Fly ash in the production of concrete for various purpose and dry construction mixtures

In recent years, the search for and use of alternative binder building materials has become the subject of many studies both in Russia and abroad. This is due to the trend to reduce the harmful effects of the production of building materials and to more rational use of available raw materials. Fly ash, being a waste of the energy industry, accumulated in large volumes in ash dumps throughout Russia, is a promising material for use in the production of cement-containing building materials and products. The article provides a review of scientific literature and patents on the use of fly ash in various types of concrete, as well as in the production of dry building mixtures. On the basis of the review, positive and negative effects from the introduction of fly ash additives on the properties of concrete, ways to increase the efficiency of using the considered waste in the production of building materials were identified. The experimental part of the work presents the results of determining the strength and water resistance of heavy concrete samples with partial replacement of cement with fly ash obtained by burning coal at a new thermal power plant in the Kaliningrad region.

1. Bikbau M.YA., Zharko V.I. Energosberezheniye i ekologiya proizvodstva nanotsementov. O vozmozhnosti snizheniya udel'nykh zatrat topliva i vybrosov gazov pri proizvodstve tsementa [Energy saving and ecology of nanocement production. On the possibility of reducing the specific fuel consumption and gas emissions in the production of cement]. Building materials, equipment, technologies of the XXI century. 2015. No. 7-8 (198-199). Pp. 22-25. (rus)

2. Danakin D.N., Kozhukhova N.I. Razrabotka yacheistykh betonov na osnove zol-unosa [Development of cellular concrete based on fly ash]. VII International Youth Forum “Education. The science. Production”: Conference Proceedings. Belgorod: Belgorod State Technological University named after V.G. Shukhov, 2015. Pp. 554-558. (rus)

3. Volzhenskiy A.B. Mineral'nyye vyazhushchiye veshchestva [Mineral binders]. Moscow: Stroyizdat, 1986. 464 p. (rus)

4. Bozhenov P.I. Tekhnologiya avtoklavnykh materialov [Technology of autoclave materials]. Leningrad: Stroyizdat, 1978. 327 p. (rus)

5. Galibina E.A. Avtoklavnyye stroitel'nyye materialy iz otkhodov TETS [Autoclave building materials from CHP waste]. Leningrad: Stroyizdat. Leningrad. Department, 1986. 128 p. (rus)

6. Kostin V.V. Polucheniye i svoystva gazobetonov, napolnennykh zolami [Obtaining and properties of aerated concrete filled with ash]. Abstract for the degree of Ph.D. M., 1993. (rus)

7. Chernyshov Ye.M. Zakonomernosti razvitiya struktury avtoklavnykh materialov [Patterns of the development of the structure of autoclave materials]. Stroitel'nyye materialy. 1992. No. 11. Pp. 28-31. (rus)

8. Ovcharenko G.I. Zoly ugley KATEKa v stroitel'nykh materialakh [Ashes of KATEK coals in building materials]. Krasnoyarsk: Izd-vo Krasnoyar. Un-ta, 1992. 216 p. (rus)

9. Runova R.F., Plokhiy V.P., Dekhno A.L., Yamenko A.B. Osobennosti strukturoobrazovaniya vyazhushchego na osnove vysokouglerodistykh zol [Peculiarities of structure formation of a binder based on highcarbon ash]. Cement. 1995. No. 3. Pp. 38-41. (rus)

10. Andreyev V.V., Khalin V.A., Politov I.P. Avtoklavnyye materialy na osnove zol TETS [Autoclave materials based on CHP ash]. Moscow: VNIIESM. 1992. No. 9. Pp.23-43. (rus)

11. Kozlova V.K. Osnovnyye napravleniya ispol'zovaniya zol i zoloshlakovykh smesey TETS Sibiri v proizvodstve stroitel'nykh materialov i v stroitel'stve [The main directions of the use of ashes and ash and slag mixtures from Siberian thermal power plants in the production of building materials and in construction]. Izvestiya vuzov. Seriya str-vo i arkhitektura. 1990. No. 10. Pp. 60-63. (rus)

12. Oshchepkov I.A., Khudonosova Z.A. Aktivizatsiya vyazhushchikh svoystv vysokokal'tsiyevykh zolunosa teplovykh elektrostantsiy i perspektiva ekonomii tsementa v stroitel'stve [Activation of binding properties of high-calcium fly ash from thermal power plants and the prospect of saving cement in construction]. Izvestiya vuzov. Seriya str-vo i arkhitektura. 1995. No. 12. Pp. 64-69. (rus)

13. Chen Y., Guan L., Zhu S., Chen W. Foamed concrete containing fly ash: Properties and application to backfilling. Construction and Building Materials. 2021. No. 273. 121685. doi:10.1016/j.conbuildmat.2020.121685

14. Chernykh K.P., Ovcharenko G.I., Frantsen V.B. Tekhnologiya, stabiliziruyushaya svoystva gazobetona na osnove vysokokal'tsiyevykh zol [Technology stabilizing the properties of aerated concrete based on high-calcium ash]. Proceedings of the scientific and technical anniversary conference "Modern Building Materials". Novosibirsk: Izd-vo NGASU, 2000. Pp. 47-48. (rus)

15. Ovcharenko G.I,. Frantsen V.B., Chernykh K.P. Zoly TETS ugley KAB v kachestve syr'yevogo komponenta dlya proizvodstva gazobetona [Ashes of thermal power plant of KAB coals as a raw material component for the production of aerated concrete]. International scientific-practical conference "Humanism and construction on the threshold of the third millennium": abstracts. Barnaul: publishing house Alt GTU. 1999. Pp. 129. (rus)

16. Gao H., Wang W., Liao H., Cheng F. Characterization of light foamed concrete containing fly ash and desulfurization gypsum for wall insulation prepared with vacuum foaming process. Construction and Building Materials. 2021. No. 281. 122411. doi:10.1016/j.conbuildmat.2021.122411.

17. She W., Du Y., Zhao G., Feng P., Zhang Y., Cao X., Influence of coarse fly ash on the performance of foam concrete and its application in high-speed railway roadbeds. Construction and Building Materials. 2018. No. 170, Pp. 153-166. doi:10.1016/j.conbuildmat.2018.02.207.

18. Gökçe H.S., Hatungimana D., Ramyar K. Effect of fly ash and silica fume on hardened properties of foam concrete. Construction and Building Materials. 2019. No. 194. Pp. 1-11. doi:10.1016/j.conbuildmat.2018.11.036.

19. Mugahed Amran Y.H., Alyousef R., Alabduljabbar H., Khudhair M.H.R., Hejazi F., Alaskar A., Alrshoudi F., Siddika A. Performance properties of structural fibred-foamed concrete. Results in Engineering. 2020. No. 5. 100092. doi:10.1016/j.rineng.2019.100092.

20. Liu X., Ni C., Meng K., Zhang L., Liu D., Sun L. Strengthening mechanism of lightweight cellular concrete filled with fly ash. Construction and Building Materials. 2020. No. 251. 118954. doi:10.1016/j.conbuildmat.2020.118954.

21. Patent RU 2237041 C1, Russian Federation, IPC C04B 38/10. Raw mix for the manufacture of structural heat-insulating foam concrete: No. 2003111123/03, Appl. 04/17/2003: Published. 09/27/2004 / P.F. Sobkalov, V.M. Bertov; patentee(s): Open Joint Stock Company "All-Russian Scientific Research Institute of Hydraulic Engineering named after B.E. Vedeneev".

22. Patent RU 2543847 C2, Russian Federation, IPC C04B 38/02, C04B 38/10, B82B 3/00. Method for preparing a mixture for the production of composite cellular concrete: No. 2013131123/03, Appl. 07/05/2013: Published. 03/10/2015 / E. N. Yastremsky, I. A. Emelyanov.

23. Patent RU 2719895 C1, Russian Federation, IPC C04B 38/10. Concrete mix: No. 2019121054, Appl. 07/03/2019: Published. 04/23/2020 / R.S. Fedyuk, A.V. Baranov, Yu.L. Liseytsev, V.S. Lesovik, E.A. Popov; patent holder(s): Federal State Budgetary Educational Institution of Higher Education "Vladivostok State University of Economics and Service" (VGUES).

24. Patent RU 2635687 C1, Russian Federation, IPC C04B 38/02, C04B 38/10, C04B 40/02. Raw mix for aerated concrete: No. 2016122858, Appl. 06/08/2016: Published. 11/15/2017 / O.V. Chemisenko, Yu.L. Breiter, E.N. Poloumova; patent holder(s): Federal State Budgetary Educational Institution of Higher Education "Omsk State Technical University".

25. Fomina I.V., Kapustin F.L. Effektivnyy zapolnitel' dlya konstruktsionnykh betonov na osnove zoly-unos [Efficient filler for structural concrete based on fly ash]. Aprobatsiya. 2013. No. 3(6). Pp. 56-60. (rus)

26. Golik V.I., Dmitrak YU.V., Khmelevskiy M.V., Stas' P.P. Rezhim peremeshivaniya komponentov pri izgotovlenii betona s dobavkoy zoly unosa [The mode of mixing components in the manufacture of concrete with the addition of fly ash]. Bulletin of the Tula State University. Earth Sciences. 2019. No. 1. Pp. 201-210. (rus)

27. Korovkin M.O., Kalashnikov V.I., Yeroshkina N.A. Vliyaniye vysokokal'tsiyevoy zoly-unosa na svoystva samouplotnyayushchegosya betona [Influence of high-calcium fly ash on the properties of self-compacting concrete]. Regional'naya arkhitektura i stroitel'stvo. 2015. No. 1(22). Pp. 49-53. (rus)

28. Jani P., Imqam A. Class C fly ash-based alkali activated cement as a potential alternative cement for CO2 storage applications. Journal of Petroleum Science and Engineering. 2021. No. 201. 108408. doi:10.1016/j.petrol.2021.108408

29. Fuzail Hashmi A., Shariq M., Baqi A. An investigation into age-dependent strength, elastic modulus and deflection of low calcium fly ash concrete for sustainable construction. Construction and Building Materials. 2021. No. 283. 122772. doi:10.1016/j.conbuildmat.2021.122772.

30. She W., Du Y., Zhao G., Feng P., Zhang Y., Cao X. Influence of coarse fly ash on the performance of foam concrete and its application in high-speed railway roadbeds. Construction and Building Materials. 2018. No. 170. Pp. 153-166. doi:10.1016/j.conbuildmat.2018.02.207.

31. Patent RU 2745041 C1, Russian Federation, IPC E21B 33/138, C04B 28/02, C09K 8/467, C04B 22/08, C04B 40/00, C04B 22/16, C04B 103/14. Accelerators for composite cement compositions: No. 2019121706, Appl. 02/22/2017: Published. 03/18/2021 / T.D. Pisklak, Sh.U. Rijo, R.G. Morgan, T.S. Sodhi, S.E.A. Lamzden, S.J. Lewis; Halliburton Energy Services, Inc.

32. Chindaprasirt P., Rattanasak U. Shrinkage behavior of structural foam lightweight concrete containing glycol compounds and fly ash. Materials & Design. 2011. No. 32(2). Pp. 723-727. doi:10.1016/j.matdes.2010.07.036

33. Patent RU 2479518 C1, Russian Federation, IPC C04B 18/06. Raw mix for the production of lightweight concrete aggregate (penosol): No. 2011137771/03, Appl. 09/13/2011: Published. 04/20/2014 / V.A. Kutolin, V.A. wide; patentee(s): Establishment of the Russian Academy of Sciences Institute of Geology and Mineralogy im. V.S. Sobolev of the Siberian Branch of the Russian Academy of Sciences (Institute of Geology and Mineralogy SB RAS, IGM SB RAS).

34. Lesovik V.S., Fedyuk R.S. Povysheniye effektivnosti malopronitsayemykh tsementnykh kompozitov [Improving the efficiency of low-permeability cement composites]. Vestnik MGSU. 2021. Vol. 16. No. 10. Pp. 1346- 1356. (rus)

35. Popov S.V., Braginskiy V.G., Davidenko V.P. Issledovaniye spetsial'nykh svoystv betona na zapolnitelyakh iz zoloshlakovykh smesey TES [Investigation of the special properties of concrete on aggregates from ash and slag mixtures at TPPs]. Vestnik Donbasskoy natsional'noy akademii stroitel'stva i arkhitektury. 2010. No. 5- 1(85). Pp. 135-139. (rus)

36. Patent RU 2717436 C1, Russian Federation, IPC C04B 28/36, C01B 17/00, C04B 7/28, C04B 111/20. Binder: No. 2019115562, Appl. 05/21/2019: Published. 03/24/2020 / R.T. Akhmetova, G.A. Medvedev, A.A. Yusupova, L.R. Baraeva, A.Yu. Akhmetova, A.I. Khatsrinov; patent holder: Federal State Budgetary Educational Institution of Higher Education "Kazan National Research Technological University" (FGBOU VO "KNRTU").

37. Patent RU 2482146 C2, Russian Federation, IPC C09D 5/00, C09D 1/00. High-temperature heatshielding coating: No. 2011136161/05, Appl. 05/31/2011: Published. 05/20/2013 / Yu.A. Grigoriev; patent holder: Limited Liability Company "OVK-Russia"

38. Amran M., Debbarma S., Ozbakkaloglu T. Fly ash-based eco-friendly geopolymer concrete: A critical review of the long-term durability properties. Construction and Building Materials. 2021. No. 270. 121857. doi:10.1016/j.conbuildmat.2020.121857

39. Moghaddam S.C., Madandoust R., Jamshidi M., Nikbin I.M. Mechanical properties of fly ash-based geopolymer concrete with crumb rubber and steel fiber under ambient and sulfuric acid conditions. Construction and Building Materials. 2021. No. 281. 122571. doi:10.1016/j.conbuildmat.2021.122571

40. Shalayev A.G., Shalayeva M.A., Antonenko N.A. Ispol'zovaniye zoly-unosa dlya resheniya ekologicheskikh problem sukhikh stroitel'nykh smesey [The use of fly ash to solve the environmental problems of dry building mixtures]. New technologies in the educational process and production: Proceedings of the XVIII International Scientific and Technical Conference. Ryazan: Ryazan Institute (branch) of the Federal State Budgetary Educational Institution of Higher Education "Moscow Polytechnic University", 2020. Pp. 200-203. (rus)

41. Bondar' A.V., Koval'skiy V.P. Ispol'zovaniye otkhodov dlya proizvodstva stroitel'nykh materialov [The use of waste for the production of building materials]. Northern Palmyra: IX Youth Ecological Conference: Conference Proceedings. St. Petersburg: St. Petersburg Research Center for Environmental Safety of the Russian Academy of Sciences, 2018. Pp. 148-151. (rus)

42. Dvorkin L.I., Zhitkovskiy V.V. Sukhiye stroitel'nyye smesi s dobavkoy izvestkovo-karbonatnoy pyli [Dry construction mixtures with the addition of lime-carbonate dust]. Sukhiye stroitel'nyye smesi. 2018. No. 4. Pp. 13-16. (rus)

43. Badmayeva E.V., Urkhanova L.A., Lkhasaranov S.A. Issledovaniye vliyaniya mineral'nykh dobavok na vyazkost' kompozitsionnykh vyazhushchikh dlya sukhikh stroitel'nykh smesey [Investigation of the influence of mineral additives on the viscosity of composite binders for dry building mixtures]. Topical issues of building materials science: Conference Proceedings. Ulan-Ude: Buryat State University named after Dorzhi Banzarov, 2021. Pp. 6-9. (rus)

44. Urkhanova L.A., Lkhasaranov S.A., Badmayeva E.V. Issledovaniye vliyaniya mineral'nykh dobavok na svoystva i fazovyy sostav kompozitsionnykh vyazhushchikh dlya sukhikh stroitel'nykh smesey [Study of the influence of mineral additives on the properties and phase composition of composite binders for dry building mixtures]. Vestnik VSGUTU. 2021. No. 4(83). Pp. 79-84. (rus)

45. Rashchupkina M.A., Simacheva E.E., Skvortsova N.V. Polucheniye effektivnykh sukhikh stroitel'nykh smesey dlya kladochnykh i shtukaturnykh rabot [Obtaining effective dry building mixes for masonry and plastering]. III International Scientific and Practical Conference "Architectural and construction and road transport complexes: problems, prospects, innovations": Conference Proceedings. Omsk: Siberian State Automobile and Road University (SibADI), 2019. Pp. 385-390. (rus)

46. Chernysheva N.V., Murtazayev S.A.YU., Aslakhanova A.KH. Sukhiye stroitel'nyye smesi na osnove KGV [Dry building mixes based on KGV]. Sukhiye stroitel'nyye smesi. 2012. No. 1. Pp. 12-13. (rus)

47. Zakharov A., Puzatova A, Dmitrieva M., Leitsin V. Prospects for the Use of Fly Ash from a Thermal Power Plant of the Kaliningrad Region in the Construction Industry. Lecture Notes in Civil Engineering. 2022. No. 168. Pp. 105-116. doi:10.1007/978-3-030-91145-4_11.