Identification of the failure modes of CFRP shear-strengthened reinforced concrete beams by the finite element method

Soares, Palloma Borges; Lazzari, Paula Manica; Campos Filho, Américo; Lazzari, Bruna Manica; Pacheco, Alexandre Rodrigues

doi:10.1590/S1983-41952023000300004

Palloma Borges Soares

conceptualization

writing

data curation

formal analysis

methodology

Universidade Federal do Rio Grande do Sul, Programa de Pós-Graduação em Engenharia Civil, Porto Alegre, RS, Brasil

https://orcid.org/0000-0001-7305-7823

Paula Manica Lazzari

conceptualization

formal analysis

methodology

supervision

Universidade Federal do Rio Grande do Sul, Programa de Pós-Graduação em Engenharia Civil, Porto Alegre, RS, Brasil

https://orcid.org/0000-0003-2163-1269

Américo Campos Filho

conceptualization

formal analysis

methodology

supervision

Universidade Federal do Rio Grande do Sul, Programa de Pós-Graduação em Engenharia Civil, Porto Alegre, RS, Brasil

https://orcid.org/0000-0001-7764-3010

Bruna Manica Lazzari

conceptualization

methodology

Pontifícia Universidade Católica do Rio Grande do Sul, Escola Politécnica, Porto Alegre, RS, Brasil

https://orcid.org/0000-0003-4005-9608

Alexandre Rodrigues Pacheco

conceptualization

Universidade Federal do Rio Grande do Sul, Programa de Pós-Graduação em Engenharia Civil, Porto Alegre, RS, Brasil

https://orcid.org/0000-0001-9646-8625

Corresponding author: Palloma Borges Soares. E-mail: pallomaborges24@gmail.com

Conflict of interest: Nothing to declare.

Author contributions: PBS: conceptualization, writing, data curation, formal analysis, and methodology; PML and ACF: conceptualization, formal analysis, methodology, and supervision; BML: conceptualization and methodology; ARP: conceptualization.

Editors: Leandro Trautwein, Mauro Real, Mario Pimentel.

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Figure 1
Bilinear relation between bonding stress and slip [¹⁷17 Fédération Internationale du Betón, Externally Bonded FRP Reinforcement for RC Structures: Bulletin D’information, N. 14. Lausanne, Switzerland: FIB, 2001.].

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Figure 2
Configuration and reinforcement details for Series A beams [²⁰20 A. Khalifa and A. Nanni, “Rehabilitation of rectangular simply supported RC beams with shear deficiencies using CFRP composites,” Constr. Build. Mater., vol. 16, no. 3, pp. 135-146, Jan. 2002.].

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Figure 3
Configuration and reinforcement details for Series B beams [²¹21 A. Khalifa, A. Belarbi, and A. Nanni, “Shear performance of RC members strengthened with externally bonded FRP wraps,” in Proc. 12th World Conf. Earthq. Eng., New Zealand National Society for Earthquake Engineering , Org. (Auckland, New Zealand), Jan. 2000, pp. 1-8.].

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Figure 4
Schematic representation of CFRP strengthening schemes for beam specimens of Series A [²⁰20 A. Khalifa and A. Nanni, “Rehabilitation of rectangular simply supported RC beams with shear deficiencies using CFRP composites,” Constr. Build. Mater., vol. 16, no. 3, pp. 135-146, Jan. 2002.].

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Figure 5
Schematic representation of test set-up for Series A [²⁰20 A. Khalifa and A. Nanni, “Rehabilitation of rectangular simply supported RC beams with shear deficiencies using CFRP composites,” Constr. Build. Mater., vol. 16, no. 3, pp. 135-146, Jan. 2002.].

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Figure 6
Strengthening schemes and test set-up for Series B beams [²¹21 A. Khalifa, A. Belarbi, and A. Nanni, “Shear performance of RC members strengthened with externally bonded FRP wraps,” in Proc. 12th World Conf. Earthq. Eng., New Zealand National Society for Earthquake Engineering , Org. (Auckland, New Zealand), Jan. 2000, pp. 1-8.].

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Figure 7
Finite element discretization of the beams: (a) A-SO4-1, and (b) A-SW3-1.

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Figure 8
Finite element discretization of the beams: (a) B-CO2, and (b) B-CF4.

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Figure 9
Cross-sections of the beams: (a) A-SW, A-SO, B-CW, and B-CO without CFRP; (b) B-CF without CFRP; (c) CFRP U-wrap; and (d) CFRP, totally wrapped.

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Figure 10
CONTA174 and TARGE170 elements for modeling beam B-CW2.

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Figure 11
Load vs. displacement diagram of beams with shear failure.

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Figure 12
Stress

σ_{x}

in the reinforcement of beam A-SW3-1 (kN/cm²).

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Figure 13
Principal strain

ε_{1}

in the concrete of beam A-SO4-1 (cm/cm).

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Figure 14
Principal strain

ε_{1}

in the concrete of beam B-CF1 (cm/cm).

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Figure 15
Failure modes observed in the beam tests [¹⁹19 A. Khalifa, “Shear performance of reinforced concrete beams strengthened with advanced composites,” Ph.D. dissertation, Struct. Eng. Depart., Alexandria Univ., Alexandria, Egypt, 1999.].

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Figure 16
Load vs. midspan deflection diagram for the beams with splitting failure.

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Figure 17
Stress

σ_{z}

in concrete for beam A-SW3-2 (kN/cm²).

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Figure 18
Principal strain

ε_{1}

in concrete for beam A-SW4-2 (cm/cm).

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Figure 19
Principal strain

ε_{1}

in concrete for beam B-CW2 (cm/cm).

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Figure 20
Failure modes observed in the experiments [¹⁹19 A. Khalifa, “Shear performance of reinforced concrete beams strengthened with advanced composites,” Ph.D. dissertation, Struct. Eng. Depart., Alexandria Univ., Alexandria, Egypt, 1999.].

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Figure 21
Load vs. midspan deflection diagram for beams with debonding failure.

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Figure 22
Evolution of the principal stress

σ_{1}

in the CFRP strengthening for beam A-SO3-3 (kN/cm²).

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Figure 23
Bond stress in the interface of beam A-SO3-3 (kN/cm²).

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Figure 24
Slip in the interface of beam A-SO3-3 (cm).

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Figure 25
Evolution of the principal stress

σ_{1}

in the CFRP strengthening for beam A-SO4-2 (kN/cm²).

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Figure 26
Bond stress in the interface of the beam A-SO4-2 (kN/cm²).

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Figure 27
Slip in the interface of beam A-SO4-2 (cm).

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Figure 28
Principal stress

σ_{1}

in the CFRP strengthening of beam B-CO2 (kN/cm²).

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Figure 29
Bond stress in the interface of beam B-CO2 (kN/cm²).

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Figure 30
Slip in the interface of beam B-CO2 (cm).

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Figure 31
Failure modes observed in the experiments [¹⁹19 A. Khalifa, “Shear performance of reinforced concrete beams strengthened with advanced composites,” Ph.D. dissertation, Struct. Eng. Depart., Alexandria Univ., Alexandria, Egypt, 1999.].

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Figure 32
Load vs. midspan deflection diagram for beams with bending failure.

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Figure 33
Stress

σ_{x}

in the reinforcement of beam B-CF2 (kN/cm²).

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Figure 34
Stress

σ_{x}

in the reinforcement of beam B-CF4 (kN/cm²).

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Figure 35
Principal stress

σ_{1}

in the CFRP strengthening of beam B-CF2 (kN/cm²).

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Figure 36
Bond stress in the interface of beam B-CF2 (kN/cm²).

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Figure 37
Interface slip of beam B-CF2 (cm).

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Figure 38
Principal stress

σ_{1}

in the CFRP strengthening of beam B-CF4 (kN/cm²).

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Figure 39
Failure modes observed in the experiments [¹⁹19 A. Khalifa, “Shear performance of reinforced concrete beams strengthened with advanced composites,” Ph.D. dissertation, Struct. Eng. Depart., Alexandria Univ., Alexandria, Egypt, 1999.].

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Table 1
Material properties [²¹21 A. Khalifa, A. Belarbi, and A. Nanni, “Shear performance of RC members strengthened with externally bonded FRP wraps,” in Proc. 12th World Conf. Earthq. Eng., New Zealand National Society for Earthquake Engineering , Org. (Auckland, New Zealand), Jan. 2000, pp. 1-8.].

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Table 2
Summary of beam characteristics [²¹21 A. Khalifa, A. Belarbi, and A. Nanni, “Shear performance of RC members strengthened with externally bonded FRP wraps,” in Proc. 12th World Conf. Earthq. Eng., New Zealand National Society for Earthquake Engineering , Org. (Auckland, New Zealand), Jan. 2000, pp. 1-8.].

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Table 3
Interface model parameters.

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Table 4
Summary of test results.

(1)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

Material	Specification	Compressive strength (MPa)	Yielding stress (MPa)	Ultimate tensile strength (MPa)	Modulus of elasticity (GPa)
Concrete	Group A-SW	19.3	-	2.2	20
	Group A-SO	27.5	-	2.7	25
	Group B-CW	27.5	-	2.7	25
	Group B-CO	20.5	-	2.2	22
	Group B-CF	50.0	-	4.1	33
Steel	φ = 32 mm	-	460	730	200
	φ = 16 mm	-	430	700	200
	φ = 10 mm	-	350	530	200
CFRP	t_fa = 0.165 mm	-	-	3790	228
CFRP	t_fb = 0.165 mm	-	-	3500	228

Nº	Specimen designation	Structural system and cross-section details	a/d ratio	Concrete strength (MPa)	Shear reinforcement
Nº	Specimen designation	Structural system and cross-section details	a/d ratio	Concrete strength (MPa)	Steel stirrups in the test region	CFRP
1	A-SW3-1	Simply supported beams	3	19.3	φ 10@125mm	-
2	A-SW3-2		3	19.3	φ 10@125mm	Two plies (90°/0°)
3	A-SW4-1		4	19.3	φ 10@125mm	-
4	A-SW4-2		4	19.3	φ 10@125mm	Two plies (90°/0°)
5	A-SO3-1		3	27.5	-	-
6	A-SO3-2		3	27.5	-	U-wrap strips, 50 @ 125mm
7	A-SO3-3		3	27.5	-	U-wrap strips, 75 @ 125mm
8	A-SO3-4		3	27.5	-	One-ply continuous U-wrap
9	A-SO3-5		3	27.5	-	Two plies (90°/0°)
10	A-SO4-1		4	27.5	-	-
11	A-SO4-2		4	27.5	-	U-wrap strips, 50 @ 125mm
12	A-SO4-3		4	27.5	-	One-ply continuous U-wrap
13	B-CW1	Continuous beams	3.6	27.5	φ 10@125mm	-
14	B-CW2		3.6	27.5	φ 10@125mm	Two plies (90°/0°)
15	B-CO1		3.6	20.5	-	-
16	B-CO2		3.6	20.5	-	U-wrap strips, 50 @ 125mm
17	B-CO3		3.6	20.5	-	One-ply continuous U-wrap
18	B-CF1	Continuous beams	3.6	50	-	-
19	B-CF2		3.6	50	-	One-ply continuous U-wrap
20	B-CF3		3.6	50	-	Two plies (90°/0°)
21	B-CF4		3.6	50	-	One-ply totally wrapped

Group	Maximum bonding stress τ_f1 (kN/cm²)	Tangential stiffness K_t (kN/cm³)	Maximum slip s₀ (cm)
A-SW	0.317	77	0.0182
A-SO	0.366	77	0.0169
B-CW	0.366	77	0.0169
B-CO	0.324	77	0.0180
B-CF	0.479	77	0.0148

Nº	Specimen designation	CFRP shear reinforcement	Experimental		Numerical		Variation (%)
Nº	Specimen designation	CFRP shear reinforcement	Failure mode	Load (kN)	Failure mode	Load (kN)	Variation (%)
1	A-SW3-1	-	Shear	252.8	Shear	249.9	-1.1
2	A-SW3-2	Two plies (90°/0°)	Splitting	354.6	Splitting	355.3	0.2
3	A-SW4-1	-	Shear	201.2	Shear	231.6	15.1
4	A-SW4-2	Two plies (90°/0°)	Splitting	361.6	Splitting	372.8	3.1
5	A-SO3-1	-	Shear	151	Shear	151	0
6	A-SO3-2	U-wrap strips, 50 @ 125mm	Debonding	261.9	Debonding	235	-10.3
7	A-SO3-3	U-wrap strips, 75 @ 125mm	Debonding	267.1	Debonding	240.4	-10.0
8	A-SO3-4	One-ply continuous U-wrap	Debonding	289	Debonding	337.1	16.6
9	A-SO3-5	Two plies (90°/0°)	Splitting	339.4	Splitting	321.2	-5.4
10	A-SO4-1	-	Shear	129.4	Shear	126.3	-2.4
11	A-SO4-2	U-wrap strips, 50 @ 125mm	Debonding	254.9	Debonding	240.5	-5.6
12	A-SO4-3	One-ply continuous U-wrap	Splitting	311.1	Splitting	341.5	9.8
13	B-CW1	-	Shear	175	Shear	175	0
14	B-CW2	Two plies (90°/0°)	Splitting	214	Splitting	241	12.6
15	B-CO1	-	Shear	48	Shear	43	-10.4
16	B-CO2	U-wrap strips, 50 @ 125mm	Debonding	88	Debonding	99	12.5
17	B-CO3	One-ply continuous U-wrap	Debonding	113	Splitting	140	23.9
18	B-CF1	-	Shear	93	Shear	93	0
19	B-CF2	One-ply continuous U-wrap	Flexural	119	Flexural	139	16.8
20	B-CF3	Two plies (90°/0°)	Flexural	131	Flexural	150	14.5
21	B-CF4	One-ply; totally wrapped	Flexural	140	Flexural	150	7.1

[1] Corresponding author: Palloma Borges Soares. E-mail: pallomaborges24@gmail.com

Brasil

Brasil

Identification of the failure modes of CFRP shear-strengthened reinforced concrete beams by the finite element method

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Abstract