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RECOVERY OF GOLD AND SILVER FROM WASTES GENERATED IN JEWELRY PRODUCTION

Year 2021, Volume: 60 Issue: 1, 51 - 61, 01.03.2021
https://doi.org/10.30797/madencilik.899238

Abstract

In this study, it was aimed to recover metallic values by gravity methods from the floor sweeping
waste with high gold and silver contents, which are produced as a result of various activities in the
jewelry workshops. In addition, the metallic values that remains in the slag phase after thermal
process of the floor sweeping wastes were concentrated by centrifugal separators. As a result
of gravity separation tests in which the floor sweeping waste subjected to shaking table, MGS
(multi gravity separator) and Knelson concentrator, a heavy product (24.2% wt.) was produced
with 638 g/t Au and 6227 g/t Ag grades and the metal recovery rates were calculated as 84.4%
and 82.2%, respectively. The slag was first ground below 100 μm and then fed to the centrifugal
separators in order to obtain fine size gold and silver particles that were trapped in the glassy
phase. As a result of enrichment studies with Knelson concentrator, a concentrate (13.8% wt.)
was obtained with 30 g/t Au and 52 g/t Ag grades, and the metal recoveries were found as 64.6%
and 44.4%, respectively.

References

  • Akcil, A., Erust, C., Gahan, S., Ozgun, M., Sahin, M., Tuncuk, A., 2015. Precious Metal Recovery from Waste Printed Circuit Boards Using Cyanide and Non-Cyanide Lixiviants–A Review. Waste Management, 45, 258–271. doi:10.1016/j.wasman.2015.01.017.
  • Ammen, C. W., 1997. Recovery and Refining of Precious Metals. 2nd ed. New York: Chapman & Hall.
  • Aydın, Ş. B., Gül, A., 2020. Environmentally Friendly Process Instead of Cyanide Leaching on Recycling of Gold and Silver from Jewellery Scraps and Wastes. Waste Management & Research, https://doi. org/10.1177/073424 2X20931947.
  • Burat, F., Özer, M., 2018. Physical Separation Route for Printed Circuit Boards (PCBs). Physicochemical Problems of Mineral Processing, 54, (2), 554-566.
  • Burat, F., Baştürkcü, H., Özer, M., 2019. Gold&silver Recovery from Jewelry Waste with Combination of Physical and Physicochemical Methods. Waste Management, 89, 10-20, (2019).
  • Burat, F., Demirağ, A., Şafak, M. C., 2020. Recovery of Noble Metals from Floor Sweeping Jewelry Waste by Flotation‑Cyanide Leaching. Journal of Material Cycles and Waste Management, 22, 907-915.
  • Canda, L., Heput, T., Ardelean, E., 2016. Methods for Recovering Precious Metal from Industrial Waste. IOP Conf. Series: Materials Science and Engineering. 106. Chmielewski, A. G., Urbanski, T. S., Migdal, W., 1997.
  • Separation Technologies for Metals Recovery from Industrial Wastes. Hydrometallurgy, 45, 333-344.
  • Corti, C. W., 1997a. Recovery and Recycling In Gold Jewellery Production. Gold Technology, 21, 11.
  • Corti, C. W., 1997b. In-House Gold Refining: The Options. Gold Technology, 21, 31.
  • Corti, C. W., 2002. Recovery and Refining of Gold Jewellery Scraps and Wastes. The Santa Fe Symposium on Jewellery Manufacturing Technology, 1-20. London.
  • Delfini, M., Manni, A., Massacci, P., 2000. Gold Recovery from Jewellery Waste. Minerals Engineering, 13 (6), 663- 666.
  • Ferrini, M., Manni, A., Massacci, P., 1998. Chemical Analyses by ICP-AES of Jewellery Waste in Italy. In Proc. Biennial International Conference on Chemical Measurement and Monitoring of the Environment. Enviro Analysis 98, Ottawa, 501-506.
  • Garside, M., 2020. Gold Demand Worldwide, https:// www.statista.com/statistics/299609/gold-demand-byindustry- sector-share/. Yayın tarihi 10 Temmuz. Erişim tarihi 26 Temmuz 2020.
  • Houseley K., Apling A. C., Chapman R. J., 1998. Effect of Particle Size and Shape on Recovery of Gold By Use of A Knelson Concentrator. Innovation in Physical Separation Technologies, Richard Mozley Symposium, 65-72.
  • Kaya, M. 2016. Recovery of Metals and Nonmetals from Electronic Waste by Physical and Chemical Recycling Processes. Waste Management, 57, 64–90. doi:10.1016/j.wasman.2016.08.004.
  • Kaspin, S., Mohamad, N., 2015. Investigating the Standard Process of Conventional Gold Refining Process In Kelantan. Malaysia, 2015 International Conference on Sustainable Energy and Environmental Engineering.
  • Loewen, R., 1989. Refining Jeweler’s Wastes. Proceedings, Santa Fe Symposium on Jewelry Manufacturing Technology, 331.
  • Manni, A. İ, Saviano, G., Massacci, P., 2001. Technical Note: Characterization of Gold Particles in Recoverable Waste Matrix. Minerals Engineering, 14 (12), 1679-1684.
  • Mbaya, R. K. K., 2004. Recovery of Noble Metals from Jewellery Wastes, Tshwane University of Technology, Doctorate Thesis.
  • Potgieter, J. H., Potgieter, S. S, Mbaya, R. K. K., Teodorovic, A, 2004. Small-Scale Recovery of Noble Metals from Jewellery Wastes. The Journal of The South African Institute of Mining and Metallurgy, 563-572.
  • Sabah, E, Şapçı, F. O., 2020. Ramat Geri Kazanım Prosesinde Açığa Çıkan Cüruflardan Gravite Ayırması ile Altın Kazanımı. Politeknik Dergisi, doi:10.2339/ politeknik.742859.
  • Spiller D. E., 1983. Gravity Separation of Gold Then and Now, Mining Yearbook, Colorado Mining Association, Colorado.
  • Yazıcı, E. Y., Deveci, H., 2014. Ferric Sulphate Leaching of Metals from Waste Printed Circuit Boards. International Journal of Mineral Processing, 133, 39-45.
  • Wills, B. A. and Napier-Munn, T., 2006. Wills’ Mineral Processing Technology. 7th Edition, Butterworth- Heinemann, Oxford.

KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI

Year 2021, Volume: 60 Issue: 1, 51 - 61, 01.03.2021
https://doi.org/10.30797/madencilik.899238

Abstract

Bu çalışmada, kuyumcu atölyelerindeki çeşitli faaliyetler sonucunda açığa çıkan, yüksek altın ve
gümüş içeriklerine sahip zemin süpürme artıklarından metalik değerlerin gravite yöntemleri ile
geri kazanılması amaçlanmıştır. Ayrıca, bu artıklardaki değerli metalleri kazanmak için uygulanan
ısıl işlemler sonucunda oluşan cüruf içerisinde kalan altın ve gümüşü konsantre etmek amacıyla
santrifüj ayırıcılar kullanılarak zenginleştirme deneyleri yapılmıştır. Yüksek metal içeriklerine
sahip zemin süpürme artığı ile sarsıntılı masa, MGS (multi gravite separator) ve Knelson
konsantratörü kullanılarak yapılan zenginleştirme işlemleri sonucunda, ağırlıkça %24,2 oranında
bir ağır ürün 638 g/t Au ve 6227 g/t Ag içerikleri ile üretilmiş, metal kazanma verimleri ise
sırasıyla %84,4 ve %82,2 olarak bulunmuştur. Cüruf içerisinde ince boyutlarda hapsolmuş altın
ve gümüş’ün kazanılması amacıyla malzeme ilk olarak 100 μm altına öğütülmüş ve daha sonra
santrifujlü ayırıcılara beslenmiştir. Knelson konsantratörü ile yapılan zenginleştime çalışmalarının
sonucunda, ağırlıkça %13,8 oranında bir ağır ürün 30 g/t Au ve 52 g/t Ag içerikleri ile elde edilmiş
olup, metal kazanma verimleri sırasıyla % 64,6 ve % 44,4 olarak bulunmuştur.

References

  • Akcil, A., Erust, C., Gahan, S., Ozgun, M., Sahin, M., Tuncuk, A., 2015. Precious Metal Recovery from Waste Printed Circuit Boards Using Cyanide and Non-Cyanide Lixiviants–A Review. Waste Management, 45, 258–271. doi:10.1016/j.wasman.2015.01.017.
  • Ammen, C. W., 1997. Recovery and Refining of Precious Metals. 2nd ed. New York: Chapman & Hall.
  • Aydın, Ş. B., Gül, A., 2020. Environmentally Friendly Process Instead of Cyanide Leaching on Recycling of Gold and Silver from Jewellery Scraps and Wastes. Waste Management & Research, https://doi. org/10.1177/073424 2X20931947.
  • Burat, F., Özer, M., 2018. Physical Separation Route for Printed Circuit Boards (PCBs). Physicochemical Problems of Mineral Processing, 54, (2), 554-566.
  • Burat, F., Baştürkcü, H., Özer, M., 2019. Gold&silver Recovery from Jewelry Waste with Combination of Physical and Physicochemical Methods. Waste Management, 89, 10-20, (2019).
  • Burat, F., Demirağ, A., Şafak, M. C., 2020. Recovery of Noble Metals from Floor Sweeping Jewelry Waste by Flotation‑Cyanide Leaching. Journal of Material Cycles and Waste Management, 22, 907-915.
  • Canda, L., Heput, T., Ardelean, E., 2016. Methods for Recovering Precious Metal from Industrial Waste. IOP Conf. Series: Materials Science and Engineering. 106. Chmielewski, A. G., Urbanski, T. S., Migdal, W., 1997.
  • Separation Technologies for Metals Recovery from Industrial Wastes. Hydrometallurgy, 45, 333-344.
  • Corti, C. W., 1997a. Recovery and Recycling In Gold Jewellery Production. Gold Technology, 21, 11.
  • Corti, C. W., 1997b. In-House Gold Refining: The Options. Gold Technology, 21, 31.
  • Corti, C. W., 2002. Recovery and Refining of Gold Jewellery Scraps and Wastes. The Santa Fe Symposium on Jewellery Manufacturing Technology, 1-20. London.
  • Delfini, M., Manni, A., Massacci, P., 2000. Gold Recovery from Jewellery Waste. Minerals Engineering, 13 (6), 663- 666.
  • Ferrini, M., Manni, A., Massacci, P., 1998. Chemical Analyses by ICP-AES of Jewellery Waste in Italy. In Proc. Biennial International Conference on Chemical Measurement and Monitoring of the Environment. Enviro Analysis 98, Ottawa, 501-506.
  • Garside, M., 2020. Gold Demand Worldwide, https:// www.statista.com/statistics/299609/gold-demand-byindustry- sector-share/. Yayın tarihi 10 Temmuz. Erişim tarihi 26 Temmuz 2020.
  • Houseley K., Apling A. C., Chapman R. J., 1998. Effect of Particle Size and Shape on Recovery of Gold By Use of A Knelson Concentrator. Innovation in Physical Separation Technologies, Richard Mozley Symposium, 65-72.
  • Kaya, M. 2016. Recovery of Metals and Nonmetals from Electronic Waste by Physical and Chemical Recycling Processes. Waste Management, 57, 64–90. doi:10.1016/j.wasman.2016.08.004.
  • Kaspin, S., Mohamad, N., 2015. Investigating the Standard Process of Conventional Gold Refining Process In Kelantan. Malaysia, 2015 International Conference on Sustainable Energy and Environmental Engineering.
  • Loewen, R., 1989. Refining Jeweler’s Wastes. Proceedings, Santa Fe Symposium on Jewelry Manufacturing Technology, 331.
  • Manni, A. İ, Saviano, G., Massacci, P., 2001. Technical Note: Characterization of Gold Particles in Recoverable Waste Matrix. Minerals Engineering, 14 (12), 1679-1684.
  • Mbaya, R. K. K., 2004. Recovery of Noble Metals from Jewellery Wastes, Tshwane University of Technology, Doctorate Thesis.
  • Potgieter, J. H., Potgieter, S. S, Mbaya, R. K. K., Teodorovic, A, 2004. Small-Scale Recovery of Noble Metals from Jewellery Wastes. The Journal of The South African Institute of Mining and Metallurgy, 563-572.
  • Sabah, E, Şapçı, F. O., 2020. Ramat Geri Kazanım Prosesinde Açığa Çıkan Cüruflardan Gravite Ayırması ile Altın Kazanımı. Politeknik Dergisi, doi:10.2339/ politeknik.742859.
  • Spiller D. E., 1983. Gravity Separation of Gold Then and Now, Mining Yearbook, Colorado Mining Association, Colorado.
  • Yazıcı, E. Y., Deveci, H., 2014. Ferric Sulphate Leaching of Metals from Waste Printed Circuit Boards. International Journal of Mineral Processing, 133, 39-45.
  • Wills, B. A. and Napier-Munn, T., 2006. Wills’ Mineral Processing Technology. 7th Edition, Butterworth- Heinemann, Oxford.
There are 25 citations in total.

Details

Primary Language Turkish
Journal Section Research Article
Authors

Tülin Ulucan This is me 0000-0002-8076-5120

Mustafa Özer This is me 0000-0003-2642-6782

Hüseyin Baştürkcü This is me 0000-0001-7301-9317

Fırat Burat This is me 0000-0001-7051-0063

Publication Date March 1, 2021
Submission Date July 28, 2020
Published in Issue Year 2021 Volume: 60 Issue: 1

Cite

APA Ulucan, T., Özer, M., Baştürkcü, H., Burat, F. (2021). KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI. Bilimsel Madencilik Dergisi, 60(1), 51-61. https://doi.org/10.30797/madencilik.899238
AMA Ulucan T, Özer M, Baştürkcü H, Burat F. KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI. Mining. March 2021;60(1):51-61. doi:10.30797/madencilik.899238
Chicago Ulucan, Tülin, Mustafa Özer, Hüseyin Baştürkcü, and Fırat Burat. “KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI”. Bilimsel Madencilik Dergisi 60, no. 1 (March 2021): 51-61. https://doi.org/10.30797/madencilik.899238.
EndNote Ulucan T, Özer M, Baştürkcü H, Burat F (March 1, 2021) KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI. Bilimsel Madencilik Dergisi 60 1 51–61.
IEEE T. Ulucan, M. Özer, H. Baştürkcü, and F. Burat, “KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI”, Mining, vol. 60, no. 1, pp. 51–61, 2021, doi: 10.30797/madencilik.899238.
ISNAD Ulucan, Tülin et al. “KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI”. Bilimsel Madencilik Dergisi 60/1 (March 2021), 51-61. https://doi.org/10.30797/madencilik.899238.
JAMA Ulucan T, Özer M, Baştürkcü H, Burat F. KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI. Mining. 2021;60:51–61.
MLA Ulucan, Tülin et al. “KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI”. Bilimsel Madencilik Dergisi, vol. 60, no. 1, 2021, pp. 51-61, doi:10.30797/madencilik.899238.
Vancouver Ulucan T, Özer M, Baştürkcü H, Burat F. KUYUMCULUK KÖKENLİ ARTIKLARDAN ALTIN VE GÜMÜŞÜN GERİ KAZANIMI. Mining. 2021;60(1):51-6.

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