Details

Title

Application of the Triboelectric Method for the Ongoing Assessment of the Quality of Reclaim in Mechanical Reclaimers

Journal title

Archives of Foundry Engineering

Yearbook

2022

Volume

vol. 22

Issue

No 2

Authors

Affiliation

Dańko, R. : AGH University of Science and Technology, Department of Foundry, ul. Reymonta 23, 30-059 Kraków, Poland ; Pietrzak, A. : AGH University of Science and Technology, Department of Foundry, ul. Reymonta 23, 30-059 Kraków, Poland ; Gruszka, D. : AGH University of Science and Technology, Department of Foundry, ul. Reymonta 23, 30-059 Kraków, Poland

Keywords

Reclaim ; Reclamation process ; Regeneration ; Foundry engineering ; Phenol resin ; Moulding sand

Divisions of PAS

Nauki Techniczne

Coverage

63-70

Publisher

The Katowice Branch of the Polish Academy of Sciences

Bibliography

[1] Boenisch, D. (1991, March). Reclamation of spent sands containing bentonite. Guidelines for an economical leading to minimized waste. Giesserei 77, nr 19, 1990. In and AFS International Sand Reclamation Conference, Conference Proceedings, Novi/MI (p. 211).
[2] Dańko, J., Dańko, R., Łucarz, M. (2007). Processes and devices for the matrix regeneration of spent molding sands. Akapit. 291. (in Polish).
[3] Dańko, R. (2007). Development of energetic model for dry mechanical reclamation process of used foundry sands. International Journal of Cast Metals Research. 20(4), 228-232.
[4] Dańko, R. (2012). Strength model of self-setting moulding sands with synthetic resins in an aspect of the of the integrated matrix recycling process. Gliwice: Archives of Foundry Engineering.
[5] Łucarz, M. & Dereń, M. (2017). Conditions of thermal reclamation process realization on a sample of spent moulding sand from an aluminum alloy foundry plant. Archives of Foundry Engineering. 17(2), 197-201.
[6] Leidel, D. S. (1993). Low temperature sand reclamation for dramatically improved quality and reduced cost. Transactions-Japan Foundrymen’s Society. 12, 1-1.
[7] Lewandowski, L. (1997). Materials for foundry molds. Akapit. (in Polish).
[8] Siddique, R., Kaur, G. & Rajor, A. (2010). Waste foundry sand and its leachate characteristics. Resources, Conservation and Recycling. 54(12), 1027-1036.
[9] Svidro, J.T. (2010). The effect of sulphur content in chemical bonded sand moulds on the mechanism of penetration. International Foundry Research. 62(4), 32-41.
[10] Polzin, H., Nitsch, U., Tilch, W. & Flemming, E. (1997). Regenerierung anorganisch gebundener Altsande mit einer mechanisch arbeitender Pilotanlage. Giesserei-Praxis. 23, 500-507.
[11] Vijayakumar, S., Srinivasan, M.V. & Govindaraju, M. (2021). Reduction of waste in furan molding process from cast iron foundry. Materials Today: Proceedings. 46, 5032-5035.
[12] Wang, J.N. & Fan, Z.T. (2010). 'Freezing–mechanical'reclamation of used sodium silicate sands. International Journal of Cast Metals Research. 23(5), 257-263.
[13] Wang, L.C., Jiang, W.M., Gong, X.L., Liu, F.C. & Fan, Z.T. (2019). Recycling water glass from wet reclamation sewage of waste sodium silicate-bonded sand. China Foundry. 16(3), 198-203.
[14] Cruz, N., Briens, C. & Berruti, F. (2009). Green sand reclamation using a fluidized bed with an attrition nozzle. Resources, Conservation and Recycling. 54(1), 45-52.
[15] Dungan, R.S., Huwe, J. & Chaney, R.L. (2009). Concentrations of PCDD/PCDFs and PCBs in spent foundry sands. Chemosphere. 75(9), 1232-1235.
[16] Zitian, F., Fuchu, L., Wei, L. & Guona, L. (2014). A new low-cost method of reclaiming mixed foundry waste sand based on wet-thermal composite reclamation. China Foundry. 11(5).
[17] Ghormley, S., Williams, R. & Dvorak, B. (2020). Foundry Sand Source Reduction Options: Life Cycle Assessment Evaluation. Environments. 7(9), 66.
[18] Holtzer, M. & Kmita, A. (2020). Mold and Core Sands in Metalcasting: Chemistry and Ecology. Sustainable Development. Springer, Cham.

Date

2022.05.16

Type

Article

Identifier

DOI: 10.24425/afe.2022.140226
×