DOI QR코드

DOI QR Code

고로슬래그 콘크리트의 투수특성에 관한 실험적 연구

An Experimental Study on Permeability Characteristics of Blast Furnace Slag Concrete

  • 백신원 (한경대학교 토목안전환경공학과) ;
  • 오대영 (한국농어촌공사 아산지사)
  • 투고 : 2013.01.21
  • 심사 : 2013.04.18
  • 발행 : 2013.05.31

초록

The pavement is generally used on the highways, local loads, roads for bicycle riding and neighborhood living facility such as parking lot, plaza, park and sports facilities. However, the pavement material that is usually used on the most of roads is impermeable asphalt-concrete and cement-concrete. If the pavement material is impermeable, many problems can be happened on the drainage facilities in the rainy season. Additionally, a lot of rainwater on the pavement surface cannot permeate to the underground and flows to the sewage ditch, stream and river, etc. If a lot of rainwater flows at once, the floods can be out along the streams and rivers. So, underground water can be exhausted. Micro organisms cannot live in the underground. Recently, many studies has been conducted to exploit the permeable concrete that has high performance permeability. However, it is required to develop the permeable concrete which has high strength and durability. In this study, permeable and strength tests were performed to investigate the permeable characteristics of porous concrete according to fine aggregate content and substitution ratio of blast furnace slag. In this test, crushed stones with 10~20 mm and sand with 5~10 mm were used as a coarse aggregate and a fine aggregate respectively. The substitution ratio of blast furnace slag to cement weight is 0 %, 15 %, and 30 %. The ratio of fine aggregate to total aggregate is 0 %, 18 %, and 35 %. As a result, permeability coefficient was decreased according to fine aggregate ratio of total aggregate. Compressive strength was also decreased according to substitution ratio of blast furnace slag.

키워드

참고문헌

  1. Choi, J., and E. Hwang, 2002. Physical properties of permeable polymer concrete. Journal of the Korea Concrete Institute 14(1): 41-48 (in Korean). https://doi.org/10.4334/JKCI.2002.14.1.041
  2. Jo, G., H. Lee, and S. Lee, 2002. Estimation of application on the site for the draining cement concrete pavement. Korean Society of Civil Engineers 22(4D): 697-705 (in Korean).
  3. Lee, Y., and M. Joo, 2002. Fundamental properties of water-permeable polymer-modified concrete. Journal of the Korea Concrete Institute 14(1): 402-408 (in Korean). https://doi.org/10.4334/JKCI.2002.14.3.402
  4. Choi, J., 2007. Influence of the types and grading of aggregate on the properties of porous concrete. Korean Society of Civil Engineers 27(3A): 393-400 (in Korean).
  5. Choi, K., B. Lho, M. Joo, and B. Lee, 2008. An experimental study on performance in elevation of porous polymer concrete. Korea Concrete Institute Spring Seminar 20(1): 953-956 (in Korean).
  6. Lho, B., K. Choi, J. Kim, 2007. An experimental study on permeability in elevation of porous polymer concrete using unsaturated polyester resin. Korean Society of Civil Engineers 19(2): 163-169 (in Korean).
  7. Choi, H. Y., M. H. Kim., H. Z. Hwang., and S. W. Choi, 2001. Experimental study on the properties of concrete by the kinds of admixture and the replacement ratios of activated hwangtoh. Journal of the Korean Society of Agricultural Engineers 13(2): 127-129 (in Korean).
  8. Lee, J., and C. Park, 2010. Effect of blast furnace slag, hwangtoh and reinforcing fibers on th physical and mechanical properties of porous concrete using blast furnace slag coarse aggregate. Journal of the Korean Society of Agricultural Engineers 52(5): 53-60 (in Korean).
  9. Ministry of Construction and Transportation, 1996. Guide for road pavement design and construction (in Korean).