the new dry-ECD assisted truing and dressing technique offers a number of advantages over the conventional single-tip diamond dressing and truing method. Furthermore, mechanism of the dry-ECD assisted truing and dressing is investigated through the careful analysis of the properties of chips.     

Electrical discharge truing of metal-bonded CBN wheels using single-point electrode

Industrial application of superabrasive metallic-bond form-wheels is currently limited by problems arising when trying to recover geometrical accuracy after precision is lost due to wear. Literature shows this is a current field of research, and different configurations of the electrical discharge dressing process can be found. In this work an original method for form truing of metal bonded cubic boron nitride (CBN) form wheels is presented for the first time in literature. The method uses a single-point metallic electrode, thus eliminating the need for expensive form electrodes. A mathematical model was derived to predict electrode path and velocity. The model includes the effect of electrode wear. Experimental tests were carried out on a test bench, showing over 90% efficiency in the removal of material from the wheel surface. Wheel performance after truing was examined through grinding tests.     

粗磨粒金刚石砂轮精密磨削工程陶瓷的试验研究

为了实现粗磨粒金刚石砂轮延性域磨削加工SiC陶瓷材料,采用碟轮对粒径为297~420μm的粗磨粒金刚石砂轮进行了精密修整。然后,使用经过修整好的粗磨粒金刚石砂轮对SiC陶瓷进行磨削加工。在此基础上,对不同的砂轮线速度、工件进给速度、磨削切深对SiC陶瓷表面粗糙度和表面形貌的影响进行了研究。试验结果表明:经过精密修整的粗磨粒金刚石砂轮是能够实现SiC陶瓷材料的延性域磨削的,表面粗糙度值Ra达到0.151μm;随着砂轮线速度增大、工件进给速度和磨削切深减小,SiC陶瓷表面的脆性断裂减小,塑性去除增加。     

An experimental investigation of rotary diamond truing and dressing of vitreous bond wheels for ceramic grinding

Experiments of rotary diamond truing and dressing of vitreous bond grinding wheels were conducted to investigate the effects of feed, speed ratio, and overlap ratio on cylindrical grinding of zirconia. The applications of ceramic engine components with complex and precise form and the lack of technology for precision truing of diamond grinding wheels have driven the need to study the use of vitreous bond CBN and SiC wheels for form grinding of ceramics. Truing and grinding forces and the roundness and surface finish of ground zirconia parts were measured. By varying truing process parameters, a wide range of surface finish and roundness could be achieved. Experimental results showed that wheels trued at speed ratio below −1.0 could grind parts with fine surface finish and good roundness. The analysis of truing and grinding results showed the trend of increasing grinding force at higher specific truing energy and better surface finish at higher grinding force. The lack of speed control of the direct–drive, variable–speed truing spindle was observed and its effect on the reverse of direction of truing force at positive speed ratios was studied.     

3D graphical evaluation of micron-scale protrusion topography of diamond grinding wheel

A new graphical evaluation of micron-scale wheel protrusion topography is proposed by using 3D coordinate data derived from contact measuring of 180 diamond grinding wheel. The objective is to quantify 3D distribution of grain protrusion height, gain rake angle and grain relief angle on wheel working surface in dressing. First adaptive measuring was conducted on the base of topographical curvature to identify grain cutting edge in 3D space, second grain protrusion mode was established by polar coordinate transfer so as to ascertain datum plane of grain protrusion, then linear approximation graphics was conducted to display wheel protrusion topography, finally distributions of gain rake angle and grain relief angle were investigated with reference to grain protrusion height. Analytical results show that higher outer grains have more and shaper cutting edges, but lower layer grains retain approximately original crystal forms. In wheel protrusion topography, grain protrusion heights, grain rake angles and grain relief angles are dispersedly distributed in the range 0–28 μm, −45.0° to −89.1° and 1.2–73.1°, respectively, which can be increased by dressing. It is concluded that 3D grain protrusion attitudes distributed on wheel working surface can be quantified by 3D graphical evaluation method.     

3D laser investigation on micron-scale grain protrusion topography of truncated diamond grinding wheel for precision grinding performance

A grain tip (GT) truncation is proposed to truncate grain protrusion tips of #270 diamond grinding wheel in plunge grinding of hard and brittle material. In this study, a 3D laser microscopy was employed to measure the wheel working surface and parameterize its 3D grain protrusion topography. The objective is to investigate how micron-scale grain protrusion parameters influence grinding performance such as grinding force and surface roughness. First, the GT truncation was performed after dressing of diamond grinding wheel in grinding experiment of quartz glass; then its 3D grain protrusion topography was constructed by smoothing 3D measured noise, matching measured point cloud, transferring protrusion frame and extracting 3D diamond grains; finally, the grain protrusion parameters such as grain protrusion number, grain protrusion height, grain protrusion volume, grain rake angle, grain clearance angle, etc. were investigated in connection with ground surface and grinding force. It is shown that GT truncation averagely decreases grain protrusion number, grain protrusion height, grain protrusion volume, grain rake angle and grain clearance angle by about 44%, 74%, 75%, 24% and 70% on whole wheel surface, respectively. However, it greatly increases active grain number by about 32 times and active grain volume by about 181 times in actual grinding with the depth of cut in 1 μm, thus leading to a decrease (about 80%) in surface roughness and an increase (about 40 times) in grinding force. It is also found that truncated diamond grain tips are mostly shaped with nanometer-scale tip wedges along grain cutting direction, leading to about 75% very large negative grain rake angles and about 75% large grain clearance angles, thus contributing to ductile-mode grinding. It is confirmed that the active grain number and active grain volume for the actual depth of cut may be regarded as main grain protrusion parameters to evaluate and predict the precision grinding performance of a coarser diamond grinding wheel.     

电镀金刚石砂轮磨削火成岩质水晶的磨削力研究

采取顺磨和逆磨两种磨削方式,采用电镀金刚石砂轮对火成岩质水晶进行了平面磨削实验。通过测量磨削过程中的水平磨削力和垂直磨削力,得出了磨削深度、进给速度对磨削力的影响规律。结果表明,随着磨削深度的增大磨削力增大,随着进给速度的增大磨削力也增大。同时分析并讨论了火成岩质水晶的磨削力比,磨削力比Ft/Fn为0.33～0.36。     

非球面模芯镜面磨削专用杯形砂轮修整技术的研究

针对轴承钢非球面模芯镜面磨削用铸铁结合剂CBN杯形砂轮的修整问题,设计了专用摆动电极和圆弧成形电极修整装置,该装置结构简单,微调精度高;利用电极与CBN砂轮铸铁结合剂之间的电火花放电腐蚀现象,在亚微米机床上,利用高频直流脉冲电源作对砂轮进行电火花整形,整形后的砂轮通过调整放电电压与放电间隙,在电解液作用下进行短时间修锐。通过最终检测结果表明,砂轮的尺寸误差为3．5μm,最大面形轮廓误差约为3μm,修整后砂轮的尺寸误差和形状误差均达到非球面模芯镜面磨削加工要求。     

细纱机锭杆CBN砂轮成形磨削及修整方法研究

本研究采用CBN砂轮代替传统的棕刚玉砂轮,进行了细纱机锭杆表面成形磨削实验研究.锭杆材料选用热轧轴承钢GCr15.磨削在无锡产M11100专用磨床上进行,CBN砂轮为CBN-850磨料、粒度160#、浓度100%、硬度为J-K.砂轮主轴转速提高到2000 r/min,采用英国产泰勒索夫5对加工表面进行测量,结果表明锭杆表面粗糙度由Ra 0.8降低到Ra0.4 μm.精度由IT8提高到IT6.用酸蚀法检测锭杆表面,结果显示完全克服了磨削烧伤现象;采用金相显微镜测定表面变质层达到0.035 mm以下.由于CBN砂轮磨粒耐磨、锋利,使得砂轮修整次数大大减少,生产效率提高20倍以上.文中还阐述了采用计算机数控系统修整砂轮成形面的原理.     

碟轮修整单层钎焊金刚石砂轮的试验研究

单层钎焊金刚石砂轮在制作完成之初由于砂轮基体加工存在误差以及磨粒粒径大小不一等原因造成磨粒等高性不一致,这使其难以在硬脆材料的精密磨削中得到广泛的应用。采用自制的钎焊碟轮对80/100#单层钎焊金刚石砂轮进行了修整试验研究。在修整试验前后跟踪了砂轮磨粒等高性的变化,进行了SiC陶瓷的磨削试验,并观测了工件表面质量的变化情况。试验结果表明:采用此方法能够实现单层钎焊金刚石砂轮的高效精密修整。修整试验结束后砂轮磨粒等高性较好,磨削SiC陶瓷的表面质量得到明显改善,表面粗糙度Ra值达到了0.1μm以下。     

细粒度钎焊金刚石砂轮磨削花岗石的磨削力特征分析

通过测量磨削力,研究细粒度钎焊金刚石砂轮磨削花岗岩过程磨削力随加工参数的变化特征。结果表明:磨削力是随着砂轮线速度的增大而减小,随着工件进给速度的变大而增大,随着磨削深度的增大而增大。回归分析表明,磨削力受磨削深度的影响程度最大。不同加工条件下,法向磨削力与切向磨削力之间存在良好的线性关系,比值约为7.6。磨削过程中,金刚石与花岗石之间的运动符合Coulomb定律描述的滑动摩擦方式。     

电火花修形砂轮对ELID磨削效果影响的实验研究

本文对经电火花精修形、粗修形后形成硬质层和去除修形形成硬化层的金属结合剂超硬磨料砂轮进行对比实验,研究了三种砂轮的ELID电解曲线和电解后的砂轮表面形貌,分析了不同砂轮被电解后对加工工件的表面粗糙度的影响。实验结果表明：电火花修形后砂轮,表面硬质层阻值较大,不宜直接用于ELID精密镜面磨削加工;电火花修形能够提高砂轮表面的强度和硬度,能够提高砂轮的耐磨性;为保证砂轮基体受电火花淬火影响最小,形成硬质层最薄,电火花精修形时需选用较小的占空比。     

钎焊金刚石砂轮磨削石材中金刚石粒度对磨削力的影响研究

本文通过测量不同金刚石粒度的高频感应钎焊金刚石砂轮磨削花岗石过程中的磨削力，对砂轮所受的法向力和切向力进行了研究。对不同粒度条件下磨削深度、进给速度和砂轮线速度对磨削力的影响进行了分析。研究发现磨削力随砂轮线速度的增大而减小，随磨削深度和进给速度的增大而增大，磨削深度对磨削力的影响程度比进给速度大。小粒度金刚石磨削时，磨削三要素对磨削力的影响比大粒度金刚石磨削时大。     

钎焊金刚石砂轮磨削硬质合金温度的试验研究

根据半人工热电偶测温原理制备了磨削测温试样,利用感应钎焊金刚石砂轮和电镀金刚石砂轮进行硬质合金YG6的磨削试验,研究了磨削深度、工件进给速度对工件表面磨削温度的影响。试验结果表明:在相同的磨削参数下感应钎焊金刚石砂轮的磨削温度要远低于电镀金刚石砂轮,且随着磨削深度和工件进给速度的增大磨削温度上升较为平缓,钎焊金刚石砂轮磨粒出露高度高、容屑空间大,磨粒呈有序排布是磨削温度较低的主要原因。     

Study on micro-topographical removals of diamond grain and metal bond in dry electro-contact discharge dressing of coarse diamond grinding wheel

A coarse diamond grinding wheel is able to perform smooth surface grinding with high and rigid grain protrusion, but it is very difficult to dress it. Hence, the dry electro-contact discharge (ECD) is proposed to dress #46 diamond grinding wheel for dry grinding of carbide alloy. The objective is to understand micro-topographical removals of diamond grain and metal bond for self-optimizing dressing. First, the pulse power and direct-current (DC) power were employed to perform dry ECD dressing in contrast to mechanical dressing; then the micro-topographies of diamond grains and metal bond were recognized and extracted from measured wheel surface, respectively; finally, the relationship between impulse discharge parameters and micro-topographical removals was investigated with regard to grain cutting parameters, dry grinding temperature and ground surface. It is shown that the dry ECD dressing along with spark discharge removal may enhance the dressing efficiency by about 10 times and dressing ratio by about 34 times against the mechanical dressing along with cutting removal. It averagely increases grain protrusion height by 12% and grain top angle by 23%, leading to a decrease 37% in grinding temperature and a decrease 46% in surface roughness. Compared with the DC-25V power along with arc discharges, the Pulse-25V power removes the metal bond at 0.241 mm³/min by utilizing discharge energy by 73% and diamond grain at 0.013 mm³/min through surface graphitization, respectively, leading to high and uniform grain protrusion. It is confirmed that the impulse discharge parameters are likely to control the microscopic grain protrusion topography for efficient dressing according to their relations to the micro-removal of metal bond.