A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Investigation on Cutting Power of Wood–Plastic Composite Using Response Surface Methodology
For the sake of improving the benefit of enterprise by reducing energy waste. RSM (response surface methodology) was used to investigated the cutting power of wood–plastic composite at different cutting conditions (rake angle, cutting speed, depth of cut, and flank wear). Based on the experimental results, a cutting power model with a high degree of fitting was developed, which can be used to predict cutting power and optimal cutting conditions. Meanwhile, the effects of rake angle, cutting speed, depth of cut, and flank wear and their interaction on the cutting power were probed by analysis of variance, and the significant terms were determined. Finally, the optimal cutting condition was obtained as follows: rake angle of 10°, cutting speed of 300 m/min, depth of cut of 1.5 mm, and flank wear of 0.1 mm. This parameter combination is suggested to be used for industrial manufacturing of wood–plastic composite in terms of the incredible machining efficiency and the lowest energy consumption.
Investigation on Cutting Power of Wood–Plastic Composite Using Response Surface Methodology
For the sake of improving the benefit of enterprise by reducing energy waste. RSM (response surface methodology) was used to investigated the cutting power of wood–plastic composite at different cutting conditions (rake angle, cutting speed, depth of cut, and flank wear). Based on the experimental results, a cutting power model with a high degree of fitting was developed, which can be used to predict cutting power and optimal cutting conditions. Meanwhile, the effects of rake angle, cutting speed, depth of cut, and flank wear and their interaction on the cutting power were probed by analysis of variance, and the significant terms were determined. Finally, the optimal cutting condition was obtained as follows: rake angle of 10°, cutting speed of 300 m/min, depth of cut of 1.5 mm, and flank wear of 0.1 mm. This parameter combination is suggested to be used for industrial manufacturing of wood–plastic composite in terms of the incredible machining efficiency and the lowest energy consumption.
Investigation on Cutting Power of Wood–Plastic Composite Using Response Surface Methodology
Wangyu Xu (author) / Zhanwen Wu (author) / Wei Lu (author) / Yingyue Yu (author) / Jinxin Wang (author) / Zhaolong Zhu (author) / Xiaodong Wang (author)
2022
Article (Journal)
Electronic Resource
Unknown
WPC , RSM , ANOVA , cutting power , cemented carbide , Plant ecology , QK900-989
Metadata by DOAJ is licensed under CC BY-SA 1.0
Optimizing Wood Composite Drilling with Artificial Neural Network and Response Surface Methodology
| DOAJ | 2024