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Erschienen in:
Finite Element Analysis on Torsion Behaviour for Tapered Steel Section with Perforation Kapitel lesen Erstes Kapitel lesen

2020 | OriginalPaper | Buchkapitel

Experimental Verification of Reinforced Concrete Pile Caps

verfasst von : Khattab Saleem Abdul-Razzaq, Mustafa A. Farhood, Ali Mustafa Jalil

Erschienen in: Proceedings of AICCE'19

Verlag: Springer International Publishing

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Abstract

This paper deals with the experimental verification of the conventional design of pile caps, ACI 318-14, chapter thirteen. Six reinforced concrete pile cap specimens were designed according to the conventional theory, constructed, tested till failure, and then, compared to the theoretical design ones. The six specimens were divided into two groups; group A in which the spacing between piles was 270 mm, and group B; in which the spacing between piles was 410 mm. Every group contained three pile cap specimens, which were; two pile-cap specimens, three pile-cap specimens and four pile-cap specimens. The two pile-caps were 700 mm in length, 270 mm in height and 240 mm in width, while the three pile-caps were 586 mm in length, 270 mm in height and 700 mm in width. The four pile-caps were 700 mm in length, 270 mm in height and 700 mm in width. It is found that the experimental loads were higher than the design theoretical loads by (180–220)%. That takes place because the conventional method deals with Bernoulli region, while the pile cap is deep. In addition, ACI-318 procedures do not take into consideration the longitudinal reinforcement amount and overemphasize the role of the effective depth.

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Vorheriges Kapitel Reusable Concrete Debris as Aggregate Replacement on the Properties of Green Concrete
Nächstes Kapitel Rainfall Intensity (I)–Duration (D) Induced Debris Flow Occurrences in Peninsular Malaysia
Literatur
1.
Abdul-Razzaq KS, Ali HI, Abdul-Kareem MM (2017) A new strengthening technique for deep beam openings using steel plates. Int J Appl Eng Res 12(24):15935–15947
2.
Abdul-Razzaq KS, Jebur SF (2017) Suggesting alternatives for reinforced concrete deep beams by reinforcing struts and ties. In: MATEC web of conferences 120
3.
Abdul-Razzaq KS, Jebur SF, Mohammed AH (2018) Concrete and steel strengths effect on deep beams with reinforced struts. Int J Appl Eng Res 13(1):66–73
4.
Abdul-Razzaq KS, Jebur SF, Mohammed AH (2018) Strut and Tie modeling for RC deep beams under non-central loadings. Civil Eng J 4(5):937–948CrossRef
5.
Abdul-Razzaq KS, Jalil AM, Mohammed AH (2018) Applying various types of loading on continuous deep beams using Strut and Tie modelling. Int J Eng Technol 7(4.20):251–258
6.
Abdul-Razzaq KS, Jebur SF (2018) Experimental verification of Strut and Tie method for reinforced concrete deep beams under various types of loadings. J Eng Sustain Dev 21(6):39–55
7.
Mohammedali TK, Jalil AM, Abdul-Razzaq KS, Mohammed AH (2019) STM experimental verification for reinforced concrete continuous deep beams. Int J Civil Eng Technol (IJCIET) 10(2):2227–2239
8.
Abdul-Razzaq KS, Jalil AM (2017) Behavior of reinforced concrete continuous deep beams-literature review. In: 2nd conference of post graduate researches (CPGR’2017):158–163
9.
Jalil AM, Hamood MJ, Abdul-Razzaq KS, Mohammed AH (2018) Applying different decentralized loadings on RC continuous deep beams using STM. Int J Civil Eng Technol (IJCIET) 9(11):2752–2769
10.
Abdul-Razzaq KS, Farhood MA (2017) Design and behavior of reinforced concrete pile caps: a literature review. Int J Eng Res Sci Technol 6(4)
11.
Suzuki K, Otsuki K, Tsuchiya T (2001) Influence of edge distance on failure mechanism of pile caps. Trans Jpn Concr Inst 22:361–368
12.
Suzuki K, Otsuki K (2002) Experimental study on corner shear failure of pile caps. Trans Jpn Concr Inst 23:303–310
13.
Dawood AA, Kadhum AK, Abdul-Razzaq KS (2018) Strength of reinforced concrete corbels—a parametric study. Int J Civil Eng Technol (IJCIET) 9(11):2274–2288
14.
ACI Committee 318 (2014) American concrete institute, building code requirements for structural concrete (ACI 318-14) and commentary (318R-14)
15.
ACI Committee 318 (2005) American concrete institute, building code requirements for structural concrete (ACI 318-05) and commentary (318R-05), 430
16.
ACI Committee 318 (1983) American concrete institute, building code requirements for reinforced concrete (ACI 318-83). Farmington Hills
17.
ACI Committee 318 (1999) American concrete institute, building code requirements for structural concrete (ACI 318-99) and commentary (318R-99). Farmington Hills, 391
18.
ACI Committee 318 (2002) American concrete institute, building code requirements for structural concrete (ACI 318-02) and commentary (318R-02). Farmington Hills, 443
19.
Blevot JL, Fremy R (1967) Semelles sur Pieux. Institute Technique du Batiment et des Travaux Publics 20(230):223–295
20.
Clarke JL (1973) Behaviour and design of pile caps with four piles. Technical Report Springs 42:489
21.
Comite Euro-International Du Beton, CEB-FIP (1970) International recommendations for the design and construction of concrete structures. London, UK
22.
British Standards Institution (1972) Code of practice for the structural use of concrete-CP 110. London, UK
23.
Sabnis Gajanan M, Gogate Anand B (1984) Investigation of thick slab (pile cap) behavior. ACI J 81(1):35–39
24.
Suzuki Kuniyasu, Otsuki Kazuo, Tsubata Takuya (1998) Influence of bar arrangement on ultimate strength of four-pile caps. Trans Jpn Concr Inst 20:195–202
25.
Kumar A (2014) Study on the behavior of pile cap model with various type failure of concrete cap. Global J 1(1): 2349–283
26.
Iraqi Specification No. 5 (1984) Portland Cement, Iraqi Central Agency for Standardization and Quality Control. Planning Council (translated from Arabic edition), Iraq
27.
Iraqi Specification No. 45 (1984) Aggregate from natural sources for concrete. Iraqi Central Agency for Standardization and Quality Control (translated from Arabic edition), Iraq
28.
ASTM, C39 (2003) Standard specification for testing method for compressive strength of cylindrical concrete specimens. American Society for Testing and Materials, Philadelphia, PA
29.
ASTM, C496 (1996) Standard specification for splitting tensile strength of cylindrical concrete specimens. American Society for Testing and Materials, Philadelphia, PA
30.
ASTM, C78 (2002) Standard test method for flexural strength of concrete (using simple beam with third-point loading). American Society for Testing and Materials, Philadelphia, PA
Metadaten
Titel
Experimental Verification of Reinforced Concrete Pile Caps
verfasst von
Khattab Saleem Abdul-Razzaq
Mustafa A. Farhood
Ali Mustafa Jalil
Copyright-Jahr
2020
Buch
Proceedings of AICCE'19

Print ISBN: 978-3-030-32815-3

Electronic ISBN: 978-3-030-32816-0

Copyright-Jahr: 2020

DOI
https://doi.org/10.1007/978-3-030-32816-0_65