Your search keyword '"10092390 - Beukes, Johan Paul"' showing total 11 results

1. SEM image processing as an alternative method to determine chromite pre-reduction

Author

10092390 - Beukes, Johan Paul, 20164200 - Bunt, John Reginald, 10710361 - Van Zyl, Pieter Gideon, 10202927 - Jordaan, Anine, 10059059 - Tiedt, Louwrens Rasmus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, 20049544 - Venter, Andrew Derick, 21173508 - Mohale, Given Terrance Mpho, Mohale, G.T.M., Beukes, J.P., Kleynhans, E.L.J., Van Zyl, P.G., Bunt, J.R., Tiedt, L.R., Venter, A.D., Jordaan, A., 10092390 - Beukes, Johan Paul, 20164200 - Bunt, John Reginald, 10710361 - Van Zyl, Pieter Gideon, 10202927 - Jordaan, Anine, 10059059 - Tiedt, Louwrens Rasmus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, 20049544 - Venter, Andrew Derick, 21173508 - Mohale, Given Terrance Mpho, Mohale, G.T.M., Beukes, J.P., Kleynhans, E.L.J., Van Zyl, P.G., Bunt, J.R., Tiedt, L.R., Venter, A.D., and Jordaan, A.

Abstract

The specific energy consumption (SEC) of the pelletized chromite prereduction process is the lowest of all FeCr production processes commercially applied. This process also eliminates the use of chromite ore fines that could result in furnace blow-outs or so-called bed turnovers, yields a high chromium (Cr) recovery, and can produce a low-sulphur (S) and -silicon (Si) FeCr. However, this process requires extensive operational control due to the variation in pre-reduction levels and carbon contents of the pre-reduced, pelletized furnace feed material. The wet chemical analytical method currently applied for the determination of chromite prereduction is time-consuming. In this paper, the development of an alternative method consisting of scanning electron microscopy (SEM) micrograph image processing is presented. A strong linear correlation (R2 = 0.919) between chromite pre-reduction (%), as determined by wet chemical analysis, and the new method was obtained. Further development could result in the industrial application of the method, which could contribute significantly to the metallurgical stability and enhanced process control of the pelletized chromite pre-reduction process

Published

2017

2. SEM image processing as an alternative method to determine chromite pre-reduction

Author

10092390 - Beukes, Johan Paul, 20164200 - Bunt, John Reginald, 10710361 - Van Zyl, Pieter Gideon, 10202927 - Jordaan, Anine, 10059059 - Tiedt, Louwrens Rasmus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, 20049544 - Venter, Andrew Derick, 21173508 - Mohale, Given Terrance Mpho, Mohale, G.T.M., Beukes, J.P., Kleynhans, E.L.J., Van Zyl, P.G., Bunt, J.R., Tiedt, L.R., Venter, A.D., Jordaan, A., 10092390 - Beukes, Johan Paul, 20164200 - Bunt, John Reginald, 10710361 - Van Zyl, Pieter Gideon, 10202927 - Jordaan, Anine, 10059059 - Tiedt, Louwrens Rasmus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, 20049544 - Venter, Andrew Derick, 21173508 - Mohale, Given Terrance Mpho, Mohale, G.T.M., Beukes, J.P., Kleynhans, E.L.J., Van Zyl, P.G., Bunt, J.R., Tiedt, L.R., Venter, A.D., and Jordaan, A.

Abstract

The specific energy consumption (SEC) of the pelletized chromite prereduction process is the lowest of all FeCr production processes commercially applied. This process also eliminates the use of chromite ore fines that could result in furnace blow-outs or so-called bed turnovers, yields a high chromium (Cr) recovery, and can produce a low-sulphur (S) and -silicon (Si) FeCr. However, this process requires extensive operational control due to the variation in pre-reduction levels and carbon contents of the pre-reduced, pelletized furnace feed material. The wet chemical analytical method currently applied for the determination of chromite prereduction is time-consuming. In this paper, the development of an alternative method consisting of scanning electron microscopy (SEM) micrograph image processing is presented. A strong linear correlation (R2 = 0.919) between chromite pre-reduction (%), as determined by wet chemical analysis, and the new method was obtained. Further development could result in the industrial application of the method, which could contribute significantly to the metallurgical stability and enhanced process control of the pelletized chromite pre-reduction process

Published

2017

3. Techno-economic feasibility of a preoxidation process to enhance prereduction of chromite

Author

10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10183906 - Fick, Johan Izak Jacobus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, Kleynhans, E.L.J., Beukes, J.P., Van Zyl, P.G., Fick, J.I.J., 10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10183906 - Fick, Johan Izak Jacobus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, Kleynhans, E.L.J., Beukes, J.P., Van Zyl, P.G., and Fick, J.I.J.

Abstract

Ferrochrome (FeCr) is vital for the production of stainless and high-alloy ferritic steels, since it is the only source of new Cr units. FeCr production is an energy-intensive process. The pelletized chromite prereduction process is most likely the FeCr production process with the lowest specific electricity consumption (SEC), i.e. MWh/t, currently in operation. However, due to increases in costs, efficiency, and environmental pressures, FeCr producers are attempting to lower their overall energy consumption even further. Recently, it was proven that pre-oxidation of chromite ore prior to pelletization and prereduction significantly decreases both the SEC and lumpy carbonaceous reductants required for smelting. This paper presents the first attempt at conceptualizing the technoeconomic feasibility of integrating chromite pre-oxidation into the prereduction process. Financial modelling yielded a net present value (NPV) at a 10% discount rate of approximately R900 million and an internal rate of return (IRR) of approximatelyy 30.5% after tax, suggesting that the implementation of pre-oxidation prior to pellet prereduction may be financially viable. Sensitivity analysis indicated that the parameter with the greatest influence on project NPV and IRR is the level of prereduction. This indicates that the relationship between maintaining the optimum pre-oxidation temperature and the degree of prereduction is critical for maximium process efficiency

Published

2017

4. Techno-economic feasibility of a preoxidation process to enhance prereduction of chromite

Author

10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10183906 - Fick, Johan Izak Jacobus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, Kleynhans, E.L.J., Beukes, J.P., Van Zyl, P.G., Fick, J.I.J., 10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10183906 - Fick, Johan Izak Jacobus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, Kleynhans, E.L.J., Beukes, J.P., Van Zyl, P.G., and Fick, J.I.J.

Abstract

Ferrochrome (FeCr) is vital for the production of stainless and high-alloy ferritic steels, since it is the only source of new Cr units. FeCr production is an energy-intensive process. The pelletized chromite prereduction process is most likely the FeCr production process with the lowest specific electricity consumption (SEC), i.e. MWh/t, currently in operation. However, due to increases in costs, efficiency, and environmental pressures, FeCr producers are attempting to lower their overall energy consumption even further. Recently, it was proven that pre-oxidation of chromite ore prior to pelletization and prereduction significantly decreases both the SEC and lumpy carbonaceous reductants required for smelting. This paper presents the first attempt at conceptualizing the technoeconomic feasibility of integrating chromite pre-oxidation into the prereduction process. Financial modelling yielded a net present value (NPV) at a 10% discount rate of approximately R900 million and an internal rate of return (IRR) of approximatelyy 30.5% after tax, suggesting that the implementation of pre-oxidation prior to pellet prereduction may be financially viable. Sensitivity analysis indicated that the parameter with the greatest influence on project NPV and IRR is the level of prereduction. This indicates that the relationship between maintaining the optimum pre-oxidation temperature and the degree of prereduction is critical for maximium process efficiency

Published

2017

5. Techno-economic feasibility of a preoxidation process to enhance prereduction of chromite

Author

10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10183906 - Fick, Johan Izak Jacobus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, Kleynhans, E.L.J., Beukes, J.P., Van Zyl, P.G., Fick, J.I.J., 10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10183906 - Fick, Johan Izak Jacobus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, Kleynhans, E.L.J., Beukes, J.P., Van Zyl, P.G., and Fick, J.I.J.

Abstract

Ferrochrome (FeCr) is vital for the production of stainless and high-alloy ferritic steels, since it is the only source of new Cr units. FeCr production is an energy-intensive process. The pelletized chromite prereduction process is most likely the FeCr production process with the lowest specific electricity consumption (SEC), i.e. MWh/t, currently in operation. However, due to increases in costs, efficiency, and environmental pressures, FeCr producers are attempting to lower their overall energy consumption even further. Recently, it was proven that pre-oxidation of chromite ore prior to pelletization and prereduction significantly decreases both the SEC and lumpy carbonaceous reductants required for smelting. This paper presents the first attempt at conceptualizing the technoeconomic feasibility of integrating chromite pre-oxidation into the prereduction process. Financial modelling yielded a net present value (NPV) at a 10% discount rate of approximately R900 million and an internal rate of return (IRR) of approximatelyy 30.5% after tax, suggesting that the implementation of pre-oxidation prior to pellet prereduction may be financially viable. Sensitivity analysis indicated that the parameter with the greatest influence on project NPV and IRR is the level of prereduction. This indicates that the relationship between maintaining the optimum pre-oxidation temperature and the degree of prereduction is critical for maximium process efficiency

Published

2017

6. SEM image processing as an alternative method to determine chromite pre-reduction

Author

10092390 - Beukes, Johan Paul, 20164200 - Bunt, John Reginald, 10710361 - Van Zyl, Pieter Gideon, 10202927 - Jordaan, Anine, 10059059 - Tiedt, Louwrens Rasmus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, 20049544 - Venter, Andrew Derick, 21173508 - Mohale, Given Terrance Mpho, Mohale, G.T.M., Beukes, J.P., Kleynhans, E.L.J., Van Zyl, P.G., Bunt, J.R., Tiedt, L.R., Venter, A.D., Jordaan, A., 10092390 - Beukes, Johan Paul, 20164200 - Bunt, John Reginald, 10710361 - Van Zyl, Pieter Gideon, 10202927 - Jordaan, Anine, 10059059 - Tiedt, Louwrens Rasmus, 20278241 - Kleynhans, Ernst Lodewyk Johannes, 20049544 - Venter, Andrew Derick, 21173508 - Mohale, Given Terrance Mpho, Mohale, G.T.M., Beukes, J.P., Kleynhans, E.L.J., Van Zyl, P.G., Bunt, J.R., Tiedt, L.R., Venter, A.D., and Jordaan, A.

Abstract

The specific energy consumption (SEC) of the pelletized chromite prereduction process is the lowest of all FeCr production processes commercially applied. This process also eliminates the use of chromite ore fines that could result in furnace blow-outs or so-called bed turnovers, yields a high chromium (Cr) recovery, and can produce a low-sulphur (S) and -silicon (Si) FeCr. However, this process requires extensive operational control due to the variation in pre-reduction levels and carbon contents of the pre-reduced, pelletized furnace feed material. The wet chemical analytical method currently applied for the determination of chromite prereduction is time-consuming. In this paper, the development of an alternative method consisting of scanning electron microscopy (SEM) micrograph image processing is presented. A strong linear correlation (R2 = 0.919) between chromite pre-reduction (%), as determined by wet chemical analysis, and the new method was obtained. Further development could result in the industrial application of the method, which could contribute significantly to the metallurgical stability and enhanced process control of the pelletized chromite pre-reduction process

Published

2017

7. Comparison of physical properties of oxidative sintered pellets produced with UG2 or metallurgicalgrade South African chromite: a case study

Author

10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10192247 - Campbell, Quentin Peter, 10202927 - Jordaan, Anine, Glastonbury, R.I., Beukes, J.P., Van Zyl, P.G., Jordaan, A., Campbell, Q.P., 10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10192247 - Campbell, Quentin Peter, 10202927 - Jordaan, Anine, Glastonbury, R.I., Beukes, J.P., Van Zyl, P.G., Jordaan, A., and Campbell, Q.P.

Abstract

The physical properties of oxidative sintered pellets produced from typical South African UG2 ore are compared with the physical properties of pellets produced with conventional South African metallurgical-grade chromite ore (from the Lower Group 6 or the Middle Group 1 and 2 seams). A statistical evaluation of the cured (sintered) compressive strengths proved that pellets prepared from UG2 ore are likely to have the same, or better, compressive strength than pellets prepared from metallurgical-grade chromite ore. The cured abrasion strength of the UG2 pellets was also superior to that of the metallurgical-grade pellets. Scanning electron microscopy (SEM) backscatter, secondary electron, and elemental X-ray mapping were used to determine the reasons for the general superior strength of the UG2 pellets. The case study UG2 ore also required 13 kWh/t less energy for milling to attain the required particle size distribution prior to pelletization, which can lead to substantial cost savings. Results presented in this paper can be utilized by ferrochromium (FeCr) producers to better quantify the advantages and disadvantages associated with the use of UG2 ore for FeCr production

Published

2015

8. Comparison of physical properties of oxidative sintered pellets produced with UG2 or metallurgicalgrade South African chromite: a case study

Author

10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10192247 - Campbell, Quentin Peter, 10202927 - Jordaan, Anine, Glastonbury, R.I., Beukes, J.P., Van Zyl, P.G., Jordaan, A., Campbell, Q.P., 10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10192247 - Campbell, Quentin Peter, 10202927 - Jordaan, Anine, Glastonbury, R.I., Beukes, J.P., Van Zyl, P.G., Jordaan, A., and Campbell, Q.P.

Abstract

The physical properties of oxidative sintered pellets produced from typical South African UG2 ore are compared with the physical properties of pellets produced with conventional South African metallurgical-grade chromite ore (from the Lower Group 6 or the Middle Group 1 and 2 seams). A statistical evaluation of the cured (sintered) compressive strengths proved that pellets prepared from UG2 ore are likely to have the same, or better, compressive strength than pellets prepared from metallurgical-grade chromite ore. The cured abrasion strength of the UG2 pellets was also superior to that of the metallurgical-grade pellets. Scanning electron microscopy (SEM) backscatter, secondary electron, and elemental X-ray mapping were used to determine the reasons for the general superior strength of the UG2 pellets. The case study UG2 ore also required 13 kWh/t less energy for milling to attain the required particle size distribution prior to pelletization, which can lead to substantial cost savings. Results presented in this paper can be utilized by ferrochromium (FeCr) producers to better quantify the advantages and disadvantages associated with the use of UG2 ore for FeCr production

Published

2015

9. Comparison of physical properties of oxidative sintered pellets produced with UG2 or metallurgicalgrade South African chromite: a case study

Author

10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10192247 - Campbell, Quentin Peter, 10202927 - Jordaan, Anine, Glastonbury, R.I., Beukes, J.P., Van Zyl, P.G., Jordaan, A., Campbell, Q.P., 10092390 - Beukes, Johan Paul, 10710361 - Van Zyl, Pieter Gideon, 10192247 - Campbell, Quentin Peter, 10202927 - Jordaan, Anine, Glastonbury, R.I., Beukes, J.P., Van Zyl, P.G., Jordaan, A., and Campbell, Q.P.

Abstract

The physical properties of oxidative sintered pellets produced from typical South African UG2 ore are compared with the physical properties of pellets produced with conventional South African metallurgical-grade chromite ore (from the Lower Group 6 or the Middle Group 1 and 2 seams). A statistical evaluation of the cured (sintered) compressive strengths proved that pellets prepared from UG2 ore are likely to have the same, or better, compressive strength than pellets prepared from metallurgical-grade chromite ore. The cured abrasion strength of the UG2 pellets was also superior to that of the metallurgical-grade pellets. Scanning electron microscopy (SEM) backscatter, secondary electron, and elemental X-ray mapping were used to determine the reasons for the general superior strength of the UG2 pellets. The case study UG2 ore also required 13 kWh/t less energy for milling to attain the required particle size distribution prior to pelletization, which can lead to substantial cost savings. Results presented in this paper can be utilized by ferrochromium (FeCr) producers to better quantify the advantages and disadvantages associated with the use of UG2 ore for FeCr production

Published

2015

10. Theoretical and practical aspects of Cr(VI) in the South African ferrochrome industry

Author

10710361 - Van Zyl, Pieter Gideon, 10092390 - Beukes, Johan Paul, 22581804 - Dawson, Nicholas Finch, Beukes, J.P., Van Zyl, P.G., Dawson, N.F., 10710361 - Van Zyl, Pieter Gideon, 10092390 - Beukes, Johan Paul, 22581804 - Dawson, Nicholas Finch, Beukes, J.P., Van Zyl, P.G., and Dawson, N.F.

Abstract

The production of ferrochrome alloy from chromium bearing chromite ores is conducted at high temperature under highly reducing conditions. However, albeit completely unintended, it is impossible to completely exclude oxygen from all high temperature process steps, with the corresponding possibility arising for the generation of small amounts of Cr(VI) species. Certain Cr(VI) species are regarded as a carcinogenic, with specifically airborne exposure to these Cr(VI) species being associated with cancer of the respiratory system. With approximately three-quarters of the world’s viable chromite ore reserves located in South Africa, and annual ferrochrome production approaching almost half of total annual global output, aspects of Cr(VI) generation and control are of particular relevance and importance to the local industry, and naturally to the global industry at large. This paper seeks to examine theoretical and practical aspects associated with Cr(VI) generation (based largely on experience within the local South African industry, but considered to be generally encountered in the broader global industry context), together with mitigating measures that can be applied within the context of the production processes. From the discussions it is clear that significant improvements in various Cr(VI)-related aspects have been made by the South African ferrochrome industry. However, it is also evident that several areas of uncertainty still exist, which require further research in order to better quantify risks and enhance the efficacy of mitigating steps

Published

2010

11. Theoretical and practical aspects of Cr(VI) in the South African ferrochrome industry

Author

10710361 - Van Zyl, Pieter Gideon, 10092390 - Beukes, Johan Paul, 22581804 - Dawson, Nicholas Finch, Beukes, J.P., Van Zyl, P.G., Dawson, N.F., 10710361 - Van Zyl, Pieter Gideon, 10092390 - Beukes, Johan Paul, 22581804 - Dawson, Nicholas Finch, Beukes, J.P., Van Zyl, P.G., and Dawson, N.F.

Abstract

The production of ferrochrome alloy from chromium bearing chromite ores is conducted at high temperature under highly reducing conditions. However, albeit completely unintended, it is impossible to completely exclude oxygen from all high temperature process steps, with the corresponding possibility arising for the generation of small amounts of Cr(VI) species. Certain Cr(VI) species are regarded as a carcinogenic, with specifically airborne exposure to these Cr(VI) species being associated with cancer of the respiratory system. With approximately three-quarters of the world’s viable chromite ore reserves located in South Africa, and annual ferrochrome production approaching almost half of total annual global output, aspects of Cr(VI) generation and control are of particular relevance and importance to the local industry, and naturally to the global industry at large. This paper seeks to examine theoretical and practical aspects associated with Cr(VI) generation (based largely on experience within the local South African industry, but considered to be generally encountered in the broader global industry context), together with mitigating measures that can be applied within the context of the production processes. From the discussions it is clear that significant improvements in various Cr(VI)-related aspects have been made by the South African ferrochrome industry. However, it is also evident that several areas of uncertainty still exist, which require further research in order to better quantify risks and enhance the efficacy of mitigating steps

Published

2010