JKCI
Journal of
the Korea Concrete Institute
KCI
Contact
Open Access
Bi-monthly
ISSN : 1229-5515 (Print)
ISSN : 2234-2842 (Online)
http://www.jkci.or.kr/jkci
Mobile QR Code
Journal of the Korea Concrete Institute
ISO Journal Title
J Korea Concr Inst.
SCOPUS
KCI Accredited Journal
Main Menu
Main Menu
저널소개
About Journal
최근호
Current Issue
논문집
All Issues
목적 및 범위
Aims and Scope
편집위원회
Editorial Board
논문투고안내
Instructions to Authors
출판정책
Publishing Policies
연락처
Contact Info
논문투고
Online-Submission
Journal Search
Home
All Issues
2022-12
(Vol.34 No.6)
10.4334/JKCI.2022.34.6.667
Journal XML
Export citation
EndNote
XML
PDF
INFO
REF
References
1
Abbass, W., Khan, I. M., and Mourad, S. (2018) Evaluation of Mechanical Properties of Steel Fiber Reinforced Concrete with Different Strengths of Concrete. Construction Building Materials 168, 556-569.
2
Abdallah, S., Fan, M., and Zhou, X. (2017) Pull-Out Behaviour of Hooked End Steel Fibres Embedded in Ultra-High Performance Mortar with Various W/B Ratios. International Journal of Concrete Structures and Materials 11, 301-313.
3
ASTM C109 (2007) Standard Test Method for Compressive Strength of Hydraulic Cement Mortars. West Conshohocken, PA; ASTM International.
4
Deng, F., Ding, X., Chi, Y., Xu, L., and Wang, L. (2018) The Pull-Out Behavior of Straight and Hooked-End Steel Fiber from Hybrid Fiber Reinforced Cementitious Composite: Experimental Study and Analytical Modelling. Composite Structures 15, 693-712.
5
Kang, S. T. (2013) Bond Strength of Steel Fiber Incorporated in Ultra High Performance Fiber-Reinforced Concrete. Journal of the Korea Concrete Institute 25(5), 547-554. (In Korean)
6
KATS (2017) Testing Method for Tensile Strength of Hydraulic Cement Mortars (KS L 5104). Seoul, Korea: Korea Agency for Technology and Standards (KATS), Korea Standard Association (KSA). (In Korean)
7
Lee, J. H. (2017) Influence of Concrete Strength Combined with Fiber Content in the Residual Flexural Strengths of Fiber Reinforced Concrete. Composite Structures 168, 216-225.
8
Lee, J. H., and Kighuta, K. (2017) Twin-Twist Effect of Fibers on the Pullout Resistance in Cementitious Materials. Construction Building Materials 147, 555-562.
9
Lee, J. H., Cho, B., and Choi, E. (2017) Flexural Capacity of Fiber Reinforced Concrete with a Consideration of Concrete Strength and Fiber Content. Construction Building Materials 138, 222-231.
10
Lee, Y. C., Kim, G. Y., Nam, J. S., Kim, H. S., and Lee. S. K. (2021) The Effect of Fiber on the Pull-Out Behavior and Tensile Performance of FRCC. Journal of the Korea Concrete Institute 33(4), 411-420. (In Korean)
11
Leung, C. K. Y., and Shapiro, N. (1999) Optimal Steel Fiber Strength for Reinforcement of Cementitious Materials. Journal of Materials in Civil Engineering 11, 116-123.
12
Singh, S., Shukla, A., and Brown. R. (2004) Pullout Behavior of Polypropylene Fibers from Cementitious Matrix. Cement and Concrete Research 34, 1919-1925.
13
Won, J. P., Lee, J. H., and Lee, S. J. (2015a) Bonding Behaviour of Arch-Type Steel Fibres in a Cementitious Composite. Composite Structures 133, 117-123.
14
Won, J. P., Lee, J. H., and Lee, S. J. (2015b) Predicting Pull-Out Behaviour Based on the Bond Mechanism of Arch-Type Steel Fibre in Cementitious Composite. Composite Structures 134, 633-644.
15
Zile, E., and Zile, O. (2013) Effect of the Fiber Geometry on the Pullout Response of Mechanically Deformed Steel Fibers. Cement and Concrete Research 44, 18-24.
