Thermal optimization and experimental research of high-speed universal pulverizer

doi:10.1007/s40436-017-0208-3

Advances in Manufacturing ›› 2018, Vol. 6 ›› Issue (1): 83-94.doi: 10.1007/s40436-017-0208-3

Thermal optimization and experimental research of high-speed universal pulverizer

Qiang He, An-Ling Li, Yuan Shen, Li-Li Li

School of Mechanical Engineering, Anyang Institute of Technology, Anyang 455000, Henan, People's Republic of China

收稿日期:2017-04-07 修回日期:2017-12-29 出版日期:2018-03-25 发布日期:2018-03-25
通讯作者: Qiang He,hq@ayit.edu.cn E-mail:hq@ayit.edu.cn
基金资助:
This project was supported by the National Natural Science Foundation of China (Grant No. 51105002), National Science and Technology Major Project (Grant No. 2012ZX04005-021), Natural Science Foundation of Henan Province (Grant No. 152102210196), and Foundation of Henan Educational Committee (Grant No. 16A460001).

Thermal optimization and experimental research of high-speed universal pulverizer

Qiang He, An-Ling Li, Yuan Shen, Li-Li Li

School of Mechanical Engineering, Anyang Institute of Technology, Anyang 455000, Henan, People's Republic of China

Received:2017-04-07 Revised:2017-12-29 Online:2018-03-25 Published:2018-03-25
Contact: Qiang He,hq@ayit.edu.cn E-mail:hq@ayit.edu.cn
Supported by:
This project was supported by the National Natural Science Foundation of China (Grant No. 51105002), National Science and Technology Major Project (Grant No. 2012ZX04005-021), Natural Science Foundation of Henan Province (Grant No. 152102210196), and Foundation of Henan Educational Committee (Grant No. 16A460001).

摘要/Abstract

摘要：

Because of high efficiency, energy conservation, simple operation, wide application range, and small size, the high-speed universal pulverizer has been well received by customers. However, its electrical motor can overheat when working, which hinders continuous operation of the pulverizer. In this study, a series of efforts were made to address this problem. Firstly, a detailed analysis of the working principle of the pulverizer was conducted and an optimization plan was proposed, consisting in punching ventilation holes on the surface of the original pulverizer. Simulations of the pulverizer flow field before and after optimization were performed. The hydrodynamic simulation results were used to conduct a steady state thermal analysis of the pulverizer, investigating the influence of the flow field on heat transfer. Additionally, experimental investigations were conducted on the pulverizer before and after optimization in order to measure and compare the parameters (motor working temperature, wind speed and temperature of the motor cooling system, vibration, noise, and pulverizing degree of the material) influencing the performance of the pulverizer. The numerical simulation results showed an increment in heat transfer caused by increment in air flow volume and velocity when air was injected into the pulverizer through bottom and side holes. Experimental results showed that the pulverizer with air injection through holes had the best performance when temperature, vibration, and refinement effect were considered as performance indicators.

The full text can be downloaded at https://link.springer.com/article/10.1007/s40436-017-0208-3

关键词: High-speed universal pulverizer, Flow field simulation, Thermal analysis, Pulverizing degree, Vibration noise

Abstract:

Key words: High-speed universal pulverizer, Flow field simulation, Thermal analysis, Pulverizing degree, Vibration noise

Qiang He, An-Ling Li, Yuan Shen, Li-Li Li. Thermal optimization and experimental research of high-speed universal pulverizer[J]. Advances in Manufacturing, 2018, 6(1): 83-94.

参考文献

1. Ying XU, Liu GF, Shu ZH (2004) Research and application status of grinding equipments for traditional Chinese medicine. China Powder Sci Technol 2:25-28
2. Che Z (2015) Rotor of pulveriser, WO/2015/006982
3. Wada T (2016) Pulveriser, absorber manufacturing apparatus provided with the same, and pulp sheet pulverizing method. US Patent 20160199849
4. Özer CE, Whiten WJ, Lynch AJ (2016) A multi-component model for the vertical spindle mill. Int J Miner Process 148:155-165
5. Shah KV, Vuthaluru R, Vuthaluru HB (2009) CFD based investigations into optimization of coal pulveriser performance:effect of classifier vane settings. Fuel Process Technol 90(9):1135-1141
6. Feng L, Gui W, Yang F (2010) Soft sensor modeling for mill output of duplex inlet & outlet ball pulverizer system based on an improved grey relational analysis. Chin J Sci Instrum 31(9):2062-2067
7. Changizi N, Kaboodanian H, Jalalpour M (2016) Stress-based topology optimization of frame structures under geometric uncertainty. Comput Methods Appl Mech Eng 315:121-140
8. Chi CJ, Zhou YD, Cao SQ et al (2015) Development of a pilot roller test machine for investigating the pulverizing performance of particle beds. Miner Eng 72:65-72
9. Nakamura H, Kan H, Takeuchi H et al (2015) Effect of stator geometry of impact pulverizer on its grinding performance. Chem Eng Sci 122(122):565-572
10. Archary H, Schmitz W, Jestin L (2016) Mass flow and particle size monitoring of pulverised fuel vertical spindle mills. Chem Process Eng 37(2):175-197
11. Takeuchi H, Nakamura H, Iwasaki T et al (2012) Numerical modeling of fluid and particle behaviors in impact pulverizer. Powder Technol 217(2):148-156
12. Takeuchi H, Nakamura H, Watano S (2013) Numerical simulation of particle breakage in dry impact pulverizer. AIChE J 59(10):3601-3611
13. Yuminoki K, Tachibana S, Nishimura Y et al (2016) Scaling up nano-milling of poorly water soluble compounds using a rotation/revolution pulverizer. Pharmazie 71(2):57-64
14. Vasiljev P (2012) Ultrasonic systems for liquid pulverizer. J VibroEng 14(2):489-495
15. Wang C, Qiu Z, Xu M et al (2017) Novel reliability-based optimization method for thermal structure with hybrid random, interval and fuzzy parameters. Appl Math Model 47:573-586
16. Wang C, Qiu Z (2015) Improved numerical prediction and reliability-based optimization of transient heat conduction problem with interval parameters. Struct Multidiscip Optim 51(1):113-123
17. Ahmed HE (2016) Optimization of thermal design of ribbed flatplate fin heat sink. Appl Therm Eng 102:1422-1432
18. Lewis RW, Nithiarasu P, Seetharamu KN (2004) Fundamentals of the finite element method for heat and fluid Flow. John Wiley & Sons Inc, New Jersey
19. Palmgren A (1959) A ball and roller bearing engineering. Burbank, Philadelphia
20. Harris TA, Crecelius WJ (2006) Rolling bearing analysis, fifth. CRC Press, Florida
21. Holkup T, Cao H, Kolár P et al (2010) Thermo-mechanical model of spindles. CIRP Ann Manuf Technol 59(1):365-368
22. Rohsenow WM, Hartnett JP, Cho YI (1959) Handbook of heat transfer, 3rd edn. McGraw-Hill Professional, Secs, New York, pp 6-8
23. Yang SM (1987) Heat transfer. Higher Education Press, Beijing

Thermal optimization and experimental research of high-speed universal pulverizer

Thermal optimization and experimental research of high-speed universal pulverizer

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 1

编辑推荐

Metrics

本文评价