Civil Engineering Reference
In-Depth Information
98. BS-8110, BS 8110. 1985. Part 1: structural use of concrete, code of practice for design and
construction. Part 2: code of practice for special circumstances, British Standards Institution.
99. Angelakos, D., E.C. Bentz, and M.P. Collins. 2001. Effect of concrete strength and minimum
stirrups on shear strength of large members. Journal of Structural Engineering 98(3):
290
-
300.
100. Glavind, M., C. Munch-Petersen, and E.J. Pedersen. 1994. Framework programme 1989
92
-
bre reinforced concrete. Publication No. 14 1/94. Nordic Concrete Research.
101. Paine, K. 1996. Trial production of bre reinforced hollow core slab. Research Report SR 96
007. Department of Civil Engineering, University of Nottingham.
102. ACI-544. 1993. Guide for specifying, proportioning, mixing, placing and nishing steel ber
reinforced concrete. ACI 544.3R-93. ACI Materials Journal 90(1): 94
101.
103. JCI. 1983. Method of making
ber reinforced concrete in the laboratory. JCI Standard SF1.
JCI Standards for Test Methods of Fiber Reinforced Concrete, 35
-
36.
104. Peaston, C.H., K.S. Elliott, and K.A. Paine. 1999. Steel Fiber Reinforcement for extruded
prestressed hollow core slabs. ACI Special Publication 182: 87
-
107.
105. Cuenca, E., and Serna, P. 2013. Failure modes and shear design of prestressed hollow core
slabs made of
ber-reinforced concrete. Composites Part B: Engineering 45(1): 952
-
964.
106. Cuenca, E., and P. Serna. 2010. Shear behavior of self-compacting concrete and
ber-
reinforced concrete push-off specimens. In Design, production and placement of self-
consolidating concrete, vol. 1, ed. K.H. Khayat, and D. Feys, 429
-
438., RILEM Bookseries
Netherlands: Springer.
107. Swamy, R.N., and S. Al-Ta
'
an. 1981. Deformation and ultimate strength in flexure of
reinforced concrete beams made with steel ber concrete. ACI Journal 78(5): 395
-
405.
108. Bentur, A., and S. Mindess. 1990. Fibre reinforced cementitious composites. England:
Elsevier Applied Science, 449 pp.
109. Pisanty, A. 1992. The shear strength of extruded hollow-core slabs. Materials and Structures
25: 224
-
230.
110. Elliott, K.S., C.H. Peaston, and K.A. Paine. 2002. Experimental and theoretical investigation
of the shear resistance of steel
ber reinforced prestressed concrete X-beams-part 1:
Experimental work. Materials and Structures 35: 519
-
527.
111. Girhammar, U.A. 1992. Design principles for simply supported hollow core slabs. Structural
Engineering Review 4(4): 301
-
316.
112. Narayanan, R., and I.Y.S. Darwish. 1987. Shear in prestressed concrete beams containing
steel
bers. International Journal of Cement Composites and Lightweight Concrete 9(2):
81
-
87.
113. Elliott, K.S., C.H. Peaston, and K.A. Paine. 2002. Experimental and theoretical investigation
of the shear resistance of steel
ber reinforced prestressed concrete X-beams-part 2:
Theoretical analysis and comparison with experiments. Materials and Structures 35:
528
-
535.
114. Lim, T.Y., P. Paramasivam, and S.L. Lee. 1987. Analytical model for tensile behavior of
steel-ber concrete. ACI Materials Journal 84(4): 286
-
298.
115. Dramix-Guidelines. 1995. Design of concrete structures. Steel wire ber reinforced concrete
structures with or without ordinary reinforcement.
116. Nemegeer, D., and R. Tatnall. 1995. Measuring toughness characteristics of SFRC-a critical
view of ASTM C1018. Testing of ber reinforced concrete. ACI Special Publication 155:
77
-
92.
117. Massicotte, B. 2004. Implementing SFRC design into North American Codes: Application to
a building
-
oor. In International workshop on the advanced in
bre reinforced concrete,
Bergamo, Italia.
118. Ultkjaer, J.P., S. Krenk, and E. Brincker. 1995. Analytical model for
ctitious crack
propagation in concrete beams. ASCE Journal of Engineering Mechanics 121(1): 7
-
15.
119. Kooiman, A.G. 2000. Modelling SFRC for structural design. PhD thesis, University of Delft,
Delft, The Netherlands.
fl
Search WWH ::
Custom Search