Journal of the Korea Concrete Institute (콘크리트학회논문집)

Korea Concrete Institute (한국콘크리트학회)
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Design of Ground Floor Slab According to the Method for Evaluating the Tensile Performance of Steel Fiber Reinforced Concrete

강섬유 보강 콘크리트 인장성능 평가방법에 따른 지반 바닥슬래브의 설계

  • Received : 2015.09.25
  • Accepted : 2015.11.11
  • Published : 2016.02.29
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Abstract

Flexural strength of concrete ground slab reinforced with steel fiber is evaluated using the equivalent flexural strength ratio of steel fiber reinforced concrete based on the yield line theory. Recently, the European standard specifies that the tensile performance of the steel fiber reinforced concrete be evaluated directly from the residual flexural strength after the cracking of concrete. Thus, in the study, an experiment was carried out to evaluate the conventional equivalent flexural strength ratio and the residual flexural strength of the steel fiber reinforced concrete. Then the design flexural strength was investigated according to the location of a point load, based on the ratio of the radius of contact area of the load to the radius of relative stiffness. Design flexural capacity obtained from ACI 360R-10 was smaller than that from TR 34 (2003 & 2013). In addition, TR 34 (2013), which evaluates the design flexural capacity based on the residual flexural strength, showed slightly smaller value than TR 34 (2003).

강섬유가 보강된 콘크리트의 지반 바닥슬래브는 소성해석법인 항복선 이론을 바탕으로 평균강도 개념인 등가 휨 강도비로서 설계 휨강도를 평가하였다. 최근 유럽의 설계기준에서는 강섬유에 의한 인장성능을 균열이후의 잔류 휨강도를 직접 평가하도록 하였다. 따라서, 본 연구에서는 기존의 등가 휨강도비와 잔류 휨강도에 따른 인장성능을 실험적으로 평가하고, 하중의 등가 접촉반경과 상대강성반경 비에 의해 하중 위치별 휨 내력을 평가하였다. 설계 휨 내력은 ACI 360R-10 기준이 TR 34 (2003 & 2013)에 비해 과소 평가하였다. 또한, 잔류 휨강도로서 평가하는 TR 34 (2013)은 등가 휨강도비로 계산되어진 TR 34 (2003)의 휨 내력에 비해 다소 작게 평가하고 있지만, 그 차이는 크지 않았다.

Keywords

References

  1. Lee, C.D., Hong, G.H., Seo, C.H., and Yu, T.D., "Verfication of load-carring capacity of steel fiber reinforced concrete slab-on-grad", KCI Fall Conference, 2007, pp.337-340 (in Korean).
  2. Jung, W.K., Hong, G.H., Lee, C.D., Seo, C.H., and Yu, T.D., "Experiment study about structural performance of SFRC slabs on grade", KCI Fall Conference, 2007, pp.197-200 (in Korean).
  3. Technical Report (TR) 34, Concrete industrial ground floors: A guide to design and construction, 3rd Edition, Concrete Society, Crowthorne, 2003, UK.
  4. JSCE SF-4, Method of tests for flexural strength and flexural toughness of SFRC, The Japanese Society of Civil Engineers(JSCE), Japan Concrete Institute, 1985, Japan.
  5. Technical Report (TR) 34, Concrete industrial ground floors: A guide to design and construction, 4th Edition, Concrete Society, Crowthorne, 2013, UK.
  6. Westergaad, H.M., "Computation of stresses in concrete roads", Proceedings of the 5th Annual Meeting of the Highway Research Board, Vol.5, Part.1, 1925, pp.90-112.
  7. Westergaad, H.M., "Stresses in concrete pavements computed by theoretical analysis", Public Roads, Vol.7, No.2, 1926.
  8. Meyerhof, G.G., "Load carrying capacity of concrete pavement", Journal of the Soil Mechanics and Foundations Divisions, Proceedings of the American Society of Civil Engineers, Vol.88, June 1962, pp.89-166.
  9. ACI 360R-10, Guide to design of slabs-on-ground, American Concrete Institute (ACI), Farmington Hills, 2013, MI.
  10. ASTM C 1609/C 1609M-07, Standard test method for flexural performance of fiber reinforced concrete (using beam with third-point loading), American Society of Testing Materials (ASTM), West Conshohocken, 2007, PA.
  11. BS EN 14651:2005, Test method for metallic fibre concretemeasuring the flexural tensile strength (limit of proportionality, residual), European Committee for Standardization(CEN), Brussels, 2007, UK.

Cited by

  1. Effect of the Combination of Point Loads on the Design Flexural Capacity for Fiber Reinforced Concrete Floor Slab vol.4, pp.1, 2016, https://doi.org/10.14190/JRCR.2016.4.1.047