Moscow, Moscow, Russian Federation
Moscow, Moscow, Russian Federation
Tula, Tula, Russian Federation
Moscow, Moscow, Russian Federation
UDK 691.3 Искусственные камни. Бетоны. Искусственные строительные материалы различного состава
UDK 69.01 Сооружения и части зданий по видам строительных материалов
GRNTI 67.09 Строительные материалы и изделия
OKSO 08.03.01 Строительство
BBK 383 Строительные материалы и изделия
TBK 60 Естественные науки в целом
Additive technologies expand the boundaries of creative possibilities and allow to create unique objects and elements in the field of architectural environment design. The article discusses modern 3D printing technologies in the field of architectural environment design. The tasks of the architectural environment designer are highlighted. The process of objects layout design using 3D printing methods is covered in detail. The importance of the prototype creation stage is noted as the stage that additive technologies influence the most. Special attention is paid to the materials used to create architectural environment design objects using various 3D printing methods. The problems of 3D printing with cement mixtures and con-cretes related to their physical and chemical properties are analyzed. The trends in the application of additive technologies in the field of architectural environment design are determined.
design, architectural environment, 3D printing, additive technology, layout, concrete, gypsum, powder, adhesion, surfactants
1. Shuvalova E.M., Malysheva S.G. Rol' dizayn-tehnologiy v arhitekturnoy srede i social'nom progresse // Gradostroitel'-stvo i arhitektura. – 2017. – T.7. – № 2 (27). – S. 85-88.
2. Yusupova A.A., Yusupov A.N., Mamitova A.D., Nsanbayev B.S., Shagayeva A.E. The optimal parameters of elements of land-scape architecture // Vestnik nauki Yuzhnogo Kazahstana. – 2019. – № 4 (8). – S. 66-71.
3. Kulenenok V.V. Dizayn-koncepciya formirovaniya arhitektur-noy sredy goroda Vitebska // Vestnik Polockogo gosudarstvennogo universiteta. Seriya F. Stroitel'stvo. Prikladnye nauki. – 2012. - № 16. – S. 23-30.
4. Permyakov M.B., Krasnova T.V., Dorofeev A.V. Additivnye tehnologii v stroitel'stve i dizayne arhitekturnoy sredy: nastoyaschee i buduschee // Aktual'nye problemy sovremennoy nauki, tehniki i obrazovaniya. – 2018. – T. 9. – № 2. – S. 2-5.
5. Mal'ceva E.V., Dmitriev A.V. Koncepciya razvitiya additivnyh tehnologiy v individual'nom zhilom stroitel'stve // Zhilischnoe stroitel'stvo. – 2023. – № 11. – S. 12-18.
6. Kushnir N.V., Kushnir A.V., Geraschenko A.M., Tyrtyshnyy A.V. Istoriya i tehnologii trehmernoy pechati // Nauchnye trudy KubGTU. – Krasnodar, 2015. – №6. - S. 1-9.
7. Slavcheva G.S. Stroitel'naya 3D-pechat' segodnya: potencial, problemy i perspektivy prakticheskoy realizacii // Stroitel'-nye materialy. − 2021. – № 5. − S. 28–36.
8. Garenskiy D.A., Polyakova M.A. Sravnitel'nyy analiz metodov 3D-pechati // Aktual'nye problemy sovremennoy nauki, teh-niki i obrazovaniya. 2022. T. 13. № 1. S. 16-19.
9. Panevchik V.V., Samoylov M.V., Nekraha S.V. Bezopasnost' rashodnyh polimernyh materialov, primenyaemyh v 3D-tehnologii // Vestnik Belorusskogo gosudarstvennogo ekonomicheskogo universiteta. – 2019. – № 3 (134). – S. 87-93.
10. Lam T.V., Chyk N.Ch., Bulgakov B.I., Aleksandrova O.V. Poluchenie vysokoprochnogo melkozernistogo betona s pomosch'yu tehnologii 3D-pechati // Promyshlennoe i grazhdanskoe stroi-tel'stvo. 2023. № 9. S. 52-59.
11. Slavcheva G.S., Britvina E.A., Ibryaeva A.I. Stroitel'naya 3D-pechat': operativnyy metod kontrolya reologicheskih harakteristik smesey // Vestnik Inzhenernoy shkoly Dal'nevostochnogo federal'nogo universiteta. – 2019. – № 4 (41). – S. 134-143.
12. Kozlova I.V., Zemskova O.V., Lekanov N.A. Varianty vvedeniya tonkodispersnoy dobavki na osnove perlita v cementnye kompozicii//Stroitel'nye materialy – 2022 – № 11 – S. 42–49.
13. Kozlova I.V., Sinotova M.V. Varianty primeneniya ceolitov v proizvodstve stroitel'nyh materialov // Tehnika i tehnologiya silikatov. – 2023. – T. 30, № 2. – S. 116-128.
14. Kozlova, I., Samchenko, S., Zemskova O. Physico-Chemical Substantiation of Obtaining an Effective Cement Composite with Ultrafine GGBS Admixture, Buildings 2023, 13(4), 925. https://doi.org/10.3390/buildings13040925.
15. Kirillova N.K., Alekseeva A.N., Egorova A.D. Primenenie additivnyh tehnologiy v stroitel'stve i pri izgotovlenii keramicheskih izdeliy // Vestnik Belgorodskogo gosudarstvennogo tehnologicheskogo universiteta im. V.G. Shuhova. - 2020. - № 2. - S. 134-141.
16. Krahmatova V.Yu., Zaharov A.I., Andreev D.V., Krivoschepov A.F. Metody additivnyh tehnologiy dlya proizvodstva keramicheskih izdeliy // Steklo i keramika. 2018. № 12. S. 26-33.
17. Il'yuschenko A., Talako T., Lecko A. Additivnoe proizvod-stvo metallicheskih i keramicheskih poroshkovyh materialov // Nauka i innovacii. – 2024. – № 6 (256). – S. 28-37.
18. Bahtina T.A., Lyubomirskiy N.V., Bahtin A.S., Nikolaenko E.Yu. Razrabotka materiala na osnove izvestkovo-karbonatno-kal'cievyh kompoziciy dlya additivnyh tehnologiy // Vestnik Belgorodskogo gosudarstvennogo tehnologicheskogo universiteta im. V.G. Shuhova. - 2019. - № 4. - S. 8-16.
19. Crivello Ja., Reichmanis E. Photopolymer Materials and Process-es for Advanced Technologies // Chemistry of Materials. – 2023. – Vol. 26(1) – Rr. 533–548. DOI:https://doi.org/10.1021/cm402262g.
20. Sarsengalieva M. E. Sovremennye 3D-tehnologii v arhitek-ture i stroitel'stve // Molodoy uchenyy. – 2022. – № 17 (412). – S. 45-48.
21. Mokeeva O.D., Titova T.S. 3D-pechat' arhitekturnyh maketov i perspektivy osnascheniya ih inzhenernymi sistemami v processe pechati // Molodoy uchenyy. – 2016. – № 7(111). – S. 128-131.
22. Revich Yu.V. 3D v nature // Komp'yutera. – 2009. – № 8. – S. 37–41.
23. Bekker Yu.L., Zav'yalov V.A., Ul'yanov R.S., Shikolenko I.A. Aktual'nost' i perspektivy koncepcii kvazi-estestvennogo osvescheniya // Estestvennye i tehnicheskie nauki. – 2015. – № 5. – S. 143–145.
24. Bekker Yu.L., Zav'yalov V.A., Ul'yanov R.S., Shikolenko I.A. Vyyavlenie klyuchevyh aspektov sistemy sovmeschennogo osvescheniya s pozicii sootvetstviya koncepcii kvazi-estestvennogo osvescheniya // Estestvennye i tehnicheskie nauki. – 2015. – № 5. – S. 149–151.
25. Zav'yalov V.A., Bekker Yu.L., Ul'yanov R.S., Shikolenko I.A. Dostizhenie parametrov kvazi-estestvennogo osvescheniya za schet primeneniya avtomaticheskih sistem osvescheniya na baze CID //Sistemy. Metody. Tehnologii. – 2014. – №4. – S.88-93.
26. Kozlova I.V., Dudareva M.O. Perspektivnaya dobavka na osnove sistemy TiO2-Bi2O3 dlya cementnyh kompozitov // Stroitel'nye materialy. – 2023. – №11. – S.100-103. https://doi.org/10.31659/0585-430X-2023-819-11-100-103.
27. Samchenko S.V., Egorov E.S. Upravlenie svoystvami cementnoy pasty pri ee modificirovanii predvaritel'no gidratirovannoy cementnoy suspenziey // Tehnika i tehnologiya silikatov. – 2021. – T. 28. – № 2. – S. 54-58.
28. Kozlova I.V., Nechaev K.V. Vliyanie tonkomolotogo shlaka na svoystva cementa s mineral'nymi dobavkami // Tehnika i tehnologiya silikatov. – 2018. – T.25. – №4. - S. 109-114.
29. Ganiev A.G. Issledovanie vliyaniya superplastifikatora na svoystva betona // Aktual'nye nauchnye issledovaniya v sovremennom mire. – 2019. – №. 12–1. – S. 41–43.
30. Samchenko S.V., Kozlova I.V., Zemskova O.V., Dudareva M.O. Exploring the Surface Chemistry for the Stabilization of Bismuth Titanate Fine Particle Suspensions in Cement Systems // Nanotechnologies in construction. – 2023. – 15 (5). – Rr. 397–407. DOI:https://doi.org/10.15828/2075-8545-2023-15-5-397-407.
31. Samchenko, S., Kozlova, I., Zemskova, O., Potaev, D., Tsakhilova, D. Efficiency of stabilization of slag suspensions by polycarboxylate // E3S Web of Conferences. – 2019. – Vol. 91. - №02039. DOI:https://doi.org/10.1051/e3sconf/20199102039.
32. Muhametrahimov R.H., Galautdinov A.R., Ziganshina L.V. Sovershenstvovanie additivnogo stroitel'nogo proizvodstva povysheniem adgezii sloev pri dlitel'nyh pereryvah v proces-se 3D-pechati // Izvestiya KGASU. – 2024. - № 1(67). – S. 127-134.
33. Tao Y., Yuan Y., Vantyghem G., Van Tittelboom K. Adhesion Properties of Printable Polymer-Modified Concrete for Rock Tunnel Linings // ACI Materials Journal. – 2021. – Vol. 118. – Iss. 6.
34. Tao Y., Lesage K., De Schutter G., Van Tittelboom K. Adhesion studies in view of automated repair using 3D concrete printing // MATEC Web of Conferences. – 2023. – Vol. 378. – P. 03003.
35. Tao Ya, Ren Q., Vantyghem G., Lesage K., Van Tittelboom K., Yuan Yo., De Corte W., De Schutter G. Extending 3D concrete print-ing to hard rock tunnel linings: Adhesion of fresh cementitious mate-rials for different surface inclinations // Automation in Construction. – 2023. – Vol. 149. - P. 104787.
36. Poluektova V.A., Kozhanova E.P. Usovershenstvovanie tehnologii proizvodstva suhih stroitel'nyh smesey dlya 3D-pechati // Tehnologii additivnogo proizvodstva. – 2019. – T.1. №1. – S. 14-23.
37. Poluektova V.A., Shapovalov N. A Polimercementnaya suhaya stroitel'naya smes' dlya 3D-pechati // Patent na izobretenie RU 2739910 C1, 29.12.2020. Zayavka № 2020125199 ot 29.07.2020.
38. Slavcheva G.S., Artamonova O.V., Britvina E.A., Babenko D.S., Ibryaeva A.I. Dvuhfaznaya smes' na osnove cementa dlya kompozitov v tehnologii stroitel'noy 3D-pechati // Patent na izobretenie RU 2729283 C1, 05.08.2020. Zayavka № 2019133428 ot 21.10.2019.
39. Slavcheva G.S., Razov I.O., Solonina V.A., Panchenko Yu.F. Obosnovanie kriterial'nyh trebovaniy k napolnitelyam v so-stavah smesey dlya stroitel'noy 3D-pechati // Nanotehnologii v stroitel'stve. - 2023. – T. 15. - № 4. - S. 310–318. https://doi.org/10.15828/2075-8545-2023-15-4-310–318. – EDN: IFTQOV.
40. Shorstova E.S., Klyuev S.V., Klyuev A.V. Fibrobeton dlya 3D-pechati // Vestnik BGTU im. V.G. Shuhova. – 2019. – № 3. – S. 22–27. DOI:https://doi.org/10.34031/article_5ca1f6300a4956.62644399.
41. Ta-Yuan H. Influence of polyolefin fibers on the engineering properties of cement-based composites containing silica fume // Mate-rials & Design. - 2012. - Vol. 37. - Pp. 569 - 576.