Mathematical model for abrasive content estimation in a pulse-electroplated abrasive microtool

A mathematical model was developed to estimate the weight percent of diamond abrasive particles incorporated in nickel binder matrix during abrasive microtool fabrication by pulse-plating process. The proposed model is based on the hypothesis that, embedment of an inert micro abrasive diamond particle on the substrate will only occur when a few nickel ions from the adsorbed ionic cloud are chemically reduced at the cathode by hydrogen ions present in the diffusion layer. Experimental verification of the model developed was performed by pulse electroplating of diamond abrasive particles on tungsten micro tool shank using an in-house built experimental setup. The predictive model developed was found to estimate diamond abrasive content in nickel binder matrix within 1–7 wt% of experimental results for different pulse-plating conditions.     

High speed ball nose end milling of hardened AISI A2 tool steel with PCBN and coated carbide tools

High speed machining (HSM) of tool steels in their hardened state is emerging as an attractive approach for the mold and die industry due to its potential for significant cost savings and productivity improvement. An experimental study was conducted to investigate the tool wear mechanism and surface integrity in high speed ball nose end milling of hardened AISI A2 tool steel using coated tungsten carbide and polycrystalline cubic boron nitride (PCBN) tools. It is found that coated carbide tools can only be used at low speed (120 m/min) while high content PCBN tools are suitable for HSM range (470 m/min). PCBN tools produce a damage free workpiece with better surface finish and less work hardening. Despite the higher tool cost, HSM with PCBN tools lead to reduction in both total cost and production time per part.     

The effect of spindle speed,feed-rate and machining time to the surface roughness and burr formation of Aluminum Alloy 1100 in micro-milling operation

This paper describes the characteristics and the cutting parameters performance of spindle speeds (n, rpm) and feed-rates (f, mm/s) during three interval ranges of machining times (t, minutes) with respect to the surface roughness and burr formation, by using a miniaturized micro-milling machine. Flat end-mill tools that have two-flutes, made of solid carbide with Mega-T coated, with 0.2 mm in diameter were used to cut Aluminum Alloy AA1100. The causal relationship among spindle speeds, feed-rates, and machining times toward the surface roughness was analyzed using a statistical method ANOVA. It is found that the feed-rate (f) and machining time (t) contribute significantly to the surface roughness. Lower feed-rate would produce better surface roughness. However, when machining time is transformed into total cut length, it is known that a higher feed-rate, that consequently giving more productive machining since produce more cut length, would not degrade surface quality and tool life significantly. Burr occurrence on machined work pieces was analyzed using SEM. The average sizes of top burr for each cutting parameter selection were analyzed to find the relation between the cutting parameters and burr formation. In this research, bottom burr was found. It is formed in a longer machining time compare the formation of top burr, entrance burr and exit burr. Burr formation is significantly affected by the tool condition, which is degrading during the machining process. This knowledge of appropriate cutting parameter selection and actual tool condition would be an important consideration when planning a micro-milling process to produce a product with minimum burr.     

Micro end mill tool temperature measurement and prediction

The objective of this work is to characterize the heat transfer in micro end mill tools during machining operations. This analysis will aid in the design of heat dissipation strategies that could potentially increase tool life and machining precision. Tool temperatures, above the unmachined workpiece surface, have been measured using an infrared camera during slot milling of aluminum (6061-T6) and steel (1018) with 300 μm-diameter two-flute tungsten carbide end mills. The measured temperatures compare favorably with temperature distributions predicted by a two-dimensional, transient, heat transfer model of the tool. The heat input is estimated by applying Loewen and Shaw’s heat partitioning analysis. Analysis of heat transfer in the tool found that 46 s into a cut conduction through the length of the tool, storage in the tool, and convection from the surface account for 41.5%, 45%, and 13.5% of the heat generated during machining. Thermal expansion and cooling strategies are discussed.     

Surface modification of die steel materials by EDM method using tungsten powder-mixed dielectric

Surface modification by material transfer during electrical discharge machining (EDM) has emerged as a key research area in the last decade. Material may be provided to the machined surface of the workpiece by the eroding tool electrode or by using powder-mixed dielectric. Breakdown of the hydrocarbon dielectric contributes carbon to the plasma channel which may also cause surface modification. The present work has investigated the response of three die steel materials to surface modification by EDM method with tungsten powder mixed in the dielectric medium. Taguchi experimental design technique was used to conduct the experiments on each work material independently. Peak current, pulse on-time and pulse off-time were taken as variable factors and micro-hardness of the machined surface was taken as the response parameter. X-ray diffraction (XRD) and spectrometric analysis show substantial transfer of tungsten and carbon to the workpiece surface and an improvement of more than 100% in micro-hardness for all the three die steels. Presence of tungsten carbide (WC and W₂C) indicates that its formation is taking place in the plasma channel. Machining parameters for the best value of micro-hardness for each work material were found to be the same.     

Novel Composite CBN-TiN Coating: Synthesis and Performance Analysis

Cubic boron nitride (CBN) coating, due to its promising properties, is under development worldwide for machining and other related applications. To synthesize a continuous CBN coating by conventional vapor deposition methods (CVD/PVD), however, poses many challenges, such as metastable CBN phase stabilization, as well as the high levels of intrinsic stress developed during the growth. A novel combinatorial approach, which is under development in an effort to develop a CBN composite coating for cutting tools, is reported in this paper. The approach involves a two-step process consisting of electrostatic spray coating (ESC) of CBN particles, followed by chemical vapor infiltration (CVI) of TiN. The process is optimized to deposit a CBN-TiN composite coating with a thickness in excess of 10 μm on tungsten carbide inserts. Such coated tools have been successfully evaluated and tested for machining applications. For production on a commercial scale, the laboratory systems have been upgraded to industrial size. The outcome of scaling up from an experimental to an industrial-sized unit is reported in this paper. The industrial electrostatic spray coating unit, which can coat a batch of about 50 inserts in a couple of minutes, is currently being field tested.     

High aspect ratio micromachining of glass by electrochemical discharge machining (ECDM)

Micromachining of glass is essential for several microfluidic components, micro-pumps, micro-accelerometers, micro-reactors, micro-fuel cells and several biomedical devices. Unique properties such as high chemical resistance, thermal stability and transparency give glass scope for additional applications. However, poor machinability of glass is a major constraint, especially in high aspect ratio applications of glass in microsystem technology. Micro electrochemical discharge machining (micro ECDM) is an emerging nontraditional fabrication method capable of micromachining ceramic materials like glass. While surface features less than 100 μm have been successfully machined on glass, machining high aspect features is a challenge. Machining accuracy at high depths is severely affected due to overcut and tool wear. In this paper, high aspect ratio microtools fabricated in-house have been used for deep microhole drilling on glass using low electrolyte concentration. An aspect ratio of 11 has been achieved. The results show that lower electrolyte concentration reduced overcut by 22%, thus increasing the aspect ratio of the micro holes. Lowering the electrolyte concentration also reduced the tool wear and hole taper by 39% and 18% respectively.     

Performance-Based Predictive Models and Optimization Methods for Turning Operations and Applications: Part 3—Optimum Cutting Conditions and Selection of Cutting Tools

This paper presents a summary of recent developments in developing performance-based machining optimization methodologies for turning operations. Four major machining performance measures (cutting force, tool wear/tool life, chip form/chip breakability, and surface roughness) are considered in the present work, which involves the development and integration of hybrid models for single and multi-pass turning operations with and without the effects of progressive tool wear. Nonlinear programming techniques were used for single-pass operations, while a genetic algorithms approach was adopted for multi-pass operations. This methodology offers the selection of optimum cutting conditions and cutting tools for turning with complex grooved tools.     

Tool wear of coated drills in drilling CFRP

This study aimed to investigate the wear of certain coated drills when drilling carbon fiber reinforced composites (CFRP). Three different drills were used in the drilling experiments: uncoated, diamond coated and AlTiN coated carbide (WC–Co) drills. The tool wear in CFRP machining was quite different from that in conventional metal machining. The primary wear type was a dulling or blunting of the cutting edge, which has been referred to as edge rounding wear or edge recession. In this paper, a hypothesis has been developed to explain the edge rounding wear in CFRP machining. Due to the fracture-based chip formation of CFRP, there is lack of the work material stagnation zone in front of the cutting edge, which normally prevents the edge wear in metal machining. Series of wear lead to rapid dulling of the cutting edge. The resistance to edge rounding wear on the coated as well as uncoated drills has been investigated. The diamond coating significantly reduces the edge rounding wear. However, AlTiN coated drills showed no visible improvement over the uncoated carbide drill, despite of their high hardness, thus not protecting the drill. The wear mechanisms of the uncoated carbide drill and coatings are discussed. It is believed that the 2-body and 3-body abrasive wear fail to explain the observed tool wear in CFRP drilling. However, the wear of the coatings and uncoated carbide substrate from tribo-meter tests correlated well with the tool wear in the CFRP drilling. Therefore, the tribo-meter test can be used to screen the prospective tool materials before carrying drilling experiment.     

Laser tempering based turning process for efficient machining of hardened AISI 52100 steel

Cost-effective machining of hardened steel components such as a large wind turbine bearing has traditionally posed a significant challenge. This paper presents an approach to machine hardened steel parts efficiently at higher material removal rates and lower tooling cost. The approach involves a two-step process consisting of laser tempering of the hardened workpiece surface followed by conventional machining at higher material removal rates with lower cost ceramic tools to efficiently remove the tempered material. The laser scanning parameters that yield the highest depth of tempered layer are obtained from a kinetic phase change model. Machining experiments are performed to demonstrate the possibility of higher material removal rates and improved tool wear behavior compared to the conventional hard turning process. Tool wear performance, cutting forces, and surface finish of Cubic Boron Nitride (CBN) tools as well as low cost ceramic tools are compared in machining of hardened AISI 52100 steel (~63 HRC). In addition, cutting forces and surface finish are compared for the laser tempering based turning and conventional hard turning processes. Experimental results show the potential benefits of the laser tempering based turning process over the conventional hard turning process.     

Measurement of tool internal temperatures in the tool–chip contact region by embedded micro thin film thermocouples

Sensors capable of providing fast and reliable feedback signals for monitoring and control of existing and emerging machining processes are an important research topic, that has quickly gained academic and industrial interest in recent years. Generally, high-precision machining processes are very sensitive to variation in local machining conditions at the tool–workpiece interface and lack a thorough understanding of fundamental thermomechanical phenomena. Existing sensors to monitor the machining conditions are not suitable for robust in-process control as they are either destructively embedded and/or do not possess the necessary spatial and temporal resolution to monitor local tool internal temperatures during machining at the cutting tip/edge effectively. This paper presents a novel approach for assessing transient tool internal temperature fields in the close vicinity of less than 300 μm of the tool cutting edge. A revised array layout of 10 micro thin film micro thermocouples, fabricated using adapted semiconductor microfabrication methods, has been embedded into polycrystalline cubic boron nitride (PCBN) cutting inserts by means of a modified diffusion bonding technique. Scanning electron microscopy was used to examine material interactions at the bonding interface and to determine optimal bonding parameters. Sensor performance was statically and dynamically characterized. They show good linearity, sensitivity and very fast response time. Initial machining tests on aluminum alloys are described herein. The tests have been performed to demonstrate the functionality and reliability of tool embedded thin film sensors, and are part of a feasibility study with the ultimate goal of applying the instrumented insert in hard machining operations. The microsensor array was used for the acquisition of tool internal temperature profiles very close to the cutting tip. The influence of varying cutting parameters on transient tool internal temperature profiles was measured and discussed. With further study, the described instrumented cutting inserts could provide more valuable insight into the process physics and could improve various aspects of machining processes, e.g. reliability, tool life, and workpiece quality.     

Study on machinability of a stellite alloy with uncoated and coated carbide tools in turning

Stellite alloys, which have been widely used in the aerospace, automotive and chemical industries, are hard-to-cut cobalt-based materials. This study investigates the machinability of stellite 12 alloys with uncoated carbide cutting tool grades YG610 (K01-K10) and YT726 (K05-K10/M20) and SANDVIK coated carbide tool SNMG150612-SM1105 under dry cutting conditions. Both wear mechanisms and failure modes of the uncoated and coated tools were investigated with turning experiments. The results show that the coated tool SM1105 remarkably outperforms the uncoated tools; and the cutting tool YG610 generally outperforms YT726 under all cutting conditions. Built-up edge was found with YG610 in some cutting conditions and with SM1105 at cutting speed of 16 m/min. Tool surface burning marks were observed on YT726 at relatively higher cutting speeds. Wear develops slowly with coated tools SM1105 until VB reaches 0.2 mm at most conditions (except at v = 43 m/min, f = 0.25 mm/r). Excessive tool flank typically resulted in tool breakage at the cutting edge for uncoated tools. Abrasive and adhesive wear of cutting tools were observed at low cutting speeds while diffusion and chemical wear occurred at higher cutting speeds.     

Machining efficiency of powder mixed near dry electrical discharge machining based on different material combinations of tool electrode and workpiece electrode

Powder mixed near dry electrical discharge machining (PMND-EDM) is a novel electrical discharge machining (EDM) process. It is proposed to further improve the machining efficiency of dry EDM. The principle of material removal in PMND-EDM is illustrated and its deionization principle is proposed. The influence of residual heat on MRR is analyzed. The concept of superfluous residual heat is proposed. The material removal rate (MRR), the main index of machining efficiency for PMND-EDM process, is researched. Single factor experiments are performed to get effect of peak current, pulse on time, pulse off time, flow rate, tool rotational speed, air pressure and powder concentration on MRR under different material combinations of tool electrode and workpiece electrode. Thermal phenomena in PMND-EDM are illustrated. Effect of each process parameter on MRR of PMND-EDM is gotten and analyzed based on the deionization principle of PMND-EDM. Differences in MRR under different material combinations are found out. Brass tool electrode and W18Cr4V workpiece gain higher MRR under most of discharge conditions, while the superiority of copper tool electrode and 45 carbon steel workpiece in MRR arise when there is improper heat dissipation. The difference is analyzed based on the deionization principle of PMND-EDM.     

Design and fabrication of a laminated thermoforming tool with enhanced features

Thermoforming is a popular manufacturing process for creating useful shapes out of heated thermoplastic sheets using a porous tool under differential pressure. For large, heavy-gauge parts, thermoforming tools are typically made by CNC machining a billet of material or sand casting from an inexpensive master pattern. Although these tooling methods are well established, it is difficult to incorporate enhanced tool functionality such as conformal cooling channels, embedded sensors, unimpeded vacuum channel placement, and customized thermal mass. Profiled Edge Laminas (PEL), a rapid tooling method based on profiling, assembling, and clamping an array of thick layers, is ideally suited for tools used for thermoforming large, heavy-gauge parts and requiring enhanced features. This paper describes how the PEL tooling method can be applied to the design and fabrication of a thermoforming tool and demonstrates the entire process through a case study. Tooling design guidelines and analytical models for predicting conformal channel and vacuum line performance are included. The ease with which multiple-zone conformal cooling/heating channels, vacuum lines, and temperature sensors are incorporated into the tool is also highlighted. Specifically, a 46-layer aluminum PEL tool clamped together with bolts is successfully designed, fabricated, and demonstrated for thermoforming a 0.3×0.4×0.4 m part made from a PVC/Acrylic blend based on the outlined method. The tool incorporates three independent cooling zones sealed by a polymer sealant, three embedded temperature sensors, and an elaborate matrix of vacuum channels. All tool features and the basic geometry were machined into each individual lamina in the same set-up by 2D abrasive waterjet machining, and the final tool surface was CNC-machined. The PEL tooling method is successfully applied to the manufacture of a large, heavy-gauge thermoformed part intended for production.     

Effects of magnetic field and rotary tool on EDM performance

In this work, the effects of tool rotation and various intensities of external magnetic field on electrical discharge machining (EDM) performance have been studied. Experimental trials divided into three regimes of low energy regime, middle energy regime and high energy regime. The influences of process parameters were investigated on main outputs of material removal rate (MRR) and surface roughness (SR). In order to correlate the input parameters and output values two mathematical models were developed to predict the MRR and SR according to variations of discharge energy, magnetic field intensity and tool rotational speed. Results indicated that the applying a rotational magnetic field around the machining gap improves the MRR and SR. Combination of rotational magnetic field and rotary electrode increases the machining performance, in comparison of previous conditions. This is due to better flushing debris from machining gap. This work introduces a new method for improving the machining performance, in cost and time points of view.     

Transitioning to sustainable production – part II: evaluation of sustainable machining technologies

This paper presents a case-study that highlights the importance of sustainable machining technologies in achieving sustainable development objectives. A technology evaluation was undertaken to understand the likely impacts of the use of technology on sustainability performance measures. The evaluation is more than an experimental method for supporting the design of technology and an instrument for supporting decision-making. It is also a tool for supporting technology policy and for encouraging its adoption and application in industry. More specifically, a sustainability evaluation of cryogenic and high pressure jet-assisted machining in comparison to conventional machining is examined. Sustainability performance measures refer to environmental impact, energy consumption, safety, personal health, waste management, and cost. The case-study refers to the machining of high-temperature Ni-alloy (Inconel 718). It is shown that tooling costs represent the major contribution to the overall production cost, which contradicts previous analyses, and that sustainable machining alternatives offer a cost-effective route to improving economic, environmental, and social performance in comparison to conventional machining.     

冷喷涂镍涂层在不锈钢焊点腐蚀防护上的应用研究

目的 研究冷喷涂镍涂层对不锈钢焊点腐蚀行为的影响,为提高不锈钢焊接结构件的耐腐蚀性能提供依据。方法 采用冷喷涂技术在316L不锈钢电阻点焊结构件表面制备纯镍涂层,在金相组织、酸性盐雾腐蚀性能等检测分析基础上,研究不锈钢焊点在有涂层和无涂层条件下的腐蚀行为。结果 采用冷喷涂技术在不锈钢焊点表面制备出了孔隙率不大于0.5%的高致密纯镍涂层,带有涂层的不锈钢点焊结构件经过96 h酸性盐雾试验后,未发生腐蚀。结论 不锈钢表面钝化膜在点焊过程中发生破坏,基体裸露在腐蚀介质中,导致焊点区域发生腐蚀。在表面制备高致密镍涂层后,通过高耐蚀涂层对焊点进行屏蔽防护,有效提高其耐腐蚀性能,满足了某装备不锈钢结构件在酸性盐雾条件下的使用要求。     

Electrochemical machining characteristics and resulting surface quality of the nickel-base single-crystalline material LEK94

Nickel-base single-crystalline materials such as LEK94 possess excellent thermo-mechanical properties at high temperatures combined with low density compared to similar single-crystalline materials used in aero engines. Since the components of aero engines have to fulfil demanding safety standards, the machining of the material used for these components must result in a high geometrical accuracy in addition to a high surface quality. These requirements can be achieved by electrochemical and precise electrochemical machining (ECM/PECM). In order to identify proper machining parameters for PECM the electrochemical characteristics dependent on the microstructure and the chemical homogeneity of LEK94 are investigated in this contribution. The current density was found to be the major machining parameter affecting the surface quality of LEK94. It depends on the size of the machining-gap, the applied voltage and the electrical conductivity of the electrolyte used. Low current densities yield inhomogeneous electrochemical dissolution of different microstructural areas of the material and lead to rough surfaces. High surface qualities can be achieved by employing homogenous electrochemical dissolution, which can be undertaken by high current densities. Furthermore, a special electrode was developed for the improvement of the quality of side-gap machined surfaces.     

Macro-level environmental comparison of near-dry machining and flood machining

This paper focuses on investigating several aspects of the machining process from an ecological perspective, the result being a macro-level analysis. The analysis presented here considers not only the environmental impact of the material removal process itself, but also the impact of the associated processes such as the material preparation, and the scrap processing. A macro-level assessment of the comparative life cycle environmental performance of the near-dry machining (NDM) using TiN-coated carbide tools and the flood machining (FM) is performed by a case study referring to the gear milling. The assessment, using the SimaPro 7.1.5 software and the ecoinvent1.5 database, includes combined Life Cycle Assessment (LCA) of the workpiece material, the scrap processing, the use of lubrication, and the energy consumption.     

Stimulation of human amniotic fluid cell proliferation and colony formation by cell plating on a naturally produced extracellular matrix

Human amniotic fluid cells exhibit a higher cloning efficiency and rate of cell proliferation when maintained on dishes coated with a naturally produced extracellular matrix (ECM) in comparison with the regular tissue culture plastic. In 22 out of 31 amniotic fluid samples there was by plating the cells on ECM a 2–6 fold increase in number and size of colonies and in the cell density per colony as detected by actual staining and viewing of each colony. These effects yielded, in 21 of 41 additional samples, a reduction ranging from 2–8 days, in the culture time elapsing between amniocentesis and the first harvesting of cells for chromosomal analysis. An even greater effect was obtained with primary cells that failed to attach to plastic surfaces and stayed floating in the medium but did attach and proliferate when seeded on ECM. Cells that were left firmly attached to ECM after the first trypsinization and harvesting of cells for chromosomal analysis yielded colonies ready for second karyotyping in less than half the time required for cells maintained on plastic. Studies with secondary cultures of human amniotic fluid cells have demonstrated a 5–10 fold decrease in serum requirement of cells cultured on ECM as compared with plastic. Addition of fibroblast growth factor (FGF) to the cultures further potentiated the effects of ECM. The ECM induced stimulation of cell attachment and proliferation was not associated with any chromosomal anomalies, nor did it interfere with the handling procedure. ECM coated dishes may be useful to reduce the time interval between amniocentesis and diagnosis, in particular when the amniotic cells exhibit an exceedingly slow rate of proliferation on plastic or when large quantities of cells are required for enzymatic studies.