Technology of shotcreting based on activated binder

• Autorzy: Rudenko N.

Warianty tytułu

RU

Tekhnologia torkretirovanija na aktivirovannom vjazhushhem

• Języki publikacji: EN

Abstrakty

EN

RU

Słowa kluczowe

EN

shotcreting technology; activated binder; hydrotechnical construction; pneumatic transport; organo-mineral complex

• Wydawca: -
• Czasopismo: Teka Komisji Motoryzacji i Energetyki Rolnictwa
• Rocznik: 2014
• Tom: 14
• Numer: 1
• Opis fizyczny: p.222-228,ref.

Twórcy

autor

Rudenko N.

• Volodymyr Dahl East-Ukrainian National University, Molodizhny bl., 20а, Lugansk, 91034, Ukraine

Bibliografia

• 1. Cervera Miguel, Oliver Javier, Prato T., 1999: Thermo-Chemo-Mechanical Model for Concrete. Hydration and Aging // Journal of Engineering Mechanics. – Vol. 125. – No. 9. – 1018-1027.
• 2. Collepardi M., 2003: Innovative Concretes for Civil Engineering Structures: SCC, HPC and RPC / M. Collepardi // Workshop on New Technologies and Materials in Civil Engineering. – Proc. – Milan. – 1-8.
• 3. Hanehara S., 2008: Rheology and early age properties of cement systems / Shun-suke Hanehara, Kazuo Yamada//Cement and Concrete Research. – Vol. 38, No l. – 175-195.
• 4. Hogan F.J., Meusel J.W., 1991: Evaluation for Durability and Strength Development off a Ground Granulated Blast-Furnace Slag//Cem., Concr. and Aggreg. – V. 3. – N 1. – 40-52.
• 5. Gjorv O.E., 2007: High Strength Concrete. Advanced in Concrete Technology. – Canada. – 21-79.
• 6. Jawed Inam, 1988: Hydration of Portland cement. //Cem. Res. Progr., Surv. sci. lit. cem., publ. /Cem. Div. Amer. Ceram. Soc. – Westerville (Ohio). – 39-81.
• 7. John M. Hooks, 1999: HPS bridges for the 21-st century // Bridge Views. – Issue N 6. - 1-3.
• 8. Lea’s, 1998: Chemistry of Cement and Concrete, ed. by Peter C. Hewlett. – 1008.
• 9. Lu P., Yong I.F., 1993: Slag-Portland Cement Based DSP Paste. J. Am. Ceram. Soc. – Vol. 76. – №5. – 329-334.
• 10. Mehta P.K., 1990: Principlts Underlying Production of High Performance Concrete. /Р.С. Aitcin // Cement, Concrete and Aggregates. – Vol.12. – №2. – 70-78.
• 11. Meguid S.A., 1989: Engineering fracture mechanics. – London and New York: Elsevier applied science. – 397 p.
• 12. Middendorf B., 2006: Nanoscience and nanotechnology in cementitious materials / Middendorf B., Singh N. B. // Cement International. – № 4. – 80-86.
• 13. Neville A.M., 2000: Wlasciwosci betonu, wydanie 4, Kakow. – 874.
• 14. Powers Т.С., 1957: Тhe physical structure of Cement and Concrete / Т.С. Powers // TSJ-ACI. – Vol. 17. – № 5-6. – 189-202.
• 15. Punagin V., 2010: Properties and Technology of Concrete for high altitude monolithic construction//TEKA Kom. Mot. I Energ. Roln. – Lublin: OL PAN. – Vol. XB. – 114-119.
• 16. Punagin V., 2012: Physicochemical Characteristics of Bond and Friction between the Modified Concrete and Sliding Formwork for the Construction of High-rise Buildings//TEKA Kom. Mot. I Energ. Roln. – Lublin: OL PAN. – Vol. 12. – No. 4. – 229-234.
• 17. Reading T.J., 1987: Shotcrete as a construction material / T. J. Reading // Shotcreting. – Publication SP-14. – ACI. – 98-118.
• 18. Rohling Stefan, Niether Manfred, 1989: A model to describe the kinetics of structure formation and strength development: [Pap.] Expert Meet. Microstruct. and Prep. Concr., Espoo //VTT Symp. – №115. – 5-51.
• 19. Roy D.M., 1992: Advanced Cement Systems Including CBS, DSP, MDF/ 9-th ICCC, vol. 1 – 357-380.
• 20. Rudenko N., 2010: The Development of Conception of New Generation Concretes//TEKA Kom. Mot. I Energ. Roln. – Lublin: OL PAN. – Vol. XB. – 128-133.
• 21. Sakai E., Sugita J., 1995: Composite Mechanism of Polymer Modified Cement. Cem. Concr. Res., vol. 29. – 127-135.
• 22. Sawaide M., Iketani J., 1992, Rheological Analysis of the Behavior of Bleed Water from Freshly Cast Mortar and Concrete //ACI Materials Journal. – Vol. 89. – No. 4. – 323-328.
• 23. Schiller K.K., 1991: Mechanical Properties of Non-Metallic Brittle Materials / K. K. Schiller // Cement and Concrete Research. – Vol. 2. – 35-42.
• 24. Shah S.P., McGarry F.J., 1991: Griffith Fracture Criterion and Concrete//J. Eng. Mech. Div. Proc. Amer. Soc. Civ. Eng. – V. 97. – N 6. – 1663-1670.
• 25. Singh В.G., 1998: Specific surface of aggregates related to compressive and flexural of concrete//J.A.C.I. – Vо1. 29. – № 10. – 897-907.
• 26. Sujata K., Jennings Hamlin M., 1992: Formation of a protective layer during the hydration of cement. //J. Amer. Ceram. Soc. – №6. – 669-1673.
• 27. Tank Rajesh C., Carino Nicholas J., 1991: Rate constant functions for strength development of concrete //ACI Mater. J. – №1. – 74-83.
• 28. Thomas M.D.A., 1998: Development and field applications of silica fume concrete in Canada / K. Cail, R.D. Hooton // Canadian Journal of Engineering. – Vol. 25. №3. – 391-400.
• 29. Ulm Franz-Josef, Coussy Olivier, 1996: Strength Growth as Chemo-Plastic Hardening in Early Age Concrete // Journal of Engineering Mechanics. – Vol. 122. – No. 12. –1123-1132.
• 30. Wrihgt James, Frohnsdorf G., 1985: Durability of building materials: durability research in the United States and the influrnce of RILEM on durability research //Mater. and Constr. – Vol. 18. – No 105. – 205-214.
• 31. Zollo R.F., 1997: Fiber-reinforced Concrete: an Overview after 30 year of Development / R. F. Zollo // Cem. Concr. Com. – Vol. 19. – 107-122.