JIAO, XiaoYang ;LIU, GuoJun ;LIU, JianFang ;LI, Xinbo ;LIU, XiaoLun ;LU, Song . Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation. Strojniški vestnik - Journal of Mechanical Engineering, [S.l.], v. 59, n.12, p. 763-771, june 2018. ISSN 0039-2480. Available at: <https://www.sv-jme.eu/sl/article/research-on-levitation-coupled-with-standing-wave-levitation-and-electromagnetic-levitation/>. Date accessed: 21 nov. 2024. doi:http://dx.doi.org/10.5545/sv-jme.2013.1093.
Jiao, X., Liu, G., Liu, J., Li, X., Liu, X., & Lu, S. (2013). Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation. Strojniški vestnik - Journal of Mechanical Engineering, 59(12), 763-771. doi:http://dx.doi.org/10.5545/sv-jme.2013.1093
@article{sv-jmesv-jme.2013.1093,
author = {XiaoYang Jiao and GuoJun Liu and JianFang Liu and Xinbo Li and XiaoLun Liu and Song Lu},
title = {Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation},
journal = {Strojniški vestnik - Journal of Mechanical Engineering},
volume = {59},
number = {12},
year = {2013},
keywords = {standing wave levitation;ANSYS simulation;electromagnetic levitation;non-contact cooling},
abstract = {In order to solve the problem caused by metal materials' inability to be cooled without contact with other materials after being heated by electromagnetic levitation, a new method is proposed: using a standing wave levitator to levitate the melted metal. The standing wave levitator adopts a concave spherical surface on the emitter and the reflector. Using ANSYS software, the transducer and the standing wave fields were simulated. Based on the simulation, the distribution and the maximum acoustic pressure with different radii of the concave spherical surface on the emitter and the reflector can be obtained, from which the optimal radius was determined. Based on the optimisation, a prototype of a standing wave levitation device was designed and manufactured. Levitation experiments for light and heavy specimens were carried out. It is shown that steel balls can be levitated stably when the distance between the emitter and the reflector is two times that of the wavelength. Next, the standing wave levitator was used in an attempt to levitate a steel ball of 5 mm in diameter after being non-contact heated by electromagnetic levitation. The results show that the method utilising a standing wave levitator to levitate and cool the metal materials after being non-contact heated by the electromagnetic levitation is feasible at this preliminary state.},
issn = {0039-2480}, pages = {763-771}, doi = {10.5545/sv-jme.2013.1093},
url = {https://www.sv-jme.eu/sl/article/research-on-levitation-coupled-with-standing-wave-levitation-and-electromagnetic-levitation/}
}
Jiao, X.,Liu, G.,Liu, J.,Li, X.,Liu, X.,Lu, S. 2013 June 59. Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation. Strojniški vestnik - Journal of Mechanical Engineering. [Online] 59:12
%A Jiao, XiaoYang %A Liu, GuoJun %A Liu, JianFang %A Li, Xinbo %A Liu, XiaoLun %A Lu, Song %D 2013 %T Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation %B 2013 %9 standing wave levitation;ANSYS simulation;electromagnetic levitation;non-contact cooling %! Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation %K standing wave levitation;ANSYS simulation;electromagnetic levitation;non-contact cooling %X In order to solve the problem caused by metal materials' inability to be cooled without contact with other materials after being heated by electromagnetic levitation, a new method is proposed: using a standing wave levitator to levitate the melted metal. The standing wave levitator adopts a concave spherical surface on the emitter and the reflector. Using ANSYS software, the transducer and the standing wave fields were simulated. Based on the simulation, the distribution and the maximum acoustic pressure with different radii of the concave spherical surface on the emitter and the reflector can be obtained, from which the optimal radius was determined. Based on the optimisation, a prototype of a standing wave levitation device was designed and manufactured. Levitation experiments for light and heavy specimens were carried out. It is shown that steel balls can be levitated stably when the distance between the emitter and the reflector is two times that of the wavelength. Next, the standing wave levitator was used in an attempt to levitate a steel ball of 5 mm in diameter after being non-contact heated by electromagnetic levitation. The results show that the method utilising a standing wave levitator to levitate and cool the metal materials after being non-contact heated by the electromagnetic levitation is feasible at this preliminary state. %U https://www.sv-jme.eu/sl/article/research-on-levitation-coupled-with-standing-wave-levitation-and-electromagnetic-levitation/ %0 Journal Article %R 10.5545/sv-jme.2013.1093 %& 763 %P 9 %J Strojniški vestnik - Journal of Mechanical Engineering %V 59 %N 12 %@ 0039-2480 %8 2018-06-28 %7 2018-06-28
Jiao, XiaoYang, GuoJun Liu, JianFang Liu, Xinbo Li, XiaoLun Liu, & Song Lu. "Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation." Strojniški vestnik - Journal of Mechanical Engineering [Online], 59.12 (2013): 763-771. Web. 21 Nov. 2024
TY - JOUR AU - Jiao, XiaoYang AU - Liu, GuoJun AU - Liu, JianFang AU - Li, Xinbo AU - Liu, XiaoLun AU - Lu, Song PY - 2013 TI - Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation JF - Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2013.1093 KW - standing wave levitation;ANSYS simulation;electromagnetic levitation;non-contact cooling N2 - In order to solve the problem caused by metal materials' inability to be cooled without contact with other materials after being heated by electromagnetic levitation, a new method is proposed: using a standing wave levitator to levitate the melted metal. The standing wave levitator adopts a concave spherical surface on the emitter and the reflector. Using ANSYS software, the transducer and the standing wave fields were simulated. Based on the simulation, the distribution and the maximum acoustic pressure with different radii of the concave spherical surface on the emitter and the reflector can be obtained, from which the optimal radius was determined. Based on the optimisation, a prototype of a standing wave levitation device was designed and manufactured. Levitation experiments for light and heavy specimens were carried out. It is shown that steel balls can be levitated stably when the distance between the emitter and the reflector is two times that of the wavelength. Next, the standing wave levitator was used in an attempt to levitate a steel ball of 5 mm in diameter after being non-contact heated by electromagnetic levitation. The results show that the method utilising a standing wave levitator to levitate and cool the metal materials after being non-contact heated by the electromagnetic levitation is feasible at this preliminary state. UR - https://www.sv-jme.eu/sl/article/research-on-levitation-coupled-with-standing-wave-levitation-and-electromagnetic-levitation/
@article{{sv-jme}{sv-jme.2013.1093},
author = {Jiao, X., Liu, G., Liu, J., Li, X., Liu, X., Lu, S.},
title = {Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation},
journal = {Strojniški vestnik - Journal of Mechanical Engineering},
volume = {59},
number = {12},
year = {2013},
doi = {10.5545/sv-jme.2013.1093},
url = {https://www.sv-jme.eu/sl/article/research-on-levitation-coupled-with-standing-wave-levitation-and-electromagnetic-levitation/}
}
TY - JOUR AU - Jiao, XiaoYang AU - Liu, GuoJun AU - Liu, JianFang AU - Li, Xinbo AU - Liu, XiaoLun AU - Lu, Song PY - 2018/06/28 TI - Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation JF - Strojniški vestnik - Journal of Mechanical Engineering; Vol 59, No 12 (2013): Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2013.1093 KW - standing wave levitation,ANSYS simulation,electromagnetic levitation,non-contact cooling N2 - In order to solve the problem caused by metal materials' inability to be cooled without contact with other materials after being heated by electromagnetic levitation, a new method is proposed: using a standing wave levitator to levitate the melted metal. The standing wave levitator adopts a concave spherical surface on the emitter and the reflector. Using ANSYS software, the transducer and the standing wave fields were simulated. Based on the simulation, the distribution and the maximum acoustic pressure with different radii of the concave spherical surface on the emitter and the reflector can be obtained, from which the optimal radius was determined. Based on the optimisation, a prototype of a standing wave levitation device was designed and manufactured. Levitation experiments for light and heavy specimens were carried out. It is shown that steel balls can be levitated stably when the distance between the emitter and the reflector is two times that of the wavelength. Next, the standing wave levitator was used in an attempt to levitate a steel ball of 5 mm in diameter after being non-contact heated by electromagnetic levitation. The results show that the method utilising a standing wave levitator to levitate and cool the metal materials after being non-contact heated by the electromagnetic levitation is feasible at this preliminary state. UR - https://www.sv-jme.eu/sl/article/research-on-levitation-coupled-with-standing-wave-levitation-and-electromagnetic-levitation/
Jiao, XiaoYang, Liu, GuoJun, Liu, JianFang, Li, Xinbo, Liu, XiaoLun, AND Lu, Song. "Research on Levitation Coupled with Standing Wave Levitation and Electromagnetic Levitation" Strojniški vestnik - Journal of Mechanical Engineering [Online], Volume 59 Number 12 (28 June 2018)
Strojniški vestnik - Journal of Mechanical Engineering 59(2013)12, 763-771
© The Authors, CC-BY 4.0 Int. Change in copyright policy from 2022, Jan 1st.
In order to solve the problem caused by metal materials' inability to be cooled without contact with other materials after being heated by electromagnetic levitation, a new method is proposed: using a standing wave levitator to levitate the melted metal. The standing wave levitator adopts a concave spherical surface on the emitter and the reflector. Using ANSYS software, the transducer and the standing wave fields were simulated. Based on the simulation, the distribution and the maximum acoustic pressure with different radii of the concave spherical surface on the emitter and the reflector can be obtained, from which the optimal radius was determined. Based on the optimisation, a prototype of a standing wave levitation device was designed and manufactured. Levitation experiments for light and heavy specimens were carried out. It is shown that steel balls can be levitated stably when the distance between the emitter and the reflector is two times that of the wavelength. Next, the standing wave levitator was used in an attempt to levitate a steel ball of 5 mm in diameter after being non-contact heated by electromagnetic levitation. The results show that the method utilising a standing wave levitator to levitate and cool the metal materials after being non-contact heated by the electromagnetic levitation is feasible at this preliminary state.