한국건축시공학회지 (Journal of the Korea Institute of Building Construction)

  • 제15권5호
  • /
  • Pages.483-489
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  • 2015
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  • 1598-2033(pISSN)
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  • 2233-5706(eISSN)
한국건축시공학회 (The Korean Institute of Building Construction)
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온도변화에 따른 폴리머 시멘트 모르타르의 잔존압축강도 특성에 관한 실험적 연구

An Experimental Study on the Residual Compressive Strength of PCM Depending on Temperature Variations

  • Seo, Dong-Goo (Department of Fire and Protection Engineering, Hoseo University) ;
  • Koo, In-Hyuk (Department of Fire and Protection Engineering, Hoseo University) ;
  • Yoon, Ung-Gi (Department of Fire and Protection Engineering, Hoseo University) ;
  • Kim, Bong-Chan (Department of Fire and Protection Engineering, Hoseo University) ;
  • Kim, Hyung-Jun (Korea Conformity Laboratories) ;
  • Kwon, Young-Jin (Department of Fire and Protection Engineering, Hoseo University)
  • 투고 : 2015.06.15
  • 심사 : 2015.09.21
  • 발행 : 2015.10.20
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초록

본 연구는 고온영역에 있어서 PCM의 역학특성의 기초적인 자료를 구축하는 것을 목적으로, 정온가열에 따른 온도별(100, 200, 400, $600^{\circ}C$) 잔존압축강도 특성에 대하여 실험하였다. 화재피해 이후의 특성을 살펴보기 위해 냉간시험을 실시하였으며 그 결과, PCM의 잔존압축강도는 폴리머의 종류에 관계없이 모두 감소하는 경향이 나타났다. 또한 함유량이 많을수록 $400^{\circ}C$의 고온영역부터 크게 감소하는 특성을 보였으며, PAE가 함유된 시험체가 EVA가 함유된 시험체보다 압축강도 기울기가 크게 나타나는 것을 확인하였다. 하지만 현재 PCM의 고온에 따른 역학적특성에 관한 연구는 상당히 미흡하기 때문에 본 연구와 더불어 보수방법 등에 대한 기초적인 연구가 반드시 선행되어야 할 것으로 판단된다.

The Purpose of this study was to establish the basic data on the mechanical properties of PCM in the high temperature range. To this end, an experiment was conducted on the characteristics of the residual compressive strength by temperature (100, 200, 400 and $600^{\circ}C$) with a fixed temperature heating. An after heating test was performed to investigate the properties after fire damage. The result showed that the residual compressive strength of PCM had a tendency to decrease, regardless of the type of polymer. It was also found that when the contents were low, the residual compressive strength started to greatly decrease from the high temperature range of $400^{\circ}C$, and that the specimen containing PAE showed a steeper slope than the specimen containing EVA. However, since little studies have been conducted on the mechanical properties of PCM with the high temperature, it is considered that, in addition to this study, basic studies must be preceded, including studies on the repairing methods.

키워드

참고문헌

  1. National Fire Data System. Fire Statistics. Ministry of Public Safety and Security. 2015.
  2. Lee JY, Kim JH, Han BC, Park SG, Kwon YJ. A Study on the Anti-Spalling Performance of High-Strength Concrete Members by covered Engineered Cementitious Composite. Journal of Korean Institute of Fire Sci.&Eng. 2008 Nov;22(4):85-94.
  3. Lee MH. Analysis of the Contribution and Spalling Control Characteristics of Fire-resistance Strengthening Parameters of High Strength Concrete. Journal of Architectural Institute of Korea. 2008 Nov;24(11):109-18.
  4. Shin SW et al. Structural Fire Safety Design for High Strength Concrete. 1st rev. Architectural Institute of Korea. Republic of Korea: 2008. 220 p.
  5. Korea Concrete Institute. Fire Resistance of Reinforced Concrete Structures. Republic of Korea: Kimoondang Co. 2005. 160 p.
  6. Park DC. Performance Prediction System of Repair Materials and Repair Methods Applied to Deteriorated Reinforced Concrete Building. Land & Housing Institute. 2008 Dec:3
  7. Ohama Y. Shiroishida K. Properties of Polymer-Modified Mortars Using Powdered Emulsions. American Concrete Institute, Special Publication Vol.89. 1985 Dec; 313-22.
  8. ACI Committee 548. Guide for the Use of Polymers in Concrete. American Concrete Institute, ACI 548. 1R-97. 1997 Sept.; p. 1-4.
  9. Kwon YJ, Seo DG, Kim DE, Koo IH, Yoon UG. The Standardized Approach for Maintenance Methods of Concrete Structures Caused by Fire. In: Japan Association for Fire Science and Engineering, 2015 Conference, 2015 May 16 -May 17; Japan; 2015. p. 130-131.
  10. Kim JH, Lim SC, Kim JH, Kwon YJ. An Experimental Study on the Durability and Load Carrying Capacity of RC Structure Repair System Using FR-ECC. Korea Institute for Structural Maintenance and Inspection. 2012 Mar;16(2):75-86.
  11. Eurocode 4. Design of Composite Steel and Concrete Structures. Draft for Part 1-2: Structural Fire Design, CEN/TC250/SC4 N56, prENV. EU;1994. 1082 p.
  12. Architectural Institute of Japan. Guide Book for Fire Resistive Performance of Structural Materials. Japan: 2004. 260 p.
  13. Matsudo M, Nishida H, Ohtsuka T, Hirashima T, ABE T. Mechanical Properties of High Strength Concrete at High Temperatures: Fire Performance of High Strength Concrete(Part1). J. Struct. Constr. Eng., Architectural Institute of Japan. 2008 Feb;73(624):341-7.
  14. Kim HJ, Hamasaki H, Noguchi T, Nagai H. Mechanical Characteristics of Polymer-Modified Cement Mortar using Preheating Furnace Exposed to High Temperature. Japan Concrete Institute. 2010 ;32(1):1631-6.
  15. Bae SC, Han DY. A Study on the Strength Properties of Polymer Modified Mortars. Journal of the Regional Association of Architectural Institute of Korea, Conference 2010(1); 2010 Dec 25-26; Republic of Korea: AIK; 2010. p. 271-4.
  16. Kang YW. Evaluation on the Residual Mechanical Properties of Normal and Light-weight Concrete with Design Loading and Elevated Temperature. Chungnam National University, Degree of Doctor. 2013 Feb;24-29.
  17. Ohama Y. Handbook of Polymer-Modified Concrete and Mortars; Properties and Process Technology. Noyes Publication. 1995:125-30.
  18. Kang YH, Kang CH, Choi HG, Shin HJ, Kim WJ. Compressive Properties of Ultra High Strength Concrete Exposed to High Temperature. Journal of the Korea Concrete Institute. 2014 Jun;26(3):377-84. https://doi.org/10.4334/JKCI.2014.26.3.377