Degassing of Pure Copper Melt by Ultrasonic Cavitation

J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng
Institute of Physics (IOP)
Published 2018

Publication Date:	2018-07-20
Publisher:	Institute of Physics (IOP)
Print ISSN:	1757-8981
Electronic ISSN:	1757-899X
Topics:	Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics
Published by:	http://www.iop.org/

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autor	J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng
beschreibung	The effect of high intensity ultrasonic vibration (UV) on degassing of pure copper has been studied in this paper. The methods of reduced pressure test (RPT) and direct hydrogen and oxygen measurements are used for the evaluation of degassing efficiency on hydrogen and oxygen concentrations. The results showed that high intensity UV had a significant degassing effect for the commercially pure copper (CP-Cu) melt. With UV, the density index Di was reduced from 11.94 to 1.13%, and the product of hydrogen-oxygen concentration ([ %H ]·[ %O ]) in the liquid Cu was decreased to 1.440×10 −5 from 6.624×10 −5 . It was also found that electric power and ultrasonic treatment time could influence the degassing efficiency.
citation_standardnr	6306798
datenlieferant	ipn_articles
feed_id	123476
feed_publisher	Institute of Physics (IOP)
feed_publisher_url	http://www.iop.org/
insertion_date	2018-07-20
journaleissn	1757-899X
journalissn	1757-8981
publikationsjahr_anzeige	2018
publikationsjahr_facette	2018
publikationsjahr_intervall	7984:2015-2019
publikationsjahr_sort	2018
publisher	Institute of Physics (IOP)
quelle	IOP Conference Series: Materials Science and Engineering
relation	http://iopscience.iop.org/1757-899X/389/1/012025
search_space	articles
shingle_author_1	J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng
shingle_author_2	J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng
shingle_author_3	J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng
shingle_author_4	J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng
shingle_catch_all_1	Degassing of Pure Copper Melt by Ultrasonic Cavitation The effect of high intensity ultrasonic vibration (UV) on degassing of pure copper has been studied in this paper. The methods of reduced pressure test (RPT) and direct hydrogen and oxygen measurements are used for the evaluation of degassing efficiency on hydrogen and oxygen concentrations. The results showed that high intensity UV had a significant degassing effect for the commercially pure copper (CP-Cu) melt. With UV, the density index Di was reduced from 11.94 to 1.13%, and the product of hydrogen-oxygen concentration ([ %H ]·[ %O ]) in the liquid Cu was decreased to 1.440×10 −5 from 6.624×10 −5 . It was also found that electric power and ultrasonic treatment time could influence the degassing efficiency. J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng Institute of Physics (IOP) 1757-8981 17578981 1757-899X 1757899X
shingle_catch_all_2	Degassing of Pure Copper Melt by Ultrasonic Cavitation The effect of high intensity ultrasonic vibration (UV) on degassing of pure copper has been studied in this paper. The methods of reduced pressure test (RPT) and direct hydrogen and oxygen measurements are used for the evaluation of degassing efficiency on hydrogen and oxygen concentrations. The results showed that high intensity UV had a significant degassing effect for the commercially pure copper (CP-Cu) melt. With UV, the density index Di was reduced from 11.94 to 1.13%, and the product of hydrogen-oxygen concentration ([ %H ]·[ %O ]) in the liquid Cu was decreased to 1.440×10 −5 from 6.624×10 −5 . It was also found that electric power and ultrasonic treatment time could influence the degassing efficiency. J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng Institute of Physics (IOP) 1757-8981 17578981 1757-899X 1757899X
shingle_catch_all_3	Degassing of Pure Copper Melt by Ultrasonic Cavitation The effect of high intensity ultrasonic vibration (UV) on degassing of pure copper has been studied in this paper. The methods of reduced pressure test (RPT) and direct hydrogen and oxygen measurements are used for the evaluation of degassing efficiency on hydrogen and oxygen concentrations. The results showed that high intensity UV had a significant degassing effect for the commercially pure copper (CP-Cu) melt. With UV, the density index Di was reduced from 11.94 to 1.13%, and the product of hydrogen-oxygen concentration ([ %H ]·[ %O ]) in the liquid Cu was decreased to 1.440×10 −5 from 6.624×10 −5 . It was also found that electric power and ultrasonic treatment time could influence the degassing efficiency. J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng Institute of Physics (IOP) 1757-8981 17578981 1757-899X 1757899X
shingle_catch_all_4	Degassing of Pure Copper Melt by Ultrasonic Cavitation The effect of high intensity ultrasonic vibration (UV) on degassing of pure copper has been studied in this paper. The methods of reduced pressure test (RPT) and direct hydrogen and oxygen measurements are used for the evaluation of degassing efficiency on hydrogen and oxygen concentrations. The results showed that high intensity UV had a significant degassing effect for the commercially pure copper (CP-Cu) melt. With UV, the density index Di was reduced from 11.94 to 1.13%, and the product of hydrogen-oxygen concentration ([ %H ]·[ %O ]) in the liquid Cu was decreased to 1.440×10 −5 from 6.624×10 −5 . It was also found that electric power and ultrasonic treatment time could influence the degassing efficiency. J W Li, X Ma, L L Yang, Y L Teng, F Li and L H Meng Institute of Physics (IOP) 1757-8981 17578981 1757-899X 1757899X
shingle_title_1	Degassing of Pure Copper Melt by Ultrasonic Cavitation
shingle_title_2	Degassing of Pure Copper Melt by Ultrasonic Cavitation
shingle_title_3	Degassing of Pure Copper Melt by Ultrasonic Cavitation
shingle_title_4	Degassing of Pure Copper Melt by Ultrasonic Cavitation
timestamp	2025-07-31T23:46:02.171Z
titel	Degassing of Pure Copper Melt by Ultrasonic Cavitation
titel_suche	Degassing of Pure Copper Melt by Ultrasonic Cavitation
topic	ZL
uid	ipn_articles_6306798