Accesso libero

Reducing Thermal Crack Risks Caused by Restraint in Young Concrete - A Case Study on Walls of Water Tanks

Majid Al-Gburi
Majid Al-Gburi
, 
Jan-Erik Jonasson
Jan-Erik Jonasson
 e 
Martin Nilsson
Martin Nilsson
   | 11 lug 2022
Nordic Concrete Research's Cover Image
INFORMAZIONI SU QUESTO ARTICOLO
Articolo precedente
Articolo Successivo
Cita
Pubblicato online: 11 lug 2022
Pagine: 41 - 54
Ricevuto: 11 feb 2022
Accettato: 28 mar 2022
DOI: https://doi.org/10.2478/ncr-2022-0001
Parole chiave
© 2022 Majid Al-Gburi et al., published by Sciendo
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.

1. ACI Committee 207: “Effect of restraint, volume change, and reinforcement on cracking of massive concrete”. ACI Committee 207. ACI207.2R-95. Reapproved 2002. American Concrete Institute, Farmington Hills, USA 26 pp. Search in Google Scholar

2. JSCE: English Version of “Standard Specification for Concrete Structures 2007”. Japan Society of Civil Engineer, JSCE, December 2010, 503 pp. Search in Google Scholar

3. Ji, G: “Cracking risk of concrete structures in the hardening phase Experiments, material modeling and finite element analysis”. Department of Structural Engineering, The Norwegian University of Science and Technology Trondheim, Norway, 2008, 253 pp. Search in Google Scholar

4. Emborg, M.: “Thermal Stresses in Concrete at Early Ages, in Analysis of Concrete Structures by Fracture Mechanics”. Proceedings, International RILEM Workshop dedicated to Professor Arne Hillerborg, Abisko, Sweden, 1989, pp. 63-78. Search in Google Scholar

5. Kanazu, T., Sato, R., Sogo, S., Kishi, T., Noguchi, T., Mizobuchi, T., & Miyazawa, S.: “Outline of JCI guidelines for control of cracking of mass concrete”. Proceedings, 3rd JCI-KCI-TCI Symposium on Recent Advancement of Technologies in Concrete Engineering, Japan Concrete Institute, July 2012. Search in Google Scholar

6. Bamforth, P.B.: “Early-age thermal crack control in concrete”. CIRIA Report C660, Construction Industry Research and Information Association, London, 2007, 112 pp. Search in Google Scholar

7. ACI 224R-01: “Control of cracking in concrete structures, Manual of concrete practice, Part 3”. ACI Committee 224, American Concrete Institute, Farmington Hills, Mich, 2001, 46 pp. Search in Google Scholar

8. Al-Gburi, M., Jonasson, J.E., Nilsson, M., Hedlund, H., Hösthagen, A.: “Simplified Methods for Crack Risk Analyses of Early Age Concrete Part 1: Development of Equivalent Restraint Method”. Nordic Concrete Research, No. 46, 2012, pp. 17-38. Search in Google Scholar

9. Utsi, S., & Jonasson, J.-E.: “Estimation of the risk for early thermal cracking for SCC containing fly ash”. Materials and Structures, Volume 45, Issue 1-2, 2012, pp. 153-169.10.1617/s11527-011-9757-2 Search in Google Scholar

10. Al-Gburi, M., Jonasson, J.E., Yousif, S., T., & Nilsson, M.: “Simplified Methods for Crack Risk Analyses of Early Age Concrete Part 2: Restraint Factors for Typical Case Wall-on-Slab”. Nordic Concrete Research, No. 4, 2012, pp. 39-56. Search in Google Scholar

11. Kheder, G.F.: “A new look at the control of volume change cracking of base restrained concrete walls”. ACI Structural Journal, Vol. 94, No. 3, 1997, pp. 262-271.10.14359/478 Search in Google Scholar

12. Sule, M.: “Effect of reinforcement on early-age cracking in high strength concrete”. PhD thesis, Technical University of Delft, The Netherlands, 2003. Search in Google Scholar

13. Nagy, A.: “Cracking of Concrete Structures due to Early Thermal Deformations”. Report TVBK-1009, LTH, Lund, Sweden, 1997. Search in Google Scholar

14. Bernander, S.: “Practical measurement to avoiding early age thermal cracking in concrete structures”. Ed.by R. Springenschmid. London, England: E & FNSpon. RILEM Report. Search in Google Scholar

15. RILEM: “State of- the Art Report: Prevention of Thermal Cracking in Concrete at Early Ages “. RILEM Technical Committee 119, 1998, pp. 255-315. Search in Google Scholar

16. Al-Gburi, M., Jonasson, J.E., & Nilsson, M.: “Reduction of the Early Age Crack in the Concrete walls by Using a New Casting Technique”. Structural Engineering International Journal, Vol. 26, Issue 3, 2016, pp. 216-224.10.2749/101686616X14555429843960 Search in Google Scholar

17. Al-Gburi, M., Jonasson, J.E., & Nilsson, M.: “Effect of Casting Sequences on the Restraint in Slab On Ground- Proceedings, 1st Concrete Innovation Conference (CIC), Oslo, Norway, 2014. Search in Google Scholar

18. Zych, M.: “Numerical analysis of reinforcement stresses and stages of early age cracking in concrete tank‘s wall”. JUNIORSTAV, 2008, 2.1 Konstrukce betonové a zděné. Search in Google Scholar

19. Andrzej, S., Rafał, S., & Mariusz, M.: “Vertical cracking of reinforced concrete cylindrical tank wall at early age state”. Proceedings, 8th Conference on Shell Structures – Theory and Applications, Gdansk-Jurata, 2005. Search in Google Scholar

20. Andrzej, S., & Zych, M.: “Thermal Cracking of the Cylindrical Tank under Construction. I: Case Study”. Journal of Performance of Constructed Facilities, January 2014. Search in Google Scholar

21. Zych, M.: “Thermal Cracking of the Cylindrical Tank under Construction. II: Early Age Cracking”. Journal of Performance of Constructed Facilities, January 2014.10.1061/(ASCE)CF.1943-5509.0000577 Search in Google Scholar

22. Kianousha, M.R., Acarcanb, M, & BZiari, A.: “Behavior of base restrained reinforced concrete walls under volumetric change”. Engineering Structures, Vol. 30, 2008, pp. 1526–1534.10.1016/j.engstruct.2007.10.009 Search in Google Scholar

23. ConTeSt Pro. “User’s Manual - Program for Temperature and Stress Calculations in Concrete”. Developed by JEJMS Concrete AB in co-operation with Lulea University of Technology, Cementa AB and Peab AB. Luleå, Sweden, 2003, 198 pp. Search in Google Scholar

24. Abaqus 6.12 Getting Started with Abaqus: Interactive Edition. Search in Google Scholar

25. Swedish National Road Administration: “Handbook, Bridges”. Chapter 4-11 “Temperature cracks in concrete – cracking risk”. Borlänge, Sweden, 2004. (In Swedish.) Search in Google Scholar

26. CEN. “EN 1992-4. Euro Code 2: Design of concrete structures – Part 4: Liquid retaining and containing structure”. 1992, 28 pp. Search in Google Scholar

27. ACI Committee 224.3R-95: “Joints in Concrete Construction, Reported by ACI Committee 224. Reapproved 2001. American Concrete Institute, Farmington Hills, USA, 44 pp. Search in Google Scholar

28. Al-Rawi, R. S., & Kheder, G. F.: “Control of Cracking Due to Volume Change in Base Restrained Concrete Members”. ACI Structural Journal, Vol. 87, No. 4, July-Aug. 1990, pp. 397-405.10.14359/2747 Search in Google Scholar

29. Bamforth, P. Denton, S., & Brinckerhoff, P. “The development of a revised unified approach for the design of reinforcement to control cracking in concrete resulting from restrained contraction”. Final Report, ICE/0706/012, 2010. Search in Google Scholar

30. Bernander, S., Emborg, M. & Jonasson, J.-E.: “Temperature, maturity development and eigenstresses in young concrete”. Betonghandbok - Material, 2nd Edition, Chapter 16. AB Svensk Byggtjänst & Cementa AB, Stockholm, Sweden, 1994. (In Swedish). Search in Google Scholar

31. Beeby A.W., & Scott R. H.: “Cracking and deformation of axially reinforced members subjected to pure tension”. Magazine of Concrete Research, Vol. 57, No. 10, 2005, pp. 611-621.10.1680/macr.2005.57.10.611 Search in Google Scholar

eISSN:
2545-2819
Lingua:
Inglese
Frequenza di pubblicazione:
2 volte all'anno
Argomenti della rivista:
Materials Sciences, Materials Processing
Feed RSS della rivista