I 150 Table of Contents 152 IV

Systems. Methods. Technologies 2 (38) 2018

Системы Методы Технологии. С.П. Осипов и др. Компьютерная томография … 2018 № 2 (38) с. 146-152 151 vanced Materials in Technology and Construction, AMTC 2015: Proceedings of the II All-Russian Scientific Conference of Young Scientists "Advanced Materials in Technology and Construction"" 2016. С. 070016. Scopus, WoS. 12. Nambiar E.K.K., Ramamurthy K. Air ‐ void characterisa- tion of foam concrete // Cement and concrete research. 2007. Vol. 37, № 2. Р. 221–230. 13. Esmaily H., Nuranian H. Non-autoclaved high strength cellular concrete from alkali activated slag //Construction and Building Materials. 2012. Vol. 26, № 1. Р. 200–206. 14. Абдрахимова Е.С., Абдрахимов В. Высокопористый теплоизоляционный материал на основе жидкого стекла // Физика и химия стекла. 2017. Т. 43, № 2. С. 222–230. 15. Moreno-Atanasio R., William R.A., Jia X. Combining X- ray microtomography with computer simulation for analysis of granular and porous materials // Particuology. 2010. Vol. 8, № 2. Р. 81–99. 16. Cnudde V., Boone M., Dewanckele J., Dierick M., Van Hoorebeke L., Jacobs P. 3D characterization of sandstone by means of X-ray computed tomography // Geosphere. 2011. Vol. 7, № 1. Р. 54–61. 17. Kim K.Y., Yun T.S., Choo J., Kang D.H., Shin H.S. De- termination of air-void parameters of hardened cement-based materials using X-ray computed tomography // Construction and Building Materials. 2012. Vol. 37. Р. 93–101. 18. Hassan N.A., Airey G.D., Hainin M.R. Characterisation of micro-structural damage in asphalt mixtures using image analysis // Construction and Building Materials. 2014. Vol. 54. Р. 27–38. 19. Wei S., Yiqiang C., Yunsheng Z., Jones M.R. Characteri- zation and simulation of microstructure and thermal properties of foamed concrete // Construction and Building Materials. 2013. Vol. 47. Р. 1278–1291. 20. Peng R., Yang Y., Ju Y., Mao L., Yang Y. Computation of fractal dimension of rock pores based on gray CT images // Chinese Science Bulletin. 2011. Vol. 56, № 31. Р. 3346–3357. 21. Осипов С.П., Клименов В.А., Батранин А.В., Штейн А.М., Прищепа И.А. Применение цифровой радиографии и рентгеновской вычислительной томографии при исследова- нии строительных конструкций и в строительном материало- ведении // Вестн. Том. гос. арх.-строительного ун-та. 2015. № 6. С. 116–127. 22. Hsieh J. Computed tomography: principles, design, arti- facts, and recent advances. Bellingham, WA: SPIE, 2009. 23. Ketcham R.A., Carlson W.D. Acquisition, optimization and interpretation of X-ray computed tomographic imagery: ap- plications to the geosciences // Computers & Geosciences. 2001. Vol. 27, № 4. Р. 381–400. 24. Alvarez R.E., Macovski A. Energy-selective reconstruc- tions in x-ray computerised tomography // Physics in Medicine & Biology. 1976. Vol. 21, № 5. Р. 733–744. 25. Ружинский С.А., Портик А.Б., Савиных А.В. Все о пе- нобетоне. СПб.: Стройбетон, 2006. 630 с. 26. Kudyakov A.I., Sarkisov Ju.S., Kopanitsa N.O., Kasatkina A.V., Prischepa I.F. Foam concrete of increased strength with the thermomodified peat additives // IOP Conference Series: Mate- rials Science and Engineering. IOP Publishing, 2015. Vol. 71. № 1 (012012). 7 p. 27. Прищепа И.А., Кудяков А.И., Копаница Н.О., Попов И.И., Иванова А.Б. Сырьевая смесь для приготовления пено- бетона: пат. 2012150707/03 Рос. Федерация. № 2514069; заявл. 26.11.2012; опубл. 27.04.14, Бюл. № 12. 28. http://portal.tpu.ru/departments/laboratory/rknl/eng/produ cts/orel_tomo (дата обращения: 16.03. 2018). 29. Chung S.Y., Lehmann C., Abd Elrahman M., Stephan D. Pore characteristics and their effects on the material properties of foamed concrete evaluated using micro-CT images and numerical approaches // Applied Sciences. 2017.Vol. 7, № 6. Р. 550. 30. Landis E.N., Keane D.T. X-ray microtomography // Mate- rials characterization. 2010. Vol. 61, № 12. Р. 1305–1316. 31. Batool F., Bindiganavile V. Air-void size distribution of cement based foam and its effect on thermal conductivity // Con- struction and Building Materials. 2017. Vol. 149. Р. 17–28. 32. Verba C. Foamed Cement Interactions with CO2. – Na- tional Energy Technology Laboratory-In-house Research, 2017. Technical Report no. 20858. 44 p. 33. Hajimohammadi A., Ngo T., Mendis P., Nguyen T., Ka- shani A., Van Deventer J.S. Pore characteristics in one-part mix geopolymers foamed by H2O2: The impact of mix design // Mate- rials & Design. 2017. Vol. 130. Р. 381–391. 34. Подворчан Ю.А. Экспериментальное исследование структуры пенобетона на микротомографе «Орел-МТ» [Электронный ресурс]: бакалав. работа. Томск: ТПУ, 2016. 81 с. URL: http://earchive.tpu.ru/bitstream/11683/24794/1/ TPU 145729.pdf. (дата обращения: 10.02.2018). 35. Hajimohammadi A., Ngo T., Mendis P., Nguyen T., Ka- shani, A., Van Deventer J.S. Pore characteristics in one-part mix geopolymers foamed by H2O2: The impact of mix design // Mate- rials & Design. 2017. Vol. 130. P. 381–391. 36. Podvorchan Yu.A. Experimental study of the structure of foam concrete on the microtomograph "Eagle-MT" [Электрон- ный ресурс]: bachelor's work. Tomsk: TPU, 2016. 81 p. URL: http://earchive.tpu.ru/bitstream/11683/24794/1/ TPU 145729.pdf. (10.03. 2018). References 1. Kudyakov A.I., Kopanica N.O., Prishepa I.A., Shangin S.N.Structural and heat-insulating foam concrete with thermo- modified peat additive // Vestnik ofTomsk State University of Architecture and Building. 2013. № 1. P. 172-177. 2. Hassan A.M.T., Jones S.W. Non-destructive testing of ultra high performance fibre reinforced concrete (UHPFRC): A feasi- bility study for using ultrasonic and resonant frequency testing techniques // Construction and Building Materials. 2012. Vol. 35. P. 361-367. 3. Bartz W., Rogoz J., Rogal R., Cupa A., Szroeder P. Charac- terization of historical lime plasters by combined non-destructive and destructive tests: The case of the sgraffito in Boznow (SW Poland) //Construction and Building Materials. 2012. Vol. 30. C 439-446. 4. Riggio M., Sandak J., Franke S. Application of imaging techniques for detection of defects, damage and decay in timber structures on-site // Construction and Building Materials. 2015. dx.doi.org/10.1016/j.conbuildmat.2015.06.065. 5. Abina A., Puc U., Jeglic A., Zidansek A. Applications of terahertz spectroscopy in the field of construction and building materials //Applied Spectroscopy Reviews. 2015. Vol. 50, № 4. P. 279-303. 6. Hilal A.A., Thom N.H., Dawson A.R. The use of additives to enhance properties of pre-formed foamed concrete // Int J Eng Technol. 2015. Vol. 7, № 4. P. 286-293. 7. Prishepa I.A., Kudyakov A.I.Cement foam with micropor- ous mineral and organomineral additives. Mezhdunarodnyj zhur- nal // Vestn. Evraz. Nac. un-ta im. L.N. Gumileva. Ch. 2, № 4 (113). 2016. P. 496-499. 8. Zhang Z., Provis J.L., Reid A., Wang H. Geopolymer foam concrete: an emerging material for sustainable construction // Construction and Building Materials. 2014. Vol. 56. P. 113-127. 9. Liu M.Y.J., Alengaram U.J., Jumaat M.Z., Mo K.H. Evalu- ation of thermal conductivity, mechanical and transport properties of lightweight aggregate foamed geopolymer concrete // Energy and Buildings. 2014. Vol. 72. P. 238-245. 10. Ramamurthy K., Nambiar E.K.K., Ranjani G.I.S. A classi- fication of studies on properties of foam concrete // Cement and concrete composites. 2009. Vol. 31, № 6. P. 388-396.

RkJQdWJsaXNoZXIy MTk0ODM1