DOI QR코드

DOI QR Code

Evaluation of Impact Resistance of Steel Fiber and Organic Fiber Reinforced Concrete and Mortar

  • Kim, Gyu-Yong (Department of Architectural Engineering, Chungnam University) ;
  • Hwang, Heon-Kyu (Division of Building Works, Hyundai Amco) ;
  • Nam, Jeong-Soo (Department of Architectural Engineering, Chungnam University) ;
  • Kim, Hong-Seop (Department of Architectural Engineering, Chungnam University) ;
  • Park, Jong-Ho (Building Material, Sampyo Engineering & Construction) ;
  • Kim, Jeong-Jin (Building Material, Lotte Engineering & Construction)
  • Received : 2011.12.06
  • Accepted : 2012.06.18
  • Published : 2012.08.20

Abstract

In this study, the Impact resistance of steel fiber and organic fiber reinforced concrete and mortar was evaluated and the improvement in toughness resulting from an increase in compressive strength and mixing fiber for impact resistance on performance was examined. The types of fiber were steel fiber, PP and PVA, and these were mixed in at 0.1, 0.5 and 1.0 vol.%, respectively. Impact resistance is evaluated with an apparatus for testing impact resistance performance by high-speed projectile crash by gas-pressure. For the experimental conditions, Specimen size was $100{\times}100{\times}20$, 30mm ($width{\times}height{\times}thickness$). Projectile diameter was 7 and 10 mm and impact speed is 350m/s. After impact test, destruction grade, penetration depth, spalling thickness and crater area were evaluated. Through this evaluation, it was found that as compressive strength is increased, penetration is suppressed. In addition, as the mixing ratio of fiber is increased, the spalling thickness and crater area are suppressed. Organic fibers have lower density than the steel fiber, and population number per unit area is bigger. As a result, the improvement of impact resistance is more significant thanks to dispersion and degraded attachment performance.

Keywords

References

  1. Kim HS, Kim GY, Miyauchi H, Nam JS, Jeon YS, Koo KM. Evaluation of Impact Resistance Performance of High Strength Concrete by Projectile Size and Compressive Strength. Proceedings of the Korea Institute of Building Construction; 2011 May 20; Dong-Eui Unversity. Seoul (Korea); the Korea Institute of Building Construction; 2011. p. 7-10.
  2. Jeon YS, Kim GY, Nam JS, Kim HS, Miyauchi H. A study of the destruction condition of high strength concrete impacted by high speed projectile. Journal of the Korea institute for structural maintenance inspection. 2011 May;15(1):253-6.
  3. Zhang M H, Shim VPW, Lu G, Chew CW. Resistance of high-strength concrete to projectile impact. International Journal of Impact Engineering. 2005 April;31(7):825-41. https://doi.org/10.1016/j.ijimpeng.2004.04.009
  4. Dancygier AN, Yankelevsky DZ. High strength concrete response to hard projectile impact. International Journal of Impact Engineering. 1996 February;18(6):583-99. https://doi.org/10.1016/0734-743X(95)00063-G
  5. Koji MIWA, Masuhiro BEPPU, Tomonori OHNO, Masaharu ITOH, Masahide KATAYAMA. An estimation method of local damage in concrete plates by the modified theoretical model. Journal of Japan society of civil engineers. 2009 October;65(4):844-58.
  6. Masuhiro BEPPU, Koji MIWA, Tomonori OHNO, Masanori SHIOMI. An experimental study on the local damage of concrete plate due to high velocity impact of steel projectile. Journal of Japan society of civil engineers. 2007 March;63(1):178-91.
  7. Nam JS, Kim GY, Jeon JG, Jeon YS, Kim HS, Hwang HK, Miyauchi H, Kim MH. Impact resistance performance of mortar by mixing condition of fiber. Summaries of Technical Papers of Annual Meeting; 2010 September 09-11; University of Toyama. Toyama (Japan); Architecture Institute of Japan; 2010. p. 539-40.
  8. Kim GY, Nam JS, Miyauchi H. Evaluation on impact resistance performance of fiber reinforced mortar under high-velocity impact of projectile. Journal of the Architecture Institute of Korea. 2011 September;27(9):101-8.
  9. Jeon YS, Kim GY, Nam JS, Kim HS, Lee TG, Kim MH. Evaluation on blast resistance performance of concrete using fiber reinforced mortar panel and air space. Proceedings of the Korea Institute of Building Construction; 2010 Nov 12; Chungnam National Unversity. Seoul (Korea); the Korea Institute of Building Construction; 2010. p. 31-4.

Cited by

  1. A Study on the Penetration Resistance and Spalling Properties of High Strength Concrete by Impact of High Velocity Projectile vol.25, pp.1, 2013, https://doi.org/10.4334/JKCI.2013.25.1.099