Torque and cutting force prediction model by using response surface method
This paper describes the development of a response models (cutting force, and torque) for milling 618 stainless steel utilizing response surface methods. The both models are developed in terms of cutting speed, feed rate, axial depth and radial depth. The cutting force and torque contours have been...
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my.uniten.dspace-298452023-12-28T16:57:55Z Torque and cutting force prediction model by using response surface method Kadirgama K. Abou-El-Hossein K.A. 12761486500 8367728100 Cutting Force Milling Surface Response Method Torque Milling (machining) Surface properties Torque Cutting forces Cutting speed Model equations Response model Response surface method Second orders Surface response method Variance analysis Cutting This paper describes the development of a response models (cutting force, and torque) for milling 618 stainless steel utilizing response surface methods. The both models are developed in terms of cutting speed, feed rate, axial depth and radial depth. The cutting force and torque contours have been generated from these model equations and are shown of different plots. The model generated show that the cutting force reach the maximum value when cutting speed decreased and , feed rate, axial depth and radial depth are increased. The torque reaches the maximum value when cutting speed decreased and, feed rate, axial depth and radial depth are increased. The plot which shows the relationship between the torque and cutting speed been developed. From the plot, the cutting forces reach the highest value when the torque increased .The second order is more accurate based on the variance analysis and the predicted value is closer with the experimental result. � 2006, IJAMAS, CESER. Final 2023-12-28T08:57:55Z 2023-12-28T08:57:55Z 2006 Article 2-s2.0-67249092992 https://www.scopus.com/inward/record.uri?eid=2-s2.0-67249092992&partnerID=40&md5=f06bebf6e96b0c261d4c5b9e2251c8a0 https://irepository.uniten.edu.my/handle/123456789/29845 4 MO6 11 30 Scopus |
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Cutting Force Milling Surface Response Method Torque Milling (machining) Surface properties Torque Cutting forces Cutting speed Model equations Response model Response surface method Second orders Surface response method Variance analysis Cutting |
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Cutting Force Milling Surface Response Method Torque Milling (machining) Surface properties Torque Cutting forces Cutting speed Model equations Response model Response surface method Second orders Surface response method Variance analysis Cutting Kadirgama K. Abou-El-Hossein K.A. Torque and cutting force prediction model by using response surface method |
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This paper describes the development of a response models (cutting force, and torque) for milling 618 stainless steel utilizing response surface methods. The both models are developed in terms of cutting speed, feed rate, axial depth and radial depth. The cutting force and torque contours have been generated from these model equations and are shown of different plots. The model generated show that the cutting force reach the maximum value when cutting speed decreased and , feed rate, axial depth and radial depth are increased. The torque reaches the maximum value when cutting speed decreased and, feed rate, axial depth and radial depth are increased. The plot which shows the relationship between the torque and cutting speed been developed. From the plot, the cutting forces reach the highest value when the torque increased .The second order is more accurate based on the variance analysis and the predicted value is closer with the experimental result. � 2006, IJAMAS, CESER. |
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12761486500 |
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12761486500 Kadirgama K. Abou-El-Hossein K.A. |
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Article |
| author |
Kadirgama K. Abou-El-Hossein K.A. |
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Kadirgama K. |
| title |
Torque and cutting force prediction model by using response surface method |
| title_short |
Torque and cutting force prediction model by using response surface method |
| title_full |
Torque and cutting force prediction model by using response surface method |
| title_fullStr |
Torque and cutting force prediction model by using response surface method |
| title_full_unstemmed |
Torque and cutting force prediction model by using response surface method |
| title_sort |
torque and cutting force prediction model by using response surface method |
| publishDate |
2023 |
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1806455106293465088 |
| score |
13.219503 |