Development of a laboratory scale procedure for predicting throughput of high pressure grinding rolls

The throughput capability of a high pressure grinding roll (HPGR), a critical process parameter, has been found to heavily depend on the sample type being processed. Existing HPGR test methods require the use of pilot machines and large sample quantities to assess the throughput characteristics of a...

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Main Author: Nadolski, Stefan
Language:English
Published: University of British Columbia 2012
Online Access:http://hdl.handle.net/2429/42095
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spelling ndltd-UBC-oai-circle.library.ubc.ca-2429-420952018-01-05T17:25:44Z Development of a laboratory scale procedure for predicting throughput of high pressure grinding rolls Nadolski, Stefan The throughput capability of a high pressure grinding roll (HPGR), a critical process parameter, has been found to heavily depend on the sample type being processed. Existing HPGR test methods require the use of pilot machines and large sample quantities to assess the throughput characteristics of a certain ore type. Addressing the need for a laboratory scale HPGR test, a laboratory procedure was proposed to assess the throughput capability of mineral samples. Existing procedures were adopted from the fields of terramechanics and soil mechanics, and used as a basis for predictive HPGR throughput models. The applicability of the proposed tests was assessed through the comparison of predicted throughput with observed values from pilot HPGR testing. Results showed that outcomes of the proposed laboratory scale tests were statistically significant when used for the prediction of HPGR throughput. Primarily, the frictional properties of feed samples, as characterized by a direct shear box test, were found to be of particular significance. An approach to modelling the pressure profile which occurs on the HPGR roller surface was also proposed for potential use in a force-based model. Based on the results, an approach to HPGR testing requiring a reduced amount of sample was presented. Further work on characterizing the frictional properties of mineral samples was recommended. Analysis of HPGR outcomes indicated that strong relationships exist between power, throughput and roll gap, hence holistic approaches to HPGR modelling may be most appropriate for future predictive models. Applied Science, Faculty of Mining Engineering, Keevil Institute of Graduate 2012-04-19T17:36:32Z 2012-04-19T17:36:32Z 2012 2012-05 Text Thesis/Dissertation http://hdl.handle.net/2429/42095 eng Attribution-NonCommercial-NoDerivs 3.0 Unported http://creativecommons.org/licenses/by-nc-nd/3.0/ University of British Columbia
collection NDLTD
language English
sources NDLTD
description The throughput capability of a high pressure grinding roll (HPGR), a critical process parameter, has been found to heavily depend on the sample type being processed. Existing HPGR test methods require the use of pilot machines and large sample quantities to assess the throughput characteristics of a certain ore type. Addressing the need for a laboratory scale HPGR test, a laboratory procedure was proposed to assess the throughput capability of mineral samples. Existing procedures were adopted from the fields of terramechanics and soil mechanics, and used as a basis for predictive HPGR throughput models. The applicability of the proposed tests was assessed through the comparison of predicted throughput with observed values from pilot HPGR testing. Results showed that outcomes of the proposed laboratory scale tests were statistically significant when used for the prediction of HPGR throughput. Primarily, the frictional properties of feed samples, as characterized by a direct shear box test, were found to be of particular significance. An approach to modelling the pressure profile which occurs on the HPGR roller surface was also proposed for potential use in a force-based model. Based on the results, an approach to HPGR testing requiring a reduced amount of sample was presented. Further work on characterizing the frictional properties of mineral samples was recommended. Analysis of HPGR outcomes indicated that strong relationships exist between power, throughput and roll gap, hence holistic approaches to HPGR modelling may be most appropriate for future predictive models. === Applied Science, Faculty of === Mining Engineering, Keevil Institute of === Graduate
author Nadolski, Stefan
spellingShingle Nadolski, Stefan
Development of a laboratory scale procedure for predicting throughput of high pressure grinding rolls
author_facet Nadolski, Stefan
author_sort Nadolski, Stefan
title Development of a laboratory scale procedure for predicting throughput of high pressure grinding rolls
title_short Development of a laboratory scale procedure for predicting throughput of high pressure grinding rolls
title_full Development of a laboratory scale procedure for predicting throughput of high pressure grinding rolls
title_fullStr Development of a laboratory scale procedure for predicting throughput of high pressure grinding rolls
title_full_unstemmed Development of a laboratory scale procedure for predicting throughput of high pressure grinding rolls
title_sort development of a laboratory scale procedure for predicting throughput of high pressure grinding rolls
publisher University of British Columbia
publishDate 2012
url http://hdl.handle.net/2429/42095
work_keys_str_mv AT nadolskistefan developmentofalaboratoryscaleprocedureforpredictingthroughputofhighpressuregrindingrolls
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