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47 results on '"Moriaki Sakakura"'

1. Improvement of form accuracy in cylindrical traverse grinding with steady rest by controlling traverse speed

Author

Hidetaka FUJII, Takashi ONISHI, Chinhu LIN, Moriaki SAKAKURA, and Kazuhito OHASHI

Subjects
traverse grinding, slender workpiece, steady rest, normal grinding force, beam model, Engineering machinery, tools, and implements, TA213-215, Mechanical engineering and machinery, TJ1-1570
Abstract

In cylindrical traverse grinding, a slender workpiece is bent by the normal grinding force due to its low stiffness. Consequently, a form error is generated by the elastic deformation of the workpiece during the grinding process. To prevent such deformation of the workpiece, a steady rest is generally used. However, when the contact point between the workpiece and the steady rest is ground, the pushing force of the steady rest is lost, and the elastic deformation of the workpiece is increased immediately. As a result, a step shape error is generated at the contact point. To improve the use of the steady rest, the elastic deformation of the workpiece during the grinding process is simulated using the beam model considering the steady rest in this study. From the analysis results, it was determined that placing the steady rest outside the grinding part can reduce the elastic deformation of the workpiece. In addition, the traverse speed was controlled to maintain a constant elastic deformation. Through grinding experiments, it was confirmed that the form accuracy of the slender workpiece was improved by setting the steady rest outside the grinding part and adjusting the traverse speed.

Published
2021
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2. Development of the intelligent cylindrical grinding system considering the thermal deformation of a workpiece

Author

Takashi ONISHI, Moriaki SAKAKURA, Takuo OKANOUE, Kohei FUJIWARA, Yasuhiro FUJIYAMA, and Kazuhito OHASHI

Subjects
cylindrical grinding, thermal deformation, grinding heat, size accuracy, intelligent grinding system, Engineering machinery, tools, and implements, TA213-215, Mechanical engineering and machinery, TJ1-1570
Abstract

In cylindrical grinding, the size accuracy of a workpiece decreases due to the thermal deformation of the ground workpiece. To improve the size accuracy, it is necessary to consider the thermal deformation of the workpiece during grinding process. In this study, we have developed an intelligent grinding system that can consider the thermal deformation of the workpiece. In this system, the thermal deformation of the workpiece during grinding process is simulated by measuring tangential grinding force. The net stock removal, that is the stock removal measured after the workpiece has been cooled, is estimated by adding the measured stock removal and the simulated thermal deformation of the workpiece. To achieve the grinding process with high accuracy, the grinding wheel is retracted when the net stock removal is reached to the grinding allowance. Using this intelligent grinding system, grinding experiments were carried out. In these experiments, the size error was reduced less than 0.3μm in radius even though the thermal deformation was more than 2μm in radius. With grinding experiments, it was confirmed that the developed grinding system could improve the size accuracy successfully.

Published
2018
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4. Accurate estimation of workpiece dimension in plunge grinding without sizing gauge

Author

Takashi Onishi, Kohei Fujiwara, Kazuhito Ohashi, Moriaki Sakakura, and Yuki Murata

Subjects
Materials science, Volume (thermodynamics), Abrasive, General Engineering, Mechanical engineering, Allowance (engineering), Gauge (firearms), Residual, Sizing, Grinding, Rubbing
Abstract

In the cylindrical grinding process, the residual grinding allowance is left owing to the rubbing of the abrasive grains and the elastic deformation of the grinding system caused by the large normal grinding force. Therefore, a sizing gauge is generally used to monitor the workpiece diameter during the process. However, the sizing gauge disturbs the grinding operations, such as loading and unloading the workpiece. In this study, a new method for estimating the grinding stock of a ground workpiece is proposed. In the proposed method, the grinding stock can be estimated without a sizing gauge. The removed volume of the workpiece can be calculated from the power consumption of the wheel motor, which is easily measured. Before the grinding experiments, the specific grinding energy is determined from several grinding results. During the grinding process, the grinding stock of the ground workpiece was estimated using the determined specific grinding energy. It was confirmed that the grinding stock could be accurately estimated under several grinding conditions.

Published
2022
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6. Improvement of the Form Accuracy of a Slender Workpiece in Cylindrical Traverse Grinding

Author

Kazuhito Ohashi, Moriaki Sakakura, Teppei Takashima, Takashi Onishi, and Koichi Sakamoto

Subjects
0209 industrial biotechnology, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, Materials science, Traverse, 0203 mechanical engineering, Mechanical Engineering, 02 engineering and technology, Composite material, Industrial and Manufacturing Engineering, Grinding
Abstract

During the cylindrical traverse grinding of a slender workpiece, the ground workpiece is easily bent by the normal grinding force owing to its low stiffness. Therefore, it is difficult to finish the slender workpiece with high accuracy. To prevent the elastic deformation of a workpiece during the grinding process, a steady rest is generally used. However, considerable skill of the worker is required to use a steady rest. Therefore, we developed a new traverse grinding method without any steady rest. In this method, the elastic deformation of a workpiece was kept constant by controlling the traverse speed of the workpiece. At the middle of the ground workpiece, where the elastic deformation increased easily, the traverse speed was slowed down. However, this method had a longer grinding cycle time because the average traverse speed decreased compared to that of the conventional method. To shorten the cycle time, the peripheral speed of the grinding wheel was increased to decrease the normal grinding force. Basic grinding experiments were carried out under several grinding conditions by changing the peripheral speed of the wheel. From these grinding experiments, it was confirmed that the normal grinding force and the form error of the ground workpiece decreased as the peripheral wheel speed increased. By using results obtained from basic experiments, grinding experiments involving changes in the traverse speed were carried out at two peripheral wheel speeds. The grinding cycle time was reduced successfully by increasing the peripheral wheel speed without an increment in the form error of the ground workpiece. Furthermore, a form error was observed at the end of the workpiece where the grinding wheel traveled away from the workpiece. The form error occurred because the normal grinding force decreased rapidly when the contact length between the workpiece and the wheel was decreased at the end of the workpiece. To prevent rapid changes in the normal grinding force, the traverse speed of the workpiece was increased at the end of the workpiece. By using this method, a ground workpiece with high form accuracy was obtained.

Published
2019
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8. Improvement of the Form Accuracy Ground by a Slender Wheel in Internal Grinding

Author

Go Ichiba, Yusuke Nakabayashi, Takashi Onishi, Moriaki Sakakura, and Kazuhito Ohashi

Subjects
Form error, Materials science, Of the form, Deformation (engineering), Composite material, Grinding
Abstract

In the case of internal grinding of a deep hole, the inner surface of the hole was ground by a slender grinding wheel that has a high aspect ratio. A slender grinding wheel is bent by the normal grinding force during the grinding process. Therefore, the form accuracy of the ground workpiece is decreased especially when the aspect ratio of a wheel is high. In our previous study, it was confirmed that the biggest factor that generated the form error of the workpiece was the elastic deformation owning to the normal grinding force. To reduce the form error of the ground workpiece, it is effective to expand the spark-out duration. However, the expansion of the spark-out duration leads to the low productivity. In this study, the form of the grinding wheel was modified by a diamond dresser to improve the form accuracy of the workpiece without expanding the spark-out duration. The modified form of a wheel was determined to compensate the form error of the workpiece generated by the elastic deformation of the grinding wheel. Thorough several grinding experiment, it was confirmed that the form accuracy of the ground workpiece was successfully improved by modifying the form of a slender grinding wheel without expanding the spark-out duration.

Published
2020
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9. Effect of Steady Rest in Cylindrical Traverse Grinding of Slender Workpiece

Author

Kazuhito Ohashi, Moriaki Sakakura, Takashi Onishi, Chinhu Lin, and Hidetaka Fujii

Subjects
Rest (physics), Traverse, Materials science, Mechanics, Deformation (engineering), Grinding
Abstract

In the case of traverse grinding of a slender workpiece, the ground workpiece is easily deformed by the normal grinding force due to its low stiffness. To reduce the form error caused by the elastic deformation of the workpiece, a steady rest is widely used. Generally, a steady rest is set to push the ground area of the workpiece. However, the stepped shape error is generated at the contact point where a steady rest pushed the workpiece because the pushing force of a steady rest is decreased after the material of the contact point is removed. In this study, to reduce the stepped shape error of the ground workpiece, we proposed a new method to set a steady rest. In this method, the steady rest was set to push the area where was not ground. In addition, the traverse speed of the workpiece was adjusted to keep the elastic deformation of the workpiece constant. The suitable method to control the traverse speed was estimated by using a beam model that could simulate the elastic deformation of the workpiece during the grinding process. It was confirmed that the new method could improve the form accuracy of a slender workpiece through grinding experiments.

Published
2020
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12. Experimental Study of the Causes for Shape Error of a Large Workpiece Machined by Surface Grinding

Author

Yusuke Nakano, Yoshiyuki Shimizu, Takashi Onishi, Kazuhito Ohashi, Shinya Tsukamoto, Moriaki Sakakura, Makoto Harada, and Shinsuke Baba

Subjects
Surface (mathematics), Materials science, business.product_category, business.industry, Thermal deformation, General Engineering, Structural engineering, Mechanics, Machine tool, Grinding, Residual stress, Surface grinding, Ultimate tensile strength, business, Constant (mathematics)
Abstract

In surface grinding of a large workpiece used for a sliding surface of the machine tool, high shape accuracy is required for the ground surface. Therefore, it is important to investigate the causes of the shape error observed in a large workpiece machined by surface grinding. In this study, we focused on the thermal deformation and residual stress as the causes of shape error. The in-process measurement of the workpiece temperature distribution was carried out to estimate the effect of the thermal deformation to the shape error. The estimated value of the shape error calculated from the measured temperature distribution was much less than the actual measured shape error. Therefore, the residual stress on the ground surface was measured with a portable X-ray stress measurement device. The residual stress was changed from compressed state to tensile state as the grinding pass increased. The ground shape was also deformed to concave shape as the grinding pass increased. The value of the shape error was finally reached to the constant value in several grinding conditions. From these experimental results, it is suggested that the shape error of the large workpiece is caused by the residual stress applied to the ground surface.

Published
2016
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14. Simulation Analysis and In-Process Measurement of the Workpiece Temperature Distribution in Large Surface Grinding

Author

Moriaki Sakakura, Kazutoshi Kawakami, Makoto Harada, Yusuke Nakano, Takashi Onishi, Shinya Tsukamoto, Kazuhito Ohashi, and Takeshi Sakane

Subjects
Materials science, Mechanics of Materials, Mechanical Engineering, System of measurement, Thermistor, Surface grinding, Process (computing), Mechanical engineering, General Materials Science, Point (geometry), Grinding wheel, Work in process, Grinding
Abstract

In surface grinding, the shape error is occurred by the thermal deformation of a ground workpiece. To finish the workpiece with high accuracy, it is necessary to understand the temperature distribution of the workpiece during grinding process. However there is no study to analyze the temperature distribution of a large workpiece during surface grinding process. In this study, an advanced simulation analysis method of the temperature distribution for a large workpiece was developed. In the developed simulation analysis method, the temperature distribution was calculated from the power consumption of the wheel motor. The power consumption can be obtained easily without any specialized equipment. To evaluate the developed simulation analysis method, in-process measurement of the temperature distribution of a large workpiece was also carried out. A large workpiece ground in this study weights about 1.3 tons. The temperature distribution was measured with thermistors mounted in many places of the ground workpiece. At the area close to the grinding surface, it was found that temperature rises immediately after the passage of grinding wheel with measuring the developed in-process measurement system. On the other hand, at the area far from the grinding point, temperature does not change quickly. The in-process measured temperature distribution agreed well with the simulated results.

Published
2015
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15. Study on the Shape Error in the Cylindrical Traverse Grinding of a Workpiece with High Aspect Ratio

Author

Takashi Onishi, Takuya Kodani, Moriaki Sakakura, Shinya Tsukamoto, and Kazuhito Ohashi

Subjects
Grinding process, Traverse, Materials science, business.industry, General Engineering, Stiffness, Structural engineering, Physics::Classical Physics, Computer Science::Other, Grinding, Computer Science::Robotics, Computer Science::Computational Engineering, Finance, and Science, medicine, Composite material, medicine.symptom, business
Abstract

In cylindrical traverse grinding of a long workpiece with high aspect ratio, the shape accuracy of a workpiece worsens due to its low stiffness. In this study, the grinding force was measured during grinding process to calculate the elastic deformation of a workpiece caused by the normal grinding force. By comparing calculated elastic deformation with the measured shape error of ground workpiece, the cause for the shape error in case of grinding a long workpiece was investigated experimentally. From experimental results, it is confirmed that the main factor of the shape error of the long workpiece is its elastic deformation during grinding process.

Published
2014
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17. Grinding System Reducing the Influence of Thermal Deformation of Workpiece in Cylindrical Grinding

Author

Kazuhito Ohashi, Takashi Onishi, Takuya Kodani, Moriaki Sakakura, Naoki Sato, and Shinya Tsukamoto

Subjects
Grinding process, Materials science, Thermal deformation, General Engineering, Stock removal, Cylindrical grinding, Composite material, Sizing, Grinding
Abstract

In cylindrical grinding, a sizing device is generally used to obtain the required dimension. However, the dimensional error can be caused by the thermal deformation of the workpiece even if grinding machine is controlled with the sizing device. To solve this problem, it is necessary to develop the grinding system that can consider the thermal deformation of the workpiece during grinding process. In this study, an advanced grinding system was developed, which can predict the net stock removal of ground workpiece immediately. The grinding experiment is carried out to verify the developed system.

Published
2013
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18. Development of the intelligent cylindrical grinding system considering the thermal deformation of a workpiece

Author

Yasuhiro Fujiyama, Takashi Onishi, Kazuhito Ohashi, Moriaki Sakakura, Takuo Okanoue, and Kohei Fujiwara

Subjects
0209 industrial biotechnology, 020901 industrial engineering & automation, Materials science, Mechanical Engineering, 0502 economics and business, 05 social sciences, Thermal deformation, Mechanical engineering, Development (differential geometry), 02 engineering and technology, Cylindrical grinding, 050203 business & management, Industrial and Manufacturing Engineering
Published
2018
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20. Visual simulation of the grinding process

Author

Takanori Fujiwara, Shinya Tsukamoto, Moriaki Sakakura, and Ichiro Inasaki

Subjects
Generation process, Grinding process, Engineering, Machining, business.industry, Mechanical Engineering, Abrasive, Monte Carlo method, Mechanical engineering, Elasticity (economics), business, Industrial and Manufacturing Engineering, Grinding
Abstract

Grinding is one of the machining methods for finishing that is performed by using a large number of abrasive grains with irregular shapes and random distribution. While this feature enables accurate and high-quality machining, it complicates analysis of the grinding process. To solve this problem, a great number of computer simulations have been carried out using the Monte Carlo method. Most of them, however, statically calculate geometric interaction between a grain and a workpiece, and have not provided enough achievements for practical applications. In this study, taking this background into account, a simulation program has been developed based on the elastic support model of a grain in which the elasticity of grain support changes according to its location. The program focuses on the generation process of a workpiece surface, and simulates the interaction between grains and a workpiece, which includes the elastic and plastic deformation as well as the removal of workpiece material. Examples of the simulation shown in this study verify the fact that the simulation program facilitates analysis of the microscopic grinding phenomena, and can be used as a practical tool for predicting the grinding results and for optimizing grinding parameters.

Published
2008
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21. Numerical Analysis for Thermal Deformation of Workpiece in Cylindrical Plunge Grinding

Author

Moriaki Sakakura, Shinya Tsukamoto, Suritalatu, and Hiroyuki Hasegawa

Subjects
Grinding process, Fabrication, Materials science, Mechanics of Materials, Mechanical Engineering, Heat generation, Numerical analysis, Abrasive, Thermal deformation, Mechanical engineering, General Materials Science, Thermal conduction, Grinding
Abstract

During the last decades, heat generation in grinding is one of the top concerns because high temperature under fabrication leads to less dimensional accuracy of a workpiece. Several studies with regard to grinding heat have been carried out, focused on micro phenomena of abrasive grains or macro phenomena of thermal deformation in grinding machines. However, these researches have been extensive, schematized information such as thermal deformation, and grinding temperature is indispensable for practical applications. In this study, we combined the simulation model of the plunge grinding process and the numerical analysis method with the differencing technique for the non-steady heat conduction problem, and have constructed the simulation technique for analyzing the heat problem in the workpiece. The simulation results provided information of the heat conduction, and the thermal deformation of the workpiece.

Published
2008
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22. Analysis of Pin Grinding Mechanism in Twin Axes Synchronous Controlled Cranshaft Pin Grinder

Author

Masahiro Miyagawa, Takanori Fujiwara, Shinya Tsukamoto, Moriaki Sakakura, Mitsuo Yoshikawa, and Akinori Omori

Subjects
Crankshaft, Engineering, business.industry, Mechanical Engineering, Mechanical engineering, Rotational speed, Residual, Industrial and Manufacturing Engineering, Grinding, law.invention, Mechanism (engineering), Mechanics of Materials, law, Pulverizer, Surface roughness, Gear ratio, business
Abstract

Twin axes synchronous controlled type CNC crankshaft pin grinder has been widely used, but grinding mechanism with this type of pin grinder is not cleared well. In this study, the grinding mechanism is analyzed, and it is found that the cylindrical plunge grinding process carries on. From the investigation of substantial surface speed of both the wheel and the workpiece, grinding speed ratio is formulated. Furthermore, a simulation method, which predicts the grinding results, is developed. In order to realize high precision pin grinding, two methods, which control workpiece rotation speed adequately, are proposed, such as the controlled grinding speed ratio method and the controlled residual stock method. From the analysis, it is made clear that stable grinding force and surface roughness are generated by the controlled grinding speed ratio method, and also high dimensional accracy will be realized by the controlled residual stock method.

Published
2007
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23. A SKILL-FORMATION MODEL FOR GRINDING OPERATIONS

Author

Takanori Fujiwara, Shinya Tsukamoto, Moriaki Sakakura, and Ichiro Inasaki

Subjects
Engineering, Operator (computer programming), Machining, business.industry, Control theory, Mechanical Engineering, General Materials Science, Trial and error, business, Industrial and Manufacturing Engineering, Simulation, Grinding
Abstract

A good part of grinding operations is still dependent on skilled operators. Against such a background, this study takes up cylindrical plunge grinding, and presents a skill-formation model based on the learning process similar to that in which a grinding operator acquires skills through trial and error. The model repeats learning by giving only the total grinding stock and initial infeed rate, changing infeed rate, and evaluating the size and the removal rate in the process end. The simulation result has proved that the model shows a skill-formation process similar to that of an operator and generates desirable infeed processes.

Published
2006
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26. Form-Shaping Systems of Machine Tools: Theory and Applications

Author

V.T. Portman, Makoto Iwatate, Ichiro Inasaki, and Moriaki Sakakura

Subjects
Engineering, Engineering drawing, business.product_category, business.industry, Process (engineering), Mechanical Engineering, Mechanical engineering, Inverse, Form generation, Kinematics, Physics::Classical Physics, Industrial and Manufacturing Engineering, Machine tool, business, ComputingMethodologies_COMPUTERGRAPHICS
Abstract

The form-shaping process is the main functional process performed by a machine tool. A theory of the form-shaping system (FSS) investigates interrelationships between, on the one hand, geometry and kinematics of the machine tool and, on the other, geometry and accuracy of the machined part. In this paper, the FSS theory is developed in the following ways: (1) the general approach spreads also to the FSS with parallel-type links (previously, only chain-type systems were discussed); (2) direct and inverse form-shaping problems are formulated.

Published
1998
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27. A Study on a Learning Model for Setup of Grinding Parameters. Experimental Verification

Author

Moriaki Sakakura and Ichiro Inasaki

Subjects
Grinding process, Engineering, business.industry, Mechanical Engineering, media_common.quotation_subject, Machine learning, computer.software_genre, Generalization error, Industrial and Manufacturing Engineering, Learning data, Grinding, Range (mathematics), Mechanics of Materials, Fuzzy reasoning, Quality (business), Artificial intelligence, business, computer, media_common
Abstract

A learning model for the setup of grinding parameters had been developed by the authors using genetic algolithms and the fuzzy reasoning algorithm. Although the effectiveness of the model has been proven through a wide range of computer simulations, further practical investigations are required for industrial applications. In this respect, the performance of the model is investigated experimentally in this study. Since the performance of any learning model is affected by learning data, particular attention is paid to the influence of learning data. Ouality and quantity of the data obtained from the grinding process is discussed. The experimental results prove that the number of learning data has an influence on the rules obtained. Insufficient data cannot generate sufficient rules. On the other hand, an excessive amount of data degrades quality of the rules, which could be attributed to confliction of learning data.

Published
1995
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29. An Adaptive Causality Model of Grinding Process

Author

Ichiro Inasaki and Moriaki Sakakura

Subjects
Grinding process, Engineering drawing, Engineering, business.industry, Mechanical Engineering, Edge (geometry), Industrial and Manufacturing Engineering, Grinding, Causality (physics), Mechanics of Materials, Robustness (computer science), Control theory, Surface roughness, business
Abstract

This paper addresses a modeling method of quantitative relationships between grinding parameters and grinding results. With consideration of reasons why conventional empirical formulae are not accurate enough for practical use, a new model named the "adaptive causality model" is developed, which has adaptivity to time-varying conditions and robustness for unexpected change of conditions. As a case study, the developed model was applied to the relationship between certain dressing and grinding parameters and surface roughness of a ground workpiece, and an experimental analysis was carried out. In the experiment, wear of the edge of a single-point diamond dresser was considered as a time-varying condition. Moreover, workpieces of different material were often ground to simulate unexpected change of conditions. The experimental result proves that the "adaptive causality model" determines the quantitative relationship with sufficient accuracy in spite of change of the dresser edge and existence of some deviating data.

Published
1993
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32. A Neural Network Approach to the Decision-Making Process for Grinding Operations

Author

Ichiro Inasaki and Moriaki Sakakura

Subjects
Structure (mathematical logic), Engineering, Mathematical optimization, Artificial neural network, business.industry, Manufacturing process, Mechanical Engineering, Process (computing), Industrial and Manufacturing Engineering, Grinding, Surface roughness, Process control, Artificial intelligence, Decision-making, business, ComputingMethodologies_COMPUTERGRAPHICS
Abstract

Summary In this paper, a decision making process model for grinding operations is proposed. It has a multistage structure and consists of different two types of neural network : the Feed-Forward network and the Brain-State-in-a-Box network. As an application example of the model. the relationship between the dressing conditions and the surface roughness of ground components is simulated. The results indicate that the proposed model is capable of learning the stochastic data of surface roughness and recalling the dressing conditions which attains the required surface roughness. The simulated process can be considered to be quite similar to the decision making process of experienced operators.

Published
1992
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34. Visual Simulation of Grinding Process

Author

Ichiro Inasaki, Moriaki Sakakura, Shinya Tsukamoto, and Takanori Fujiwara

Subjects
Grinding process, Materials science, Machining, Interference (communication), Feature (computer vision), Monte Carlo method, Abrasive, Mechanical engineering, Graphics, Grinding
Abstract

Publisher Summary Grinding is one of the machining methods for finishing that is performed by using a large number of abrasive grains with irregular shapes and random distribution. While this feature enables accurate and high quality machining, it complicates analysis of the grinding process. In order to solve this problem, several computer simulations have been carried out using the Monte Carlo Method. Most of them statically calculate geometric interference between a grain and a workpiece, and have not provided enough achievements for practical applications. This chapter outlines the development of a simulation program based on the elastic behavior model of a grain. The program focuses on the generation process of a workpiece surface, and simulates the interaction of grains with a workpiece, which includes the elastic and plastic deformation and the removal of workpiece material. The simulation result is visualized using a three-dimensional graphics technique. The chapter illustrates an example, which verifies that the simulation program makes it easy to analyze the microscopic grinding phenomena, and can be used as a practical tool for predicting the grinding results and for optimizing grinding parameters.

Published
2006
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40. C23 Simulation Analysis and Measurement of Workpiece Thermal Deformation during Cylindrical PlungeGrinding (1st Report) : Simulation Analysis of Thermal Deformation Considering Temperature Distribution

Author

Takayuki Shinoda, Moriaki Sakakura, Shinya Tsukamoto, Takashi Onishi, Kazuhito Ohashi, and Yohei Wada

Subjects
Materials science, Distribution (number theory), business.industry, Thermal deformation, Mechanical engineering, Structural engineering, business
Published
2010
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44. S133015 Study on the Causes of Dimension Error in Surface Grinding with a Large Grinding Machine : Simulation Analysis of Workpiece Temperature Distribution during Grinding

Author

Tsuyoshi Sakane, Yusuke Nakano, Makoto Harada, Shinya Tsukamoto, Kazuhito OHASHl, Sho Isobe, Moriaki Sakakura, and Takashi Onishi

Subjects
Materials science, Dimension (vector space), Distribution (number theory), Machine simulation, Surface grinding, Mechanical engineering, Grinding
Published
2013
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