Relevant bibliographies by topics / Precision Grinding

Academic literature on the topic 'Precision Grinding'

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Published: 4 June 2021
Last updated: 20 February 2023

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Journal articles on the topic "Precision Grinding"

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Ke, Xiao Long, Yin Biao Guo, and Chun Jin Wang. "Compensation and Experiment Research of Machining Error for Optical Aspheric Precision Grinding." Advanced Materials Research 797 (September 2013): 103–7. http://dx.doi.org/10.4028/www.scientific.net/amr.797.103.

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According to the demand of precision machining for optical aspheric lens, especially large scale optical aspheric lens, this paper presents an error compensation technique for precision grindging. Based on precision surface grinding machine (MGK7160), grating-type parallel grinding method is put forward to realize grinding paths planning for optical aspheric lens. In order to obtain surface metrology and evaluation after grinding, an on-machine measurement system is built. On the basis of compensation principle, machining error is separated to achieve error compensation. Grinding experiments are carried out and show that it can meet the demand of precision grinding, and the accuacy after error compensation attains 6.5μm.
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Brinksmeier, E., Y. Mutlugünes, F. Klocke, J. C. Aurich, P. Shore, and H. Ohmori. "Ultra-precision grinding." CIRP Annals 59, no. 2 (2010): 652–71. http://dx.doi.org/10.1016/j.cirp.2010.05.001.

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Shiha, Albert J., and Nien L. Lee. "Precision cylindrical face grinding." Precision Engineering 23, no. 3 (July 1999): 177–84. http://dx.doi.org/10.1016/s0141-6359(99)00008-2.

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Fathima, K., M. Rahman, A. Senthil Kumar, and H. S. Lim. "Modeling of Ultra-Precision ELID Grinding." Journal of Manufacturing Science and Engineering 129, no. 2 (September 28, 2006): 296–302. http://dx.doi.org/10.1115/1.2515382.

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The electrolytic in-process dressing (ELID) grinding is a new and an efficient process for ultra-precision finishing of hard and brittle materials. Unlike conventional grinding processes, the ELID grinding is a hybrid process that consists of a mechanical and an electrochemical process, and the performance of the ELID grinding process is influenced by the parameters of the above said processes. Therefore, it is necessary to develop a new grinding model for the ELID grinding, which can be used to avoid the cumbersome and expensive experimental trials. In this paper, the authors proposed a new grinding model for ultra-precision ELID grinding. The main focus is to develop a force model for the ultra-precision ELID grinding where the material removal is significantly lower than the conventional grinding. When the material removal rate is very low, it is very important to estimate the real contact area between the wheel and work surfaces. The developed grinding model estimates the real contact area by considering the wheel and the work surface characterization and the effect of the electrolytic reaction at the grinding wheel edge. The effects of the microstructure changes on the wheel surface by the electrochemical reaction have been implemented in the model in order to improve the efficiency of the developed model. The grinding model has been simulated and the simulated results are substantiated by the experimental findings.
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Mabuchi, Yusuke, Fumihiro Itoigawa, Takashi Nakamura, Keiich Kawata, and Tetsuro Suganuma. "High Precision Turning of Hardened Steel by Use of PcBN Insert Sharpened with Short Pulse Laser." Key Engineering Materials 656-657 (July 2015): 277–82. http://dx.doi.org/10.4028/www.scientific.net/kem.656-657.277.

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Precision grinding is one of the important processes for finishing of hardened steel parts. However, the grinding process might be quite costly providing the parts with shape complexity should be finished because a number of production steps are needed. Also, this process has some environmental issues, such as disposal of a large amount of grinding sludge and grinding fluid. Precision cutting would become a better alternative process to reduce cost and environmental burden because process steps can be simplified by use of CNC machine tools with PcBN cutting insert if deterioration of cutting tool edge by wear and chipping can be suppressed for long duration. In this study, to improve performance of a PcBN cutting insert, such as wear resistance and defect resistance by the applying of pulse laser processing to sharpen cutting edge in order to realize substitution of cutting for grinding. Precision cutting experiments for hardened steel are conducted by use of the PcBN insert with sharp and tough edges processed by pulsed laser and, for comparison, by use of the PcBN insert ground with diamond wheel. From the results of cutting experiments, it was found that precision cutting with PcBN insert processed by pulsed laser can provide a steady cutting state for a long cutting duration, and a smooth finished surface comparable to precision grindings.
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KASUGA, Hiroshi, Hitoshi OHMORI, Yutaka WATANABE, and Taketoshi MISHIMA. "C30 Grinding Characteristics of Optical Glass for Surface Roughness Reduction(Nano precision Elid-grinding)." Proceedings of International Conference on Leading Edge Manufacturing in 21st century : LEM21 2009.5 (2009): 725–28. http://dx.doi.org/10.1299/jsmelem.2009.5.725.

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Guan, Jia Liang, Zhi Wei Wang, Li Li Zhu, Zhi De Chen, and Wen Chang Wang. "The Development and Research of the Special ELID Grinding Machine." Advanced Materials Research 816-817 (September 2013): 298–302. http://dx.doi.org/10.4028/www.scientific.net/amr.816-817.298.

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ELID grinding technology applied to difficult-to-machine materials’ precision and ultra-precision processing has obtained good results. Based on the existing experimental results of ELID grinding, according to the structure characteristics of the existing grinding machine, we designed and developed a special ELID grinding machine in order to greatly improve the machining precision and automation degree of the existing grinding machine and achieve precision and ultra-precision processing of difficult-to-machine materials.
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Guan, Jia Liang, Xiao Hui Zhang, Ling Chen, and Xin Qiang Ma. "Research on Cylindrical Precision Machining Adopting ELID Grinding Technology." Advanced Materials Research 1027 (October 2014): 97–100. http://dx.doi.org/10.4028/www.scientific.net/amr.1027.97.

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In order to explore the new way to precision machining of the cylindrical, ELID precision mirror grinding technology are employed to precision ultra-precision grinding experiments. Given ELID precision mirror grinding technology has effectively solved the basis of many of the typical flat-precision machining difficult materials and efficient processing, through the conversion process equipment tools, and optimization of process parameters, obtained when the wheel speed in 16 ~ 20 m / s, when the grinding depth 10μm, cylindrical grinding state is best, which could obtain Ra0.025μm surface roughness of the machined surface.
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Brinksmeier, Ekkard, Yildirim Mutlugünes, Grigory Antsupov, and Kai Rickens. "New Tool Concepts for Ultra-Precision Grinding." Key Engineering Materials 516 (June 2012): 287–92. http://dx.doi.org/10.4028/www.scientific.net/kem.516.287.

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This paper presents advanced tools for ultra precision grinding which offer a high wear resistance and can be used to generate high-quality parts with an ultraprecise surface finish. The first approach features defined dressed, coarse-grained, single layered, metal bonded diamond grinding wheels. These grinding wheels are called Engineered Grinding Wheels and have been dressed by an adapted conditioning process which leads to uniform abrasive grain protrusion heights and flattened grains. This paper shows the results from grinding optical glasses with such Engineered Grinding Wheels regarding the specific forces and the surface roughness. The results show that the cutting mechanism turns into ductile removal and optical surfaces are achievable. On the other hand, the specific normal force F´n increases due to increased contact area of the flattened diamond grains. It is shown that the topography of the Engineered Grinding Wheels has a strong beneficial influence on surface roughness. The second new tool for ultra precision grinding is made of a CVD (Chemical Vapour Deposition) poly-crystalline diamond layer with sharp edges of micrometre-sized diamond crystallites as a special type of abrasive. The sharp edges of the crystallites act as cutting edges which can be used for grinding. It is shown that by using CVD-diamond-coated grinding wheels a high material removal rate and a high surface finish with surface roughness in the nanometre range can be achieved. The CVD-diamond layers exhibit higher wear resistance compared to conventional metal and resin bonded diamond wheels. In conclusion, this paper shows that not only conventional fine grained, multi-layered resinoid diamond grinding wheels but also coarse-grained and binderless CVD-coated diamond grinding wheels can be applied to machine brittle and hard materials by ultra precision grinding.
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OZAWA, Norimitsu, Akinori YUI, and Kimiyuki MITSUI. "Precision balancing of grinding wheels." Journal of the Japan Society for Precision Engineering 53, no. 4 (1987): 652–57. http://dx.doi.org/10.2493/jjspe.53.652.

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Dissertations / Theses on the topic "Precision Grinding"

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Ebbrell, Stephen. "Process requirements for precision grinding." Thesis, Liverpool John Moores University, 2003. http://researchonline.ljmu.ac.uk/5633/.

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Hekman, Keith Alan. "Precision control in compliant grinding via depth-of-cut manipulation." Diss., Georgia Institute of Technology, 1997. http://hdl.handle.net/1853/16627.

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Onwuka, Goodness Raluchukwu. "Ultra-high precision grinding of BK7 glass." Thesis, Nelson Mandela Metropolitan University, 2016. http://hdl.handle.net/10948/5203.

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With the increase in the application of ultra-precision manufactured parts and the absence of much participation of researchers in ultra-high precision grinding of optical glasses which has a high rate of demand in the industries, it becomes imperative to garner a full understanding of the production of these precision optics using the above-listed technology. Single point inclined axes grinding configuration and Box-Behnken experimental design was developed and applied to the ultra-high precision grinding of BK7 glass. A high sampling acoustic emission monitoring system was implemented to monitor the process. The research tends to monitor the ultra-high precision grinding of BK7 glass using acoustic emission which has proven to be an effective sensing technique to monitor grinding processes. Response surface methodology was adopted to analyze the effect of the interaction between the machining parameters: feed, speed, depth of cut and the generated surface roughness. Furthermore, back propagation Artificial Neural Network was also implemented through careful feature extraction and selection process. The proposed models are aimed at creating a database guide to the ultra-high precision grinding of precision optics.
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Orton, P. A. "Instrumentation and control for precision grinding machines." Thesis, Nottingham Trent University, 1990. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.278450.

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This thesis examines the present methods of centre less bearing grinding, with a view to applying IIDderncontrol nethods in order to reduce the distribution of output size variations and improve the quality of surface finish. Established rrodels of the grinding process shew that various inportant parameters describing the process can be derived, providing that the grinding power can be accurately rronitored. Several alternative control strategies based on paNer rronitoring are considered. The drive systems of a typical grinding machine are rrodelled as they react through the non-linear grinding wheel/work interface. A simplified computer simulation of the process is demonstrated. Suitable rrethods of instrumentation are evaluated including the optical shaft encoder as a source of high resolution data for the estimation of drive shaft dynamics. A method is devised for on line pararreter estimation of the drive system transfer functions. This enables the important grinding power to be estimated fran shaft dynamics and also al loes the rronitoring of the drive system parameters. The cpt.ica l shaft encoder is also assessed as the source of data for vibration detection. A development conputer with real tine multi-tasking operating system software and specialised shaft encoder interfacing has been established as a basis for an expandable control and rronitoring system. A plan for feeackcontrol of the grinding, involving several separate control algorithms cormunicating with an expert system executive controller, is outlined.
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Tonnellier, Xavier. "Precision grinding for rapid manufacturing of large optics." Thesis, Cranfield University, 2009. http://dspace.lib.cranfield.ac.uk/handle/1826/4510.

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Large scale nuclear fusion and astronomy scientific programmes have increased the demand for large freeform mirrors and lenses. Thousands of one metre class, high quality aspherical optical components are required within the next five to ten years. Current manufacturing process chains production time need to be reduced from hundred hours to ten hours. As part of a new process chain for making large optics, an efficient low damage precision grinding process has been proposed. This grinding process aims to shorten the subsequent manufacturing operations. The BoX R grinding machine, built by Cranfield University, provides a rapid and economic solution for grinding large off-axis aspherical and free-form optical components. This thesis reports the development of a precision grinding process for rapid manufacturing of large optics using this grinding mode. Grinding process targets were; form accuracy of 1 m over 1 metre, surface roughness 150 nm (Ra) and subsurface damage below 5 m. Process time target aims to remove 1 mm thickness of material over a metre in ten hours. Grinding experiments were conducted on a 5 axes Edgetek high speed grinding machine and BoX R grinding machine. The surface characteristics obtained on optical materials (ULE, SiC and Zerodur) are investigated. Grinding machine influence on surface roughness, surface profile, subsurface damage, grinding forces and grinding power are discussed. This precision grinding process was validated on large spherical parts, 400 mm ULE and SiC parts and a 1 m Zerodur hexagonal part. A process time of ten hours was achieved using maximum removal rate of 187.5 mm 3 /s on ULE and Zerodur and 112.5 mm 3 /s on SiC. The subsurface damage distribution is shown to be "process" related and "machine dynamics" related. The research proves that a stiffer grinding machine, BoX, induces low subsurface damage depth in glass and glass ceramic.
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Thomas, David Andrew. "An adaptive control system for precision cylindrical grinding." Thesis, University of Liverpool, 1996. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.243279.

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Scagnetti, Paul Albert. "Design of an industrial precision ceramic grinding machine." Thesis, Massachusetts Institute of Technology, 1996. http://hdl.handle.net/1721.1/10918.

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Cai, Rui. "Assessment of vitrified CBN wheels for precision grinding." Thesis, Liverpool John Moores University, 2002. http://researchonline.ljmu.ac.uk/4972/.

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Basic, Saudin. "Magnetic Holding of Synthetic Quartz For Precision Grinding." BYU ScholarsArchive, 2014. https://scholarsarchive.byu.edu/etd/5615.

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The objective of this research work is to investigate the practicality of magnetic workholding of non-magnetic synthetic quartz during high-speed grinding. This research work is sponsored by Quartzdyne and will be used as the starting point to applying single-piece rounding of its quartz. Hypotheses were created that would permit the authors to conclude that magnets are in fact worthwhile workholders for non-magnetic materials. Designs of Experiments were used to reject or fail to reject the null hypotheses. Experiments were carried out using a custom HAAS lathe, modified into a grinding center with an NSK live spindle, and neodymium-iron-boron magnets used to obtain both the holding and shear forces. Lastly, purchased polyolefin foam bumpers were used to increase the shear force, values were obtained with the Starrett force measurement machine. Input variables for the Design of Experiments (DOE) comprised of the holding force, feed-rate, part rotation, and in-feed size of cuts. Sample rotation relative to the magnets was the singular output variable. Experimental results were fitted with the correct distribution and modeled. Once a statistically significant model was attained input settings that minimized quartz sample rotation were determined and used to create an optimized program. Two sets of experiments were needed before the data could be properly fitted with a model. Thirteen out of fifteen samples remained stationary during the optimized program, which was adequate in failing to reject the second null hypothesis; a static sample at 350 RPM will remain static when undergoing high-speed rounding of its outside perimeter. Comparison of cycle times was crucial in reaching this conclusion; in fact, the cycle time of 7 minutes and 58 seconds for the optimized program was substantially less than Quartzdyne's estimated batch flow per piece cycle time of around 15 minutes. Obtaining a model was not possible or needed for the first hypothesis due to all experiments having zero rotation, therefore the authors also failed to reject the first null hypothesis; a static sample sandwiched between two permanent magnets with adequate holding force will remain stationary during rotation (min 250 RPM) Larger in-feed size cuts are possible when the quartz is square in shape –interrupted cuts. As it becomes cylindrical, cuts were reduced to experimental levels. Also, due to the amount of material being removed, the resin bonded wheel required dressing, without it rotation is expected. Variation was noticed while quantifying the shear force; it is attributed to the polyolefin foam bumper with its inconsistent coefficient of friction. A more uniform material, which can provide repeatable shear force values, would lessen the variation. All optimized program samples turned out perfectly round- even the two that had slight rotation.
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Milton, Gareth Edward Mechanical &amp Manufacturing Engineering Faculty of Engineering UNSW. "An automated micro-grinding system for the fabrication of precision micro-scale profiles." Awarded by:University of New South Wales. School of Mechanical and Manufacturing Engineering, 2006. http://handle.unsw.edu.au/1959.4/32285.

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Production of micro-scale components is an important emergent field. One underdeveloped area is the production of micro-scale 3D surfaces, which has important applications in micro-optics and fibre optic sensors. One particular application is the production of micro-lenses. With scales of less than 200 ??m these lenses can improve light coupling efficiencies in micro-optic systems. However, current lens production techniques have limitations in accuracy and versatility. Creating these surfaces through mechanical micro-grinding has the potential to improve the precision and variety of profiles that can be produced, thus improving transmission efficiencies and leading to new applications. This work presents a novel micro-grinding method for the production of microscale asymmetric, symmetric and axisymmetric curved components from brittle materials such as glasses. A specialised micro-grinding machine and machining system has been designed, constructed and successfully tested and is presented here. This system is capable of producing complex profiles directly on the tips of optical fibre workpieces. A five degree of freedom centring system is presented that can align and rotate these workpieces about a precision axis, enabling axisymmetric grinding. A machine vision system, utilising a microscope lens system and sub-pixel localisation techniques, is used to provide feedback for the process, image processing techniques are presented which are shown to have a sensing resolution of 300 nm. Using these systems, workpieces are centred to within 500 nm. Tools are mounted on nanometre precise motion stages and motion and infeed are controlled. Tooling configurations with flat and tangential grinding surfaces are presented along with control and path generation algorithms. The capabilities and shortcomings of each are presented along with methods to predict appropriate feed rates based on experimental data. Both asymmetric and axisymmetric flat and curved micro-profiles have been produced on the tips of optical fibres using this system. These are presented and analysed and show that the system, as described, is capable of producing high quality micro-scale components with submicron dimensional accuracy and nanometric surface quality. The advantages of this technique are compared with other processes and discussed. Further development of the system and technique are also considered.
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Books on the topic "Precision Grinding"

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Frint, Harold. Automated inspection and precision grinding of spiral bevel gears. Cleveland, Ohio: Lewis Research Center, 1987.

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Yunn-Shiuan, Liao, and Cross-Strait Conference on Precision Machining (1st : 2010 : Taipei, Taiwan), eds. Advances in Abrasive Technology XIII: Selected, peer reviewed papers from the 13th International Symposium on Advances in Abrasive Technology (ISAAT2010), the 1st Cross-Strait Conference on Precision Machining, 19-22 September 2010, Taipei, Taiwan. Switzerland: Trans Tech Publications Ltd, 2010.

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T, Westbury Edgar. Grinding, lapping and honing: The application of abrasive processes to finishing surfaces toa high degree of precision, with descriptions of machines from the operator's viewpoint. Hinckley: TEE, 1987.

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Hofmann, Hagen. High Precision Gear Grinding. Amer Gear Manufactures Assn, 1986.

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United States. National Aeronautics and Space Administration. Scientific and Technical Information Office., ed. Automated inspection and precision grinding of spiral bevel gears. [Washington, DC]: National Aeronautics and Space Administration, Scientific and Technical Information Office, 1987.

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To, Sandy Suet. Materials Characterisation and Mechanism of Micro-Cutting in Ultra-Precision Diamond Turning. Springer, 2018.

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Wang, Hao, Sandy Suet To, and Wing Bing Lee. Materials Characterisation and Mechanism of Micro-Cutting in Ultra-Precision Diamond Turning. Springer, 2017.

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Book chapters on the topic "Precision Grinding"

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Hahn, Robert S. "Precision Grinding Cycles." In Handbook of Modern Grinding Technology, 170–90. Boston, MA: Springer US, 1986. http://dx.doi.org/10.1007/978-1-4613-1965-8_7.

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Mahar, Robert L. "Advances in Precision Grinding." In Innovations in Materials Processing, 441–55. Boston, MA: Springer US, 1985. http://dx.doi.org/10.1007/978-1-4613-2411-9_23.

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Peng, Yunfeng, Zhenzhong Wang, and Ping Yang. "Grinding and Dressing Tools for Precision Machines." In Precision Manufacturing, 233–63. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-13-0381-4_24.

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Peng, Yunfeng, Zhenzhong Wang, and Ping Yang. "Grinding and Dressing Tools for Precision Machines." In Precision Manufacturing, 1–31. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-10-5192-0_24-1.

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Zhao, Huiying, and Shuming Yang. "Design of Tools, Grinding Wheels, and Precision Spindles." In Precision Manufacturing, 93–130. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-13-0381-4_3.

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Zhao, Huiying, and Shuming Yang. "Design of Tools, Grinding Wheels, and Precision Spindles." In Precision Manufacturing, 1–38. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-10-5192-0_3-1.

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Fiedler, K. H. "Precision Grinding of Brittle Materials." In Ultraprecision in Manufacturing Engineering, 72–77. Berlin, Heidelberg: Springer Berlin Heidelberg, 1988. http://dx.doi.org/10.1007/978-3-642-83473-8_5.

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Gao, Shang, Yueqin Wu, and Han Huang. "High-Speed Grinding of Advanced Ceramics and Combination Materials." In Precision Manufacturing, 1–39. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-10-5192-0_18-1.

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Wang, H. F., G. L. Wang, and Ze Sheng Lu. "Research of Grinding Concave Paraboloiding Piece by Spherical Grinding Wheel." In Progress of Precision Engineering and Nano Technology, 114–18. Stafa: Trans Tech Publications Ltd., 2007. http://dx.doi.org/10.4028/0-87849-430-8.114.

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Xie, J. "Precision Grinding for Functional Microstructured Surface." In Micro/Nano Technologies, 1–33. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-10-6588-0_9-1.

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Conference papers on the topic "Precision Grinding"

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Cahill, Michael J., Michael J. Bechtold, Edward Fess, Frank L. Wolfs, and Rob Bechtold. "Ultrasonic precision optical grinding technology." In SPIE Optifab, edited by Julie L. Bentley and Sebastian Stoebenau. SPIE, 2015. http://dx.doi.org/10.1117/12.2195977.

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Suzuki, Hirofumi. "Precision grinding of micro-aspherical surface." In Optifab 2003: Technical Digest, edited by Harvey M. Pollicove, Walter C. Czajkowski, Toshihide Dohi, and Hans Lauth. SPIE, 2003. http://dx.doi.org/10.1117/12.2283991.

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Boehler, R. "High-precision grinding of diamond anvils." In High-pressure science and technology—1993. AIP, 1994. http://dx.doi.org/10.1063/1.46396.

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Fess, Edward, Mike Bechtold, Frank Wolfs, and Rob Bechtold. "Developments in precision optical grinding technology." In SPIE Optifab, edited by Julie L. Bentley and Matthias Pfaff. SPIE, 2013. http://dx.doi.org/10.1117/12.2029334.

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Prochaska, Andrzej, Paul T. Baine, S. J. N. Mitchell, and Harold S. Gamble. "Production of silicon diaphragms by precision grinding." In Micromachining and Microfabrication, edited by Jean Michel Karam and John A. Yasaitis. SPIE, 2000. http://dx.doi.org/10.1117/12.396440.

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SUZUKI, H., T. KITAJIMA, S. OKUYAMA, T. HIGUCHI, and N. WAJIMA. "ULTRA-PRECISION GRINDING OF MICRO FRESNEL SHAPE." In Proceedings of the Third International Conference on Abrasive Technology (ABTEC '99). WORLD SCIENTIFIC, 1999. http://dx.doi.org/10.1142/9789812817822_0009.

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Shore, P., P. Morantz, X. Luo, X. Tonnellier, R. Collins, A. Roberts, R. May-Miller, and R. Read. "Big OptiX ultra precision grinding/measuring system." In Optical Systems Design 2005. SPIE, 2005. http://dx.doi.org/10.1117/12.624166.

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Jochmann, Sven, and Holger Wirtz. "Achieving Precision Grinding Quality by Hard Turning." In ASME 1999 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 1999. http://dx.doi.org/10.1115/imece1999-0745.

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Abstract In the past decade, the technology of finish machining hardened steels with geometrically defined cutting edges has been developed. Due to its high potential to increase productivity as well as competitiveness, research and development has focused on enlarging the use of hard turning for components with very high requirements on surface quality (Rz < 1 μm), form and shape tolerances (IT3 - IT5). In this paper, a detailed comparison on achievable workpiece quality for finish grinding with Al2O3- and CBN-wheels and finish hard turning is presented. It will be shown that finish hard turning is today capable of achieving and maintaining workpiece qualities within the same high range like finish grinding processes.
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Mayer, John E., Angie H. Price, Ganesh K. Purushothaman, and Sanjay V. Gopalakrishnan. "Specific Grinding Energy Causing Thermal Damage in Precision Gear Steels." In ASME 1999 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 1999. http://dx.doi.org/10.1115/imece1999-0703.

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Abstract Thermal damage (burn) in carburized and hardened precision gear steels caused by grinding was investigated. Excessive grinding temperatures cause grinding bum and result in excessive scrappage. AISI 9310 and X53 gear steels, used in helicopters and tilt-rotor aircraft, respectively, were prepared and heat-treated by a production partner. Grinding tests were conducted on these steels. Nital etching was used to detect grinding burn. Models were established to predict onset of thermal damage for AISI 9310 and X53 steels based on specific grinding energy determined from grinding force measurements. The models were compared to results published for other steels.
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Pohl, Mario, Uwe Bielke, Rainer Börret, Rolf Rascher, and Olga Kukso. "MSF-error prevention strategies for the grinding process." In Sixth European Seminar on Precision Optics Manufacturing, edited by Christian Schopf and Rolf Rascher. SPIE, 2019. http://dx.doi.org/10.1117/12.2526581.

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Reports on the topic "Precision Grinding"

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Smith, S., H. Paul, and R. O. Scattergood. Precision diamond grinding of ceramics and glass. Office of Scientific and Technical Information (OSTI), December 1988. http://dx.doi.org/10.2172/476640.

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Bibler, J. E. Effects of imbalance and geometric error on precision grinding machines. Office of Scientific and Technical Information (OSTI), June 1997. http://dx.doi.org/10.2172/620596.

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Bandyopadhyay, B. P. Electrolytic In-process Dressing (ELID) for high-efficiency, precision grinding of ceramic parts: An experiment study. Office of Scientific and Technical Information (OSTI), August 1995. http://dx.doi.org/10.2172/95290.

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