Effect of high intensity conditioning on aggregate size of fine sphalerite

High intensity conditioning（HIC） was used as a model to study the fundamental of fine sulphide particle flotation. The effect of impeller design, mechanical energy input, and agitation speed on aggregate size of fine sphalerite was tested. The aggregate size of fine sphalerite was measured with the...

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Published in	Transactions of Nonferrous Metals Society of China Vol. 18; no. 2; pp. 438 - 443
Main Author	孙伟谢泽军胡岳华邓美姣易峦何国勇
Format	Journal Article
Language	English
Published	Elsevier Ltd 01.04.2008 School of Mineral Processing and Bioengineering, Central South University, Changsha 410083, China
Subjects	agitation speed fine particle flotation high intensity conditioning image analysis impeller design mechanical energy input sphalerite 图象分析技术计算方法选矿技术闪锌矿 sphalerite fine particle flotation high intensity conditioning agitation speed impeller design image analysis mechanical energy input
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ISSN	1003-6326
DOI	10.1016/S1003-6326(08)60077-1

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Abstract	High intensity conditioning（HIC） was used as a model to study the fundamental of fine sulphide particle flotation. The effect of impeller design, mechanical energy input, and agitation speed on aggregate size of fine sphalerite was tested. The aggregate size of fine sphalerite was measured with the Malvern Hydro 2000 Mastersizer. The results show that the size of aggregates of sphalerite particles ground for 3 min can be enlarged significantly with the activator and collector addition in HIC using the high energy impeller. The improved particle aggregation by using the high energy impeller is not directly related to a higher energy input into the system. With the same energy input into HIC, the aggregate size obtained with the high energy impeller is much coarser than that obtained with the low energy impeller. With the new impeller in HIC, the sphalerite aggregate size decreases with increasing agitation speed from 700 to 2 500 r/min. However, the recovery does not decrease until the agitation speed reaches 2 500 r/min.
AbstractList	TG1; High intensity conditioning(HIC) was used as a model to study the fundamental of fine sulphide particle flotation. The effect of impeller design, mechanical energy input, and agitation speed on aggregate size of fine sphalerite was tested. The aggregate size of fine sphalerite was measured with the Malvern Hydro 2000 Mastersizer. The results show that the size of aggregates of sphalerite particles ground for 3 min can be enlarged significantly with the activator and collector addition in HIC using the high energy impeller. The improved particle aggregation by using the high energy impeller is not directly related to a higher energy input into the system. With the same energy input into HIC, the aggregate size obtained with the high energy impeller is much coarser than that obtained with the low energy impeller. With the new impeller in HIC, the sphalerite aggregate size decreases with increasing agitation speed from 700 to 2 500 r/min. However, the recovery does not decrease until the agitation speed reaches 2 500 r/min. High intensity conditioning(HIC) was used as a model to study the fundamental of fine sulphide particle flotation. The effect of impeller design, mechanical energy input, and agitation speed on aggregate size of fine sphalerite was tested. The aggregate size of fine sphalerite was measured with the Malvern Hydro 2000 Mastersizer. The results show that the size of aggregates of sphalerite particles ground for 3 min can be enlarged significantly with the activator and collector addition in HIC using the high energy impeller. The improved particle aggregation by using the high energy impeller is not directly related to a higher energy input into the system. With the same energy input into HIC, the aggregate size obtained with the high energy impeller is much coarser than that obtained with the low energy impeller. With the new impeller in HIC, the sphalerite aggregate size decreases with increasing agitation speed from 700 to 2 500 r/min. However, the recovery does not decrease until the agitation speed reaches 2 500 r/min. High intensity conditioning（HIC） was used as a model to study the fundamental of fine sulphide particle flotation. The effect of impeller design, mechanical energy input, and agitation speed on aggregate size of fine sphalerite was tested. The aggregate size of fine sphalerite was measured with the Malvern Hydro 2000 Mastersizer. The results show that the size of aggregates of sphalerite particles ground for 3 min can be enlarged significantly with the activator and collector addition in HIC using the high energy impeller. The improved particle aggregation by using the high energy impeller is not directly related to a higher energy input into the system. With the same energy input into HIC, the aggregate size obtained with the high energy impeller is much coarser than that obtained with the low energy impeller. With the new impeller in HIC, the sphalerite aggregate size decreases with increasing agitation speed from 700 to 2 500 r/min. However, the recovery does not decrease until the agitation speed reaches 2 500 r/min.
Author	孙伟谢泽军胡岳华邓美姣易峦何国勇
AuthorAffiliation	School of Mineral Processing and Bioengineering, Central South University, Changsha 410083, China
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Cites_doi	10.1016/0892-6875(94)90145-7 10.1016/0892-6875(89)90038-1 10.1016/0301-7516(92)90044-W 10.1016/S0892-6875(96)00131-8 10.1016/0892-6875(96)00038-6 10.1016/0301-7516(80)90027-7 10.1016/0301-7516(77)90003-5 10.1016/0301-7516(81)90019-3 10.1016/0021-9797(75)90234-9 10.1016/0892-6875(91)90032-Q 10.1016/B978-0-08-037283-9.50020-2 10.1016/S0301-7516(97)00026-4
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Snippet	High intensity conditioning（HIC） was used as a model to study the fundamental of fine sulphide particle flotation. The effect of impeller design, mechanical... High intensity conditioning(HIC) was used as a model to study the fundamental of fine sulphide particle flotation. The effect of impeller design, mechanical... TG1; High intensity conditioning(HIC) was used as a model to study the fundamental of fine sulphide particle flotation. The effect of impeller design,...
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SubjectTerms	agitation speed fine particle flotation high intensity conditioning image analysis impeller design mechanical energy input sphalerite 图象分析技术计算方法选矿技术闪锌矿
Title	Effect of high intensity conditioning on aggregate size of fine sphalerite
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