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Relevant bibliographies by topics / Face grinding wheel

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Journal articles

Academic literature on the topic 'Face grinding wheel'

Author: Grafiati

Published: 30 May 2022

Last updated: 31 May 2022

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Journal articles on the topic "Face grinding wheel"

1

Mindek, R. B., and T. D. Howes. "Slot and Vertical Face Grinding of Aerospace Components." Journal of Engineering for Gas Turbines and Power 118, no. 3 (1996): 620–25. http://dx.doi.org/10.1115/1.2816693.

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Workpiece profile accuracy, wheel wear, and thermal damage were investigated for the grinding of slots and vertical faces on MAR-M-247, Inconel 713C, and M-2 tool steel using both alumina and cubic boron nitride (CBN) grinding wheels. It was found when grinding with alumina wheels that the wheel corner and first 2.5 mm of the grinding wheel sidewall account for all the grinding forces in the vertical, horizontal, and transverse directions, and therefore is responsible for all the significant grinding done on the sideface of the workpiece. Since previous work links wheel wear and workpiece thermal damage during grinding to grinding forces, this finding suggests that the area around the wheel corner is the critical region of importance in grinding these types of profiles in terms of wheel wear and the heat input to the workpiece. These, in turn, are linked to workpiece profile accuracy and metallurgical damage. Results also show that striation marks inherent in sidewall grinding can be minimized by controlling the maximum normal infeed rate of the wheel. A method for minimizing the heat input into the workpiece by minimizing grinding force during vertical face grinding is also reported.

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2

Peterka, Jozef, Jakub Hrbál, Ivan Buranský, and Jozef Martinovič. "Experimental Investigation of Wearing Grinding Wheels After Machining Sintered Carbide." Research Papers Faculty of Materials Science and Technology Slovak University of Technology 28, no. 47 (2020): 11–20. http://dx.doi.org/10.2478/rput-2020-0014.

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Abstract Solid cutting tools are widely applied in the machining of shape parts and mainly fabricated using the grinding operations. Solid cutting tools are of specific geometry and shape. The tool geometry is created by mutual movement grinding wheels and stock. In the grinding of its manufacturing, grinding wheels are worn out gradually with the grinding number increasing. The wearing grinding wheel has a significant influence on the accuracy geometry of the tool produced. The paper focuses on the wear of the grinding wheels based on diamonds, and the grinding wheels based on cubic boron nitride. The wear rate of the grinding wheels is affected by the properties of a grinding wheel, grinding conditions, and type of cutting material. A measure of the ability of a grinding wheel to remove material is given by the Grinding ratio. The grinding ratio (G ratio) is defined as the volume of material removed (Vw) divided by the volume of wheel wear (Vs). Periphery grinding wheels were used in the experiments. Cylindrical face grinding was used for the machining of sintered carbide stock with a diameter of 20 mm. The results of the experiment show that the diamond-based grinding wheels are more suitable for grinding sintered carbide.

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3

Yang, Zhi Bo, L. M. Zhang, Jiu Hua Xu, and G. L. Zhao. "Performance of Laser Brazing Diamond Grinding Wheel in Face Grinding." Key Engineering Materials 487 (July 2011): 145–48. http://dx.doi.org/10.4028/www.scientific.net/kem.487.145.

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A new technology kind of brazed monolayer cup diamond grinding wheel was developed via laser in an argon atmosphere. Grinding performances of this kind of brazed wheel in the surface grinding of the granites were studied. The experiment results show that the normal grinding forces and wear of diamond grits become higher with the increasing of the accumulated removal volume during grinding granites process. When continuous dry grinding was employed, the grits of the brazed diamond grinding wheel fail mainly in attired wear mode other than pull-out ones in conventional electroplated and sintered diamond tools, which indicates that the strong retention of brazing alloy to the diamond grits and longer service life of this kind of wheel.

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4

Li, Xing Shan, Mei Li Shao, Jun Wang, and Yu Shan Lu. "Simulation of the Surface Roughness by End Face Grinding Wheel with Ordered Abrasive Pattern." Advanced Materials Research 1095 (March 2015): 898–901. http://dx.doi.org/10.4028/www.scientific.net/amr.1095.898.

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In order to improve the grinding performance of end face grinding wheel, the ordered theory is applied to the design of grinding wheel. Based on the track equation of the end grinding, the effects of grinding parameters on the surface roughness are studied and compared with the workpiece appearance by grinding wheel with different abrasive patterns. The simulation results show that the surface roughness values are lower by the grinding wheel with phyllotactic pattern than other patterns. It will provide theoretical basis for designing abrasive ordered pattern of grinding wheel.

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5

Fujiwara, T., Shinya Tsukamoto, Kazuhito Ohashi, and Takashi Onishi. "Study on Grinding Force Distribution on Cup Type Electroplated Diamond Wheel in Face Grinding of Cemented Carbide." Advanced Materials Research 1017 (September 2014): 9–14. http://dx.doi.org/10.4028/www.scientific.net/amr.1017.9.

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In order to establish a high performance grinding method of cemented carbide, the grinding force distribution on the working surface of the cup type electroplated diamond grinding wheel is experimentally analyzed with the grinding force variation of face grinding, which is carried out on the narrow workpiece. The grinding force distribution is obtained by the successive difference of the grinding force variation. The grinding state becomes steady as soon as beginning of the interference of grinding wheel in workpiece, because the edge profile of workpiece is formed as same as the envelope of the grinding wheel. Main conclusions obtained in this study are as follows. In the region of the front edge of the grinding wheel, relatively large grinding force occurs, then in the region of the rear edge of the grinding wheel, the grinding force becomes smaller. In the left right-side end of the wheel, the grinding forces are larger than the center of the wheel. It is made clear that the grinding force distribution shows the peak value near the outer part of the wheel, and the peak value is larger in the center part of the wheel, on the contrary, the peak width become broad in both the left and right-side end of the wheel.

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6

Milsimerová, Aneta. "The Solution Design of Hobbing Worm Milling Cutters Face Teeth Undercut." Materials Science Forum 919 (April 2018): 59–67. http://dx.doi.org/10.4028/www.scientific.net/msf.919.59.

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Face teeth grinding of special tools, as hobing worm milling cutters are, is the shape and cinematically complex operation with the respect to achieving the necessary accuracy and resultant shape geometry. The grinding wheel shape, it ́s size and the control helix angle of hobing worm are the primary factors which are compelling the ground groove accuracy during the face teeth sharpening process. Inappropriately selected combination of these parameters causes undercut of this surface and the negative impact on required accuracy. The main aim of the solution is to find a variable and to create a parametric mathematical model to calculate appropriate grinding wheel shape according to the input factors – hobing worm and grinding wheel parameters which affects this issue. This system will be used to create the initial grinding wheel surface and a helix groove undercut calculation program. The graphical part of this programme will be the next benefit.

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7

Huo, F. W., D. M. Guo, Z. J. Jin, R. K. Kang, and Z. Y. Zhang. "Ultra-precision grinding of a hydrostatic mechanical sealing ring face with extremely shallow taper angle." Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 225, no. 4 (2011): 463–72. http://dx.doi.org/10.1243/09544054jem2155.

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This paper investigates the potential application of infeed grinding using a rotary table and cup grinding wheel to process a sealing ring with extremely shallow tapered faces. A mathematical model for the shape of the face of the ring is developed. The shape characteristics and the influence of machine parameters, such as the distance between the centres of the rotary table and the grinding wheel, the wheel's radius, the pitch angle, and the roll angle on the conical error, are investigated. An optimization model is developed that defines the minimum form error and the optimal machine configuration parameters. It is found that the face of the ring can be approximated as a circular conical surface. It is shown that the minimum theoretical form error is less than a nanometre for rings with an outer diameter of 300 mm. It is predicted that infeed grinding using a rotary table and cup grinding wheel is capable of processing the face of the ring to high form accuracy and this prediction is validated by experimental results.

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8

Li, Xing Shan, Mei Li Shao, Jun Wang, and Yu Shan Lu. "Simulation of Grinding Surface Roughness by End Face Grinding Wheel with Phyllotactic Abrasive Pattern." Applied Mechanics and Materials 670-671 (October 2014): 543–47. http://dx.doi.org/10.4028/www.scientific.net/amm.670-671.543.

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In order to improve the performance of end face grinding wheel, the phyllotaxis theory is introduced into the design of the wheel. Meanwhile the movement track equation of the end grinding is established, and the effects of the phyllotactic coefficient on the grinding surface roughness are studied. The simulation results show that the lower surface roughness values can be obtained when choosing reasonable phyllotactic coefficient. It will provide theoretical basis for the ordered abrasive patterns of the end grinding wheel.

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9

Yang, Xing Hua, Jian Feng Yang, Jian Guang Bai, and Sao Chun Xu. "The Effect of Porosity of CBN Grinding Tools on Grinding Properties." Materials Science Forum 724 (June 2012): 363–66. http://dx.doi.org/10.4028/www.scientific.net/msf.724.363.

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The CBN grinding wheels with different porosity, which used 100/120 CBN grind grain and 15μm glass powder as main starting materials, pore creating material as auxiliary material, were prepared by conventional sintering technology; Used GCr15 bearing steel which quenching hardness was 60HRC as ground materials, investigated the effect of porosity of CBN wheel on its cutting ability. In this paper , the metal removal rate was measured by electronic analytical balance, surface roughness of GCr15 was analyzed used LEXT laser scanning confocal microscope and the surface topography of grinding face was observed used scanning electron microscope. The investigated results showed that the metal removal rate acutely increasing with the porosity of wheels increasing in same loading weight, it reached 0.445g/min with 41% porosity in 3500g loading weight, at the same time, the difference of surface roughness caused by variation of porosity of CBN grinding wheel was slight, it did not severely lower machining precision of workpiece.

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10

Cao, L. X., H. J. Wu, and J. Liu. "Kinematic Analysis of Face Grinding Process at Lapping Machines." Key Engineering Materials 291-292 (August 2005): 145–50. http://dx.doi.org/10.4028/www.scientific.net/kem.291-292.145.

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The precise face grinding and lapping technology with abrasive or abrasive tool has been widely used in the field of the precise manufacture and ultraprecise manufacture. It has become an essential technology in the manufacture of many components. The planetary lapping machine is typical equipment for face grinding or lapping process. And the relative motions between the workpieces and grinding wheel will affect the formation of wear profiles of the tools, furthermore, the work result will be affected directly by the cutting path of this relative motions. In this paper, the kinematic principle of face grinding process on lapping machines has been analyzed. By means of the concept of pitch point and pitch circles, the complicated grinding process has been converted into two kinds of rotations with the fixed center distance. Two kinds of path curves, i.e. workpiece against grinding wheel and grinding wheel against workpiece, and their relations are analyzed. The geometrical analyses and the manufacture quality of the workpiece are linked with the aid of the cutting velocity, the range of the rotational angle of the cutting traces and the rate of the change of the rotational angle with time. The optimal path curve and kinematic parameters are achieved, and these results are corresponding to the experimental results.

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