ARBOLITCONCRETE ON SILICATESODIUM COMPOSITE BINDER AND SCRAPS OF VINE

Aim.The results of experimental studies produce siliсatеsodium composite binder of calcareous stone sawing waste, anhydrous sodium silicate, and based on them wood concrete using as an organic filler vine cuttings for the production of heat-insulating, heat-insulating, structural and structural wall material.

Methods.The main technological operations of the developed arbalitconcrete are given : preparation of a composite binder; production of organic filler from the vine; preparation of arbolit concrete mass; formation of arbolit concrete mass; low-temperature treatment (drying).

Results. It is found that the composite binder derived from waste stone sawing and anhydrous sodium silicate at their joint fine grinding (Ssp = 3000 cm2 / g), acquires binding properties and with the appropriate seal and heat treatment hardens and gains strength characteristics sufficient for making arbolitconcrete using crushed vine.

Conclusion. It was determined that arbolitobeton obtained on the basis of the crushed vine and silikatnatrievogo composite binder strength exceeds arbolitobetona from other types of binders and organic fillers of vegetable origin.

1. Salebuy S. Aerated arbolit at a local agricultural waste in the Republic of Chad. Privolzhskij nauchnyj zhurnal [Privolzhsky scientific journal]. 2011, no. 4, pp. 79 – 85.

2. Korobov G., Burova I.V. The method of calculation performance and power consumption of the chipper for bulk materials. Simferopol: NAPCS. 2005, vol.10, pp.10-30. (In Russian)

3. Lavrinov P.G. Utilization of industrial waste of enterprises of the Crimea. Simferopol: Business-Inform. 2005, 440p. (In Russian)

4. Melnikova L.V. Technology of composite materials made of wood. Moscow, 2002, 234 p. (In Russian)

5. Guide for the design and manufacturing of products from arbolita. Moscow: Stroiizdat, 1974, 88p. (In Russian)

6. Nanazashvili I.H. Building materials from wood-cement compositions. Leningrad, 1990. (In Russian)

7. Petri B.N. Development of a method and the basics of production technology of plate plastics from crushed vines without the addition of binders. Ural'skij lesotehnicheskij institut. [Ural Forestry Institute], Sverdlovsk, 1977, 184 p.(In Russian)

8. Stojanov V.V. Localitie materials and designs. Izdatel'stvo «Gorod masterov» [Publisher "the City of masters"]. Odessa. 2001, 134 p. (In Russian)

9. Stojanov V.V., Chernen'kij I.V., Mazurik V.I., Jahontova N.E. etc. Experimental investigation of the deformability of the wall panels with insulation from Rosalita, Izvestija vuzov.[Proceedings of the universities. Building and architecture]. 1986, no.5. (In Russian)

10. Toturbiev B.D. Building materials for silicate-sodium compositions based. Moscow: Stroyizdat, 1988, 208p. (In Russian)

11. Toturbiev B.D., Kerimov G.K. Cement-free refractory concretes on the basis of natural and technogenic raw materials. Akademija nauk SSSR. Dagestanskij filial. Institut geologii. [Academy of Sciences of the USSR, Dagestan branch. Geology Institute]. A collection of articles, Makhachkala. 1987, vol.36, 175 p. (In Russian)

12. Uderbayev S.S., Karibaev E.K, Kurmanaeva J.M. Study of adhesion of rice husk with zolotsementnymi cementitious mixtures. Molodoj uchenyj [Young scientist]. 2014, no.12, pp.113-114. (In Russian)

13. Shcherbakov A.S. The technology of composite wood materials: Textbook for high schools. Moscow: Ecology. 1992, 192 p. (In Russian)

14. Krutov P.I., Nanazashvili I.X., Sklizkov N.I., Savin V.I. Handbook of manufacturing and use arbolita. Moscow:Stroiizdat, 1987, 208 p. (In Russian)

15. Uderbayev S.S. Technology arbolita with a binder, activated mechano-electropolarization way: author. Diss. kand. tech. Sciences: 05.23.05. Kyzylorda, 2000, 18p. (In Russian)

16. Asdrubali F., D’Alessandro F., Schiavoni S.A Review of unconventional sustainable building insulation materials. Sustainable Materials and Technologies. 2015; 4:1–17.

17. Jelle B.P. Traditional, state-of-the-art and future thermal building insulation materials and solutions: properties, requirements and possibilities. Energy and Buildings. 2011. 43:2549–2563.

18. Papadopoulos A.M., Giama E. Environmental performance evaluation of thermal insulation materials and its impact on the building. Building and Environment. 2007; 42:2178–2187.

19. Al-Homoud M.S. Performance characteristics and practical applications of common building thermal insulation materials. Building and Environment. 2005. 40:353–366.

20. Korjenic A., Petranek V., Zach J., Hroudova J. Development and performance evaluation of natural thermal-insulation materials composed of renewable resources. Energy and Buildings. 2011. 43:2518–2523.

21. Papadopoulos A.M.: State of the art in thermal insulation materials and aims for future developments. Energy and Buildings. 2005. 37:77–86.