Production of ceramic wall material based on burnt rocks and phosphoric slag without the use of natural traditional raw materials

The purpose of the work is to qualify the raw materials according to the main evaluation characteristics – shale clay as a plastic binder, ash and slag mixture as a burning additive, and phosphoric slag as a detergent for the production of ceramic wall materials, without using natural natural raw materials. An electron microscope JSM 6390A from Jeol (Japan) was used to diagnose waste for a microstructure of element-by-element chemical composition. In the petrographic diagnosis of raw materials, immersion liquids, transparent slips, full slips, and MIN-8 and MIN-7 microscopes were used. The raw materials used were waste from shale processing plants and from the burning of shale shale clay, ash and slag mixture and phosphorous slag. Experiments have confirmed that ceramic wall material cannot be classified as an M100 product without the involvement of solvents in the composition of only a single shale clay. It has been experimentally proven that the optimal composition for obtaining M125 grade bricks is a composition containing 18% phosphorous slag and 7% ash and slag mixture. A further increase in the amount of phosphorous slag, ash and slag mixture and, consequently, a decrease in the clay binder leads to a decrease in technical performance. Qualified utilization or recycling of hightonnage man-made raw materials of the fuel and energy complex is one of the most demanded solutions to the environmental problem.

1. Puzatova A.V., Dmitrieva M.Al., Zakharov A.An., Leitsin V.N. Fly Ash in The Production of Concrete for Various Purpose and Dry Construction Mixtures. Stroitelstvo i rekonstruktsiya. 2023;5:132-147. (In Russ.). https://doi.org/10.33979/2073-7416-2023-109-5-132-147. EDN: CJJALC.

2. Balanovskaya A.V., Abdrakhimova E.S. Issues of Environmental, Economic and Practical Recycling For the Use of the Fuel and Energy Complex for the Production of Thermal Insulation Materials. Ekologiya promyshlennogo proizvodstva. 2021;3:19-26. (In Russ.). https://doi.org/10.52190/2073-2589_2021_3_19. EDN: HBGGHW.

3. Abdrakhimov V.Z. Production on the Basis of Waste of Burnt Rocks – Inter-Shale Clay and Non-Ferrous Metallurgy – Alkaline Etching Mud of Earthquake-Resistant Bricks. Ecological Systems and Devices. 2021;7:25-34. (In Russ.). https://doi.org/10.25791/esip.07.2021.1239. EDN: UXKKTK.

4. Sokolova S.Vl., Baranova M.N., Vasilieva D.Ig., Kholopov Yu.Al. Possibilities of Using Industrial Waste to Improve Heat Resistant Concrete Durability and Refractoriness. Stroitelstvo i rekonstruktsiya. 2023;2:123- 133. (In Russ.). https://doi.org/10.33979/2073-7416-2023-106-2-123-133. EDN: ANWVDP.

5. Bouzit S., Laasri S., Taha M., Laghzizil A., Hajjaji A., Merli F. et al. Characterization of Natural Gypsum Materials and Their Composites for Building Applications. Applied Sciences. 2019;9:1-15. http://doi.org/10.3390/app9122443.

6. Abdrakhimova E.S., Abdrakhimov V.Z. Use of Western Kazakhstan Raw Materials for Producing AcidResistant Materials. Refractories and Industrial Ceramics. 2023;63(6):642-648. https://doi.org/10.1007/s11148-023-00784-3. EDN: HKJGPD.

7. Galtseva N.A., Popov P.V., Kotov D.A., Golotenko D.S. Recycling of Industrial Waste. Engineering Journal of Don. 2022;5:572-581. (In Russ.). EDN: AWIEIG.

8. Abdrakhimov V.Z. Influence of Ash and Slag on the Characteristics of Heat Insulation Based on Metallurgical Waste. Coke and Chemistry. 2023;66:310–315. https://doi.org/10.3103/S1068364X23700874.

9. Abdrakhimov V.Z., Abdrakhimova E.S. Oxidation Processes in the Firing of Porous Filler Based On Oil Production Wastes and Intershale Clay. Theoretical Foundations of Chemical Engineering. 2020;54(4):750- 755. https://doi.org/10.1134/S0040579519050026. EDN: NWZUHD.

10. Abdrakhimov V.Z. Reduction of Environmental Damage Due To the Use of Waste of Non-Ferrous Metallurgy and Energy in the Production of Lightweight Refractories. Ecological Systems and Devices. 2020;2:23- 34. (In Russ.). https://doi.org/10.25791/esip.02.2020.1137. EDN: EOIRBT.

11. Barinov A.V., Kuznetsova V.V. Modern State of Harmful Agent's and Wastes of Production Presence on the Industrial Enterprise. Scientific and Educational Problems of Civil Protection. 2013;2:20-25. (In Russ.). EDN: SCNRXB.

12. Ilyina L.A., Abdrakhimov V.Z. Environmental and Economic Aspects of the Use in the Production of Construction Materials Waste Of the Fuel and Energy Complex and Their Classification. Ecological Systems and Devices. 2020;8:28-44. (In Russ.). https://doi.org/10.25791/esip.08.2020.1173. EDN: OUFYFK.

13. Rakhimov R.Z., Rakhimova N.R., Gaifullin A.R. Influence of the Addition of Dispersed Fine Polymineral Calcined Clays on the Properties of Portland Cement Paste. Advances in Cement Research. 2016;29(1):21- 32. https://doi.org/10.1680/jadcr.16.00060.

14. Zemskov V.V., Prasolov V.I. Mineral Resources Depletion as a Threat to the Economic Security of Russia. Economics: Yesterday, Today and Tomorrow. 2021;11(10-1):195-205. (In Russ.). https://doi.org/10.34670/AR.2021.76.61.023. EDN: KVHAHA.

15. Bogdanov A., Mavlyuberdinov A., Nurieva E. The Use of Nanosized Additives in the Modification of Brick Loam. E3S Web of Conferences. 2021;274:1-6. https://doi.org/10.1051/e3sconf/202127404005.

16. Pichugin E.A. Analytical Review of the Experience of Involving Ash Slag Waste of Thermal Power Plants in Economic Circulation in the Russian Federation. Regional Environmental Issues. 2019;4:77-87. (In Russ.). https://doi.org/10.24411/1728-323X-2019-14077. EDN: MNEMSX.

17. Bushumov S.A., Korotkova T.G. Environmentally Safe Sorbent From Ash-And-Slag Waste of Heat Power Engineering. Fine Chemical Technologies. 2023;18(5):446-460. (In Russ.). https://doi.org/10.32362/2410-6593-2023-18-5-446-460. EDN: HJLALY.

18. Vdovin E., Mavliev L., Stroganov V. Interaction of Clay Soil Components with Portland Cement and Complex Additive Based on Octyltriethoxysilane and Sodium Hydroxide. IOP Conference Series: Materials Science and Engineering. 2020;890:1-9. https://doi.org/10.1088/1757-899X/890/1/012031.

19. Abdrakhimov V.Z., Nikitina N.V. Phase Composition of Interstitial Clay and Gas Emissions on Heat Treatment. Coke and Chemistry. 2023;66:431-437. https://doi.org/10.3103/S1068364X23701028.

20. Abdrakhimov V.Z. Combustion Kinetics of Organic Components in Firing Porous Aggregates Based on Ash and Shale Clay. Coke and Chemistry. 2023;66:135-143. https://doi.org/10.3103/S1068364X23700655.

21. Valochka A.T., Podbolotov K.B., Khort N.A., Manak P.I. Influence of Complex Types of Thinners and Color-Bearing Raw Materials on the Properties of Building Ceramics Products. Vestnik of Polotsk State University. Part F. Constructions. Applied Sciences. 2020;16:42-46. (In Russ.). EDN: WUWUBG.