Secondary Application of Foam Glass when Producing Foam-Glass-Crystal Slabs

During the operation, overwhelming majority of building materials loses their consumer properties and the completion of the life cycle assumes their location at the polygons of solid communal waste. However, from the point of view of the sustainable development concept, the production of new materials for construction must be based on the renewable raw mate- rials exclusively. Issues of the secondary use of foam glass and foam-glass-crystal slabs for producing new slab glass-crystal materials of cellular structure are considered. It is shown that after the completion of the life cycle, slab foam glass can be processed in foam-glass crushed stone which, in its turn, can be used as a filler when producing new slab foam-glass- crystal materials. It is established that obtained slab products are not structurally differ from foam-glass-crystal slabs produced from the primary materials.

Ya.I. VAYSMAN, Doctor of Sciences (Medicine),
A.A. KETOV, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.);
P.A. KETOV, Engineer-Ecologist

Perm National Research Polytechnic University (29, Komsomolsky Avenue, Perm, 614990, Russian Federation)

1. Telichenko V.I. From the Principles of Sustainable Development to “Green” Technologies. Vestnik MGSU. 2016. No. 3, pp. 5–6. (In Russian). 
2. Benuzh A.A., Kolchigin M.A. Analysis of the Concept of “Green” Construction as a Vehicle to Ensure the Environmental Safety of Construction Activities. Vestnik MGSU. 2012. No. 12, pp. 161–165. (In Russian). 
3. Sieffert Y., Huygen J.M., Daudon D. Sustainable construction with repurposed materials in the context of a civil engineering–architecture collaboration. Journal of Cleaner Production. 2014. No. 67, pp. 125–138. Doi: http://doi.org/10.1016/j.jclepro.2013.12.018. 
4. Raut S.P., Ralegaonkar R.V., Mandavgane S.A. Development of sustainable construction material using industrial and agricultural solid waste: A review of wastecreate bricks. Construction and Building Materials. 2011. No. 25, pp. 4037–4042. Doi: http://doi.org/10.1016/j. conbuildmat.2011.04.038. 
5. Ketov A.A. Prospects of Foam Glass in Housing Construction. Stroitel’nye Materialy [Construction Materials]. 2016. No. 3, pp.79–81. (In Russian). 
6. Puzanov S.I. Features of Materials Using on the Basis of Glass Cullet as Aggregates in Portland Cement Concrete. Stroitel’nye Materialy [Construction Materials]. 2007. No. 7, pp. 12–15. (In Russian). 
7. Vaisman Ya.I., Ketov A.A., Ketov P.A. The Scientific and Technological Aspects of Foam Glass Production. Glass Physics and Chemistry. 2015. Vol. 41. No. 2, pp. 157–162. 
8. Qu Y.-N., Xu J., Su Z.-G., Ma N., Zhang X.-Y., Xi X.-Q., Yang J.-L. Lightweight and high-strength glass foams pre- pared by a novel green spheres hollowing technique. Ceramics International. 2016. Vol. 42. Issue 2, pp. 2370–2377. 
9. Vaisman Ya.I., Ketov A.A., Ketov Yu.A., Molochko R.A. Oxi- dation of Water Vapor in Hydrate Gas-Formation Mechanism in Manufacture of Cellular Glass. Russian Journal of Applied Chemistry. 2015. Vol. 88. No. 3, pp. 382–385. (In Russian). 
10. Vaisman I., Ketov A., Ketov I. Cellular glass obtained from non-powder preforms by foaming with steam. Ceramics International. 2016. Vol. 42, pp. 15261–15268. Doi: 10.1016/j.ceramint.2016.06.165. 
11. Attila Y., Güden M., Taşdemirci A. Foam glass processing using a polishing glass powder residue. Ceramics International. 2013. Vol. 39, pp. 5869–5877. Doi: 10.1016/j.ceramint.2012.12.104