Elliptical FRP-tube confined reinforced concrete columns (EFCRCCs) are an emerging form of columns particularly suitable for use where the required resistances differ substantially in the two orthogonal lateral directions. This paper first presents a systematic experimental study on the eccentric compressive behaviour of EFCRCCs, with the main test variables being the initial load eccentricity, the sectional aspect ratio, the bending direction and the fibre orientations of the FRP tube. The test results showed that EFCRCCs possessed excellent structural performance, including ample ductility under eccentric compression; the effects of the key test variables on the eccentric compressive behaviour of EFCRCCs were also clarified. A theoretical model developed for EFCRCCs, with the slenderness effect taken into consideration, is then presented. The theoretical model is shown to provide reasonably accurate and conservative predictions of the load-carrying capacity of EFCRCCs. Using this theoretical model, the effects of stress-strain behaviour of the confined concrete in EFCRCCs on their eccentric compressive behaviour are examined, which provides valuable information for the establishment of an accurate stress-strain model for the concrete in eccentrically loaded EFCRCCs.
ACI (2019) Building Code Requirements for Structural Concrete and Commentary. ACI 318-19.
2.
ASTM (2014) Standard test method for static modulus of elasticity and Poisson’s ratio of concrete in compression. ASTM, Vol. C469.
3.
ASTM (2016a) Standard test method for compressive strength of cylindrical concrete specimens. ASTM, Vol. C39.
4.
ASTM (2016b) Standard Test Methods for Tension Testing of Metallic Materials. ASTM, Vol. E8.
5.
BisbyLRangerM (2010) Axial–flexural interaction in circular FRP-Confined reinforced concrete columns. Construction and Building Materials24(9): 1672–1681.
6.
BSI (2004) Eurocode 2: Design of Concrete Structures: Part 1-1: General Rules and Rules for Buildings. British Standards Institution.
7.
CaoYGJiangCWuYF (2016) Cross-sectional unification on the stress-strain model of concrete subjected to high passive confinement by fiber-reinforced polymer. Polymers8(5): 186.
8.
CarrazedoRde HanaiJB (2017) Concrete prisms and cylinders wrapped by FRP loaded in compression with small eccentricities. Journal of Composites for Construction21(4): 04016115.
9.
ChenGPWangYLYuT, et al. (2021) Behavior and design-oriented model for elliptical FRP-Confined concrete under axial compression. Engineering Structures249: 113387.
10.
ChenGWangYYuT, et al. (2022) Elliptical FRP–concrete–steel double-skin tubular columns: axial behavior, interaction mechanism, and modeling. Journal of Composites for Construction26(6): 04022078.
11.
ChenGPWangYLYuT, et al. (2023) Cyclically loaded elliptical FRP-Confined concrete: behavioral characteristics and modeling. Engineering Structures285: 116044.
12.
ClaesonCGylltoftK (1998) Slender high-strength concrete columns subjected to eccentric loading. Journal of Structural Engineering124(3): 233–240.
13.
CsukaBKollárLP (2011) FRP-Confined circular columns subjected to eccentric loading. Journal of Reinforced Plastics and Composites30(14): 1167–1178.
14.
GB (2020) Technical Standard for Fibre Reinforced Polymer (FRP) in Construction. GB 50608. China Planning Press.
15.
GB/T (2005) Fibre-reinforced thermosetting plastic composites pipe-determination for longitudinal compressive properties. GB/T 5350. Standardization Administration of the PRC.
16.
HadiM (2006) Behaviour of FRP wrapped normal strength concrete columns under eccentric loading. Composite Structures72(4): 503–511.
17.
HadiMN (2007a) Behaviour of FRP strengthened concrete columns under eccentric compression loading. Composite Structures77(1): 92–96.
18.
HadiMN (2007b) The behaviour of FRP wrapped HSC columns under different eccentric loads. Composite Structures78(4): 560–566.
19.
HadiMNWidiarsaIBR (2012) Axial and flexural performance of square RC columns wrapped with CFRP under eccentric loading. Journal of Composites for Construction16(6): 640–649.
20.
HainAMotarefSZaghiAE (2019) Influence of fiber orientation and shell thickness on the axial compressive behavior of concrete-filled fiber-reinforced polymer tubes. Construction and Building Materials220: 353–363.
21.
HalesTAPantelidesCPReaveleyLD (2017) Analytical buckling model for slender FRP-Reinforced concrete columns. Composite Structures176: 33–42.
22.
JiangTTengJG (2012) Theoretical model for slender FRP-Confined circular RC columns. Construction and Building Materials32: 66–76.
23.
JiangCWuYF (2020) Axial strength of eccentrically loaded FRP-Confined short concrete columns. Polymers12(6): 1261.
24.
KhorramianKSadeghianP (2021) Slender RC columns strengthened with a novel hybrid strengthening system of external longitudinal and transverse FRPs. Journal of Structural Engineering147(10): 04021154.
25.
LinGTengJG (2017) Three-dimensional finite-element analysis of FRP-Confined circular concrete columns under eccentric loading. Journal of Composites for Construction21(4): 04017003.
26.
LinGTengJG (2019) Stress-strain model for FRP-Confined concrete in eccentrically loaded circular columns. Journal of Composites for Construction23(3): 04019017.
27.
LinGYuTTengJG (2016) Design-oriented stress–strain model for concrete under combined FRP-Steel confinement. Journal of Composites for Construction20(4): 04015084.
28.
LinGZengJJTengJG, et al. (2020) Behavior of large-scale FRP-Confined rectangular RC columns under eccentric compression. Engineering Structures216: 110759.
29.
LiuKC (2023) Behaviour and Modelling of Elliptical FRP tube-confined Reinforced Concrete Columns. PhD dissertation. The Hong Kong Polytechnic University.
30.
LiuKCJiangCYuT, et al. (2023) Compressive behaviour of elliptical FRP tube-confined concrete columns. Composite Structures303: 116301.
31.
MirmiranAShahawyMBeitlemanT (2001) Slenderness limit for hybrid FRP-Concrete columns. Journal of Composites for Construction5(1): 26–34.
32.
OzbakkalogluTSaatciogluM (2006) Seismic behavior of high-strength concrete columns confined by fiber-reinforced polymer tubes. Journal of Composites for Construction10(6): 538–549.
33.
ParvinAWangW (2001) Behavior of FRP jacketed concrete columns under eccentric loading. Journal of Composites for Construction5(3): 146–152.
34.
PopovicsS (1998) Strength and Related Properties of Concrete: A Quantitative Approach. John Wiley & Sons, Inc.
35.
RamB (2012) Engineering Mathematics, Volume I, Second Edition. Pearson.
36.
RejabMRMKadirgamaKNoorMM, et al. (2008) Modification and testing of four axes filament winding machine. In: International Conference on Science & Technology: Application in Industry & Education.
37.
RoccaSGalatiNNanniA (2009) Interaction diagram methodology for design of FRP-Confined reinforced concrete columns. Construction and Building Materials23(4): 1508–1520.
38.
SaafiMToutanjiHLiZ (1999) Behavior of concrete columns confined with fiber reinforced polymer tubes. Materials Journal96(4): 500–509.
39.
SainiAPrakashSS (2021) Analytical study on the effectiveness of hybrid FRP strengthening on behaviour of slender reinforced concrete square columns. Structures33: 4218–4242.
40.
ShaikhFUAAlishahiR (2019) Behaviour of CFRP wrapped RC square columns under eccentric compressive loading. Structures20: 309–323.
41.
SiddiquiNAAlsayedSHAl-SalloumYA, et al. (2014) Experimental investigation of slender circular RC columns strengthened with FRP composites. Construction and Building Materials69: 323–334.
42.
SongXBGuXLLiYP, et al. (2013) Mechanical behavior of FRP-Strengthened concrete columns subjected to concentric and eccentric compression loading. Journal of Composites for Construction17(3): 336–346.
43.
TengJGLamL (2002) Compressive behavior of carbon fiber reinforced polymer-confined concrete in elliptical columns. Journal of Structural Engineering128(12): 1535–1543.
44.
TengJGWuJYCasalboniS, et al. (2016) Behavior and modeling of fiber-reinforced polymer-confined concrete in elliptical columns. Advances in Structural Engineering19(9): 1359–1378.
45.
TengJGXiePWangZH, et al. (2023) A Novel Test Method for the Determination of Hoop Elastic Modulus and Poisson’s Ratio of FRP Tubes. National Intellectual Property Administration. (Chinese Patent CN 113281166 B).
46.
TijaniIAJiangCLimC, et al. (2022) Eccentrically loaded concrete under nonuniform passive confinement. Journal of Structural Engineering148(1): 04021247.
47.
VincentTOzbakkalogluT (2013) Influence of fiber orientation and specimen end condition on axial compressive behavior of FRP-Confined concrete. Construction and Building Materials47: 814–826.
48.
XingLLinGChenJF (2020) Behavior of FRP-Confined circular RC columns under eccentric compression. Journal of Composites for Construction24(4): 04020030.
49.
YuTTengJG (2011) Design of concrete-filled FRP tubular columns: provisions in the Chinese technical code for infrastructure application of FRP composites. Journal of Composites for Construction15(3): 451–461.
50.
ZhangBFengGSWangYL, et al. (2020) Elliptical FRP‐Concrete‐Steel double‐skin tubular columns under monotonic axial compression. Advances in Polymer Technology2020(1): 1–16.
51.
ZhangBZhouCWangC, et al. (2023) Seismic behavior and modeling of elliptical concrete-filled FRP tubes with longitudinal steel rebars under lateral cyclic load and vertical constant load. Thin-Walled Structures188: 110815.
