JKSMI
Journal of the Korea Institute for
Structural Maintenance and Inspection
KSMI
Contact
Open Access
Bi-monthly
ISSN : 2234-6937 (Print)
ISSN : 2287-6979 (Online)
http://journal.auric.kr/jksmi/
Mobile QR Code
Journal of the Korea Concrete Institute
J Korea Inst. Struct. Maint. Insp.
Indexed by
Korea Citation Index (KCI)
Main Menu
Main Menu
About Journal
Aims and Scope
Subscription Inquiry
Editorial Board
For Contributors
Instructions For Authors
Ethical Guideline
Crossmark Policy
Submission & Review
Archives
Current Issue
All Issues
Journal Search
Home
All Issues
2022-10
(Vol.26 No.5)
10.11112/jksmi.2022.26.5.151
Journal XML
XML
PDF
INFO
REF
References
1
Zhang, C., Gholipour, G., Mousavi, A. A. (2020), Blast loads induced responses of RC structural members: State-of-the-art review, Composites Part B: Engineering, 195, 108066
2
Algassem, O., Li, Y., Aoude, H. (2019), Ability of steel fibers to enhance the shear and flexural behavior of high-strength concrete beams subjected to blast loads, Engineering Structures, 199, 109611
3
Shin, J., Jeon, J. S. (2019), Retrofit scheme of FRP jacketing system for blast damage mitigation of non-ductile RC building frames, Composite Structures, 228, 111328
4
Hu, Y., Chen, L., Fang, Q., Kong, X., Shi, Y., Cui, J. (2021), Study of CFRP retrofitted RC column under close-in explosion, Engineering Structures, 227, 111431
5
Luccioni, B., Isla, F., Codina, R., Ambrosini, D., Zerbino, R., Giaccio, G., Torrijos, M. C. (2017), Effect of steel fibers on static and blast response of high strength concrete, International Journal of Impact Engineering, 107, 23-37.
6
Lee, I. C., Kim, H. S., Nam, J. S., Kim, S. B., Kim, G. Y. (2013), Evaluation of Protective Performance of Fiber Reinforced Concrete T-Wall, Journal of the Korea Institute of Buliding Construction, 13(5), 465-473.
7
Ha, J. H., Yi, N. H., Kim, S. B., Chol, J. K., Kim, J. H. (2010), Experimental Study on Blast Resistance Improvement of RC Panels by FRP Retrofitting, Journal of the Korea Concrete Institute, 22(1), 93-102.
8
Byun, K. J., Kim, H. J., Nam, J. W. (2011), Blast Load and Design of Protective Structures, Journal of the Korea Concrete Institute, 23(2), 16-22.
9
Hong, J. K. (2018), Understanding of Blast Resistant Design and Performance Evaluation of a Building designed for conventional Loads, Journal of the Korea Institute for Structural Maintenance and Inspection, 22(4), 83-90.
10
Lee, S. H., Kim, H. S. (2022), Structural Behavior of Reinforced Concrete Members Subjected to Axial and Blast Loads Using Nonlinear Dynamic Analysis, J. Comput. Struct. Eng. Inst. Korea, 35(3)
11
Stewart, M. G., Netherton, M. D. (2015), Reliability-based design load factors for explosive blast loading, Journal of Performance of Constructed Facilities, 29(5), B4014010
12
U.S. Department of Defense, (2008), Structures to resist the effects of accidental explosions, UFC-3-340-02, Washington DC, USA.
13
Korean Occupational Safety Health Agency, (2012), KOSHA GUIDE D-65-2018, KOSHA
14
Jeon, D. J., Han, S. E. (2016), A Suggestion of Simplified Load Formula for Blast Analysis, Journal of the Computational Structural Engineering Institute of Korea, 29(1), 67-75.
15
Kingery, C. N., Bulmash, G. (1984), Airblast parameters from TNT spherical air burst and hemispherical surface burst, US Army Armament and Development Center, Ballistic Research Laboratory.
16
Swisdak Jr, M. M. (1994), Simplified Kingery airblast calculations, NAVAL SURFACE WARFARE CENTER INDIAN HEAD DIV MD.
17
Formby, S. A., Wharton, R. K. (1996), Blast characteristics and TNT equivalence values for some commercial explosives detonated at ground level, Journal of Hazardous materials, 50(2-3), 183-198.
18
Netherton, M. D., Stewart, M. G. (2010), Blast load variability and accuracy of blast load prediction models, International Journal of Protective Structures, 1(4), 543-570.
19
Schwer, L. E., Malvar, L. J. (2005), Simplified concrete modeling with *MAT_CONCRET_DAMAGE_REL3, LS-DYNA Anwenderforum, Bamberg.
20
Bischoff, P. H., Perry, S. H. (1991), Compressive behaviour of concrete at high strain rates, Materials and Structures, 24, 425-450.
21
Cho, H. W., Lee, J. H., Min, J. Y., Park, J. J., Moon, J. H. (2015), Evaluation of Material Properties Variations of Cementitious Composites under High Strain Rate by SHPB Test and Image Analysis, Journal of Korea Institute for Structural Maintenance and Inspection, 19(4), 83-91.
22
Malvar, L. J., Ross, C. A. (1998), Review of Strain Rate Effectes for Concrete in Tension, ACI Materials Journal, 95(6), 735-739.
23
Malvar, L. J. (1998), Review of Static and Dynamic Properties of Steel Reinforcing Bars, ACI Materials Journal, 95(6), 609-616.
24
Harding, J., L. Mo Welsh, (1983), A tensile testing technique for fibre-reinforced composites at impact rates of strain, Journal of Materials Science, 18(6), 1810-1826.
25
Taniguchi, N., Nishiwaki, T., Kawada, H. (2012), Tensile strength of unidirectional CFRP laminate under high strain rate, Advanced Composite Materials, 16(2), 167-180.
26
Hou, J. P., Ruiz, C. (2000), Measurement of the properties of woven CFRP T300/914 at different strain ratess, Composites Science and Technology, 60(15), 2829-2834.
27
CEB, (1993), CEP-FIP Model Code 1990, Redwood Books, Trobridge, Wiltshire, UK.
28
Tanapornraweekit, G., Haritos, N., Mendis, P. (2011), Behavior of FRP-RC Slabs under Multiple Independent Air Blasts, Journal of Performance of Constructed Facilities, 25(5), 433-440.
