A Design Process for Preventing Brittle Failure in Strengthening RC Slabs with Hybrid FRP-HPC Retrofit Systems
Abstract
:1. Introduction
2. Overview Theory and Proposed Process
2.1. Failure Limits Overview
2.2. Retrofitting Mechanism and Design Process Preventing Brittle Failure
- (1)
- Assume FRP thickness (tF).
- (2)
- The overlay strength () should be greater than the limits in the following equations to ensure the neutral axis within the overlay and FRP in the tensile zone [15]; otherwise, re-assume FRP thickness.
- (3)
- Compute the design strain of FRP (εfd) at support.
- (4)
- Assume the neutral axis depth (c).
- (5)
- Compute FRP stress (ffe) corresponding to FRP strain (εfe) and concrete strain at failure (εc) by applying similar triangles based on strain compatibility.For the support section:For the mid-span section:
- (6)
- Compute reinforced steel stress (fs) and strain (εs).For the support section (εs,N):For the mid-span section (εs,P):
- (7)
- Check the equilibrium condition by comparing c defined in Equation (33) with the value in step 4. If it is satisfied, go to step 9; otherwise, return to step 4.
- (8)
- Compute strength in flexure (ϕfMn) and shear (ϕvVn)For the support section, the contribution of steel (Mns,N) and FRP (Mnf,N), asFor the mid-span section, the contribution of steel (Mns,P) and FRP (Mnf,P), as
- (9)
- Define the design factored load as specified in Figure 2.
- (10)
- Define the failure mode and failure load (wf) in accordance with the failure limits. If the failure mode is ductile, the design process preventing brittle failure can be achieved; otherwise, re-assume FRP thickness.
3. Design Example
4. Results and Discussion
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Nomenclature
AF, As | Area of CFRP and tensile steel |
b | Width of an existing slab |
c | The distance between the extreme compression fiber and the neutral axis |
CE | Environmental reduction coefficient |
Cm,Ni | Moment coefficients at support section ith |
Cm,Pi | Moment coefficients at mid-span section ith |
Cvi | Shear coefficients at section ith |
d | The distance between the extreme compression fiber and the center of the steel |
Ec, Es, Efe | Elastic modulus of concrete, steel, and CFRP |
, | Compressive strength concrete of existing slab and overlay |
ffe | CFRP effective stress |
ffu | Design ultimate strength of CFRP |
FRP’s ultimate tensile strength, according to the manufacturer | |
fs | Tension steel’s stress |
fy | Yield stress of tension steel |
h | Height of an existing RC slab |
Icr | Cracked moment |
k | The ratio of the neutral axis depth to tensile steel depth measured from extreme compression fiber |
lni | Length of clear span ith |
n | The number of CFRP layers |
Mn, Vn | Moment and shear carrying capacity |
Mn,P, Mn,N | Mid-span and support sections’ moment-carrying capacities |
Mns, Mnf | Moments contributed by tensile steel and CFRP |
MN1 | Moment-carrying capacities of the N1 section |
MD,N2 | Moment-carrying of the N-2 section |
Mu, Vu | Factored moment and shear at sections |
tF, tH | The thickness of CFRP and HPC overlay |
wf | Ultimate failure load |
wu | Design factored load |
wuM, wuV | Design factored load follow moment and shear carrying capacities |
ϕf, ϕv | Flexural and shear strength reduction factors |
ψf | CFRP strength reduction factor |
α1, β1 | Stress block factors |
εbi | Existing state strain of CFRP installation |
εcu, εfu | Ultimate strains of concrete and CFRP |
εfd | Debonding strain of CFRP |
εfe, εs | Strains of CFRP and tensile steel |
γc | Concrete unit weight |
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Span Type | Failure Modes | First Plastic Hinge | Second Plastic Hinge | Third Plastic Hinge | Shear Failure | Failure Type |
---|---|---|---|---|---|---|
End span | D-1en | N2 | N1 | M1 | - | Ductile failure |
D-2en | N2 | M1 | N1 | - | Ductile failure | |
D-3en | M1 | N2 | N1 | - | Ductile failure | |
DB-1en | N2 | N1 | - | N2 | Brittle failure | |
DB-2en | N2 | M1 | - | N2 | Brittle failure | |
DB-3aen | M1 | - | - | N2 | Brittle failure | |
DB-3ben | M1 | N2 | - | N2 | Brittle failure | |
B-1en | N2 | - | - | N2 | Brittle failure | |
B-2en | - | - | - | N2 | Brittle failure | |
Interior span | D-1in | N3, N4 | M2 | - | Ductile failure | |
D-2in | M2 | N3, N4 | - | Ductile failure | ||
DB-1in | N3, N4 | - | N3, N4 | Brittle failure | ||
DB-2in | M2 | - | N3, N4 | Brittle failure | ||
B-1in | - | - | N3, N4 | Brittle failure |
Failure Modes | Failure Load | |
---|---|---|
D-1en | (15) | |
D-2en | (16) | |
D-3en | (17) | |
DB-1en, DB-2en, DB-3aen, DB-3ben, B-1en, B-2en | (18) | |
D-1in | (19) | |
D-2in | (20) | |
DB-1in, DB-2in, B-1in | (21) |
Type | l (mm) | h (mm) | b (mm) | As (mm2) | d (mm) | fy (MPa) | Es (GPa) | |
---|---|---|---|---|---|---|---|---|
End span | 2600 | 145 | 900 | 32 | 426 | 110 | 410 | 200 |
Interior span | 2400 | - | - | - | - | - | - | - |
HPC Overlay | CFRP | |||
---|---|---|---|---|
tH (mm) | (MPa) | tF (mm) | (MPa) | Efe (GPa) |
30 | 75 | 1 | 600 | 40 |
Analysis | Reference Slab |
---|---|
Sectional capacity | = 16.73 kNm; = 16.73 kNm; = 70 kN |
Design factored load | For end span: = min(39.6; 24.7; 34.6; 53.8; 46.8) = 24.7 kN/m For interior span: = min(32; 46.5; 58.3) = 32 kN/m |
Define failure mode and failure load | For end span: D-2en according to Figure 7a; Equation (16), = 31.3 kN/m For interior span: D-1in according to Figure 7b; Equation (19), = 39.2 kN/m |
Self-weight | = 24(0.9)(0.145) = 3.13 kN/m |
Elastic modulus | = = 26,600 MPa |
At support, kd | kd = 24.65 mm |
The crack moment at support | = |
The ultimate strength and strain of CFRP | = 570 MPa; = 0.0143 |
Moment due to dead load | At N2 section: = = 2.12 kNm At N3 and N4 sections: = = = 1.64 kNm |
The existing state of strain | At N2 section: = = 0.00034 At N3 and N4 sections: = = 0.00027 |
Process | End Span | Interior Span |
---|---|---|
1. Assume CFRP thicknesses | tF = 1 mm | tF = 1 mm |
2. Check overlay strength | For both spans = 9.05 MPa (OK) = 12.49 MPa (OK) | |
3. Compute the design strain of FRP at support | = = 0.0116 = 0.0128 | |
4. Assume neutral axis depth | At the N2 section: 27.61 mm At mid-span section: 10.26 mm | At support sections (N3 and N4): 27.64 mm At mid-span section: 10.26 mm |
5. Compute FRP stress (ffe), FRP strain (εfe), and concrete strain (εc) | At the N2 section = = 0.0124 = 0.0116 = = 0.0028 = 0.0116(40,000) = 463.86 MPa At mid-span section = = 0.0058 = = 0.003 = 0.0058(40,000) = 230.97 MPa | At support sections = = 0.0125 = 0.0116 = = 0.0028 = 0.0116(40,000) = 463.86 MPa At mid-span section (same as the end span case) |
6. Compute reinforced steel stress (fs) and strain (εs) | At the N2 section = = 0.0084 = = 1680 MPa At mid-span section = = 0.0382 = 0.0382(200,000) = 7640 MPa > | At the support sections = = 0.0083 = 0.0083(200,000) = 1660 MPa > = 410 MPa At mid-span section (same as the end span case) |
7. Check the equilibrium condition | At the N2 section, due to = = 0.002; = = 0.807 = = 0.922 = = 27.61 mm (OK) At mid-span section, due to = 0.65; = 0.85 = = 10.26 mm (OK) | At support sections, due to = = 0.002; = = 0.806 = = 0.923 = = 27.64 mm (OK) At mid-span section (same as the end span case) |
8. Compute strength in flexure and shear 8.1 Compute strength in flexure at the support section | = = 17.27 kNm = = 55.89 kNm = = 58.29 kNm | = = 17.27 kNm = = 55.89 kNm = = 58.29 kNm |
8.2 Compute strength in flexure at the mid-span section | = = 24.04 kNm = = 5.54 kNm = = 25.88 kNm | same as end span case |
8.3 Compute strength in shear | = = 99.23 kN | same as end span case |
9. Define design factored load | = = 53.6 kN/m = = 53.6 kN/m = = 66.38 kN/m | = = 71.46 kN/m = = 71.46 kN/m = 82.68 kN/m |
10. Define failure mode and failure load | DB-3aen according to Figure 6a Equation (18), = = 66.38 kN/m | DB-2in according to Figure 6b Equation (21), = = 82.68 kN/m |
Adjust iteratively CFRP thicknesses to achieve ductile failure mode | It can be achieved with tF = 0.53 mm; wu = 51.05 kN/m; failure mode D-3en; = 62.95 kN/m, as shown in Figure 9a. | It can be achieved with tF = 0.62 mm; wu = 68.92 kN/m; failure mode D-2in; = 82.38 kN/m. However, to be consistent with the end span, tF = 0.53 mm; wu = 68.17 kN/m; failure mode D-2in; = 76.48 kN/m, as shown in Figure 9b. |
Span | Failure Mode | wu (kN/m) | wf (kN/m) | tF (mm) | ||
---|---|---|---|---|---|---|
Existing end span | D-2en | 24.70 | [100%] | 31.30 | [100%] | - |
Retrofitted end span | D-3en | 51.05 | [207%] | 62.95 | [201%] | 0.53 |
Existing interior span | D-1in | 32.00 | [100%] | 39.20 | [100%] | - |
Retrofitted interior span | D-2in | 68.92 | [215%] | 82.83 | [211%] | 0.62 |
Retrofitted interior span (for consistency) | D-2in | 68.17 | [213%] | 76.48 | [195%] | 0.53 |
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Nguyen, H.Q.; Han, T.H.; Park, J.K.; Kim, J.J. A Design Process for Preventing Brittle Failure in Strengthening RC Slabs with Hybrid FRP-HPC Retrofit Systems. Materials 2023, 16, 755. https://doi.org/10.3390/ma16020755
Nguyen HQ, Han TH, Park JK, Kim JJ. A Design Process for Preventing Brittle Failure in Strengthening RC Slabs with Hybrid FRP-HPC Retrofit Systems. Materials. 2023; 16(2):755. https://doi.org/10.3390/ma16020755
Chicago/Turabian StyleNguyen, Huy Q., Taek Hee Han, Jun Kil Park, and Jung J. Kim. 2023. "A Design Process for Preventing Brittle Failure in Strengthening RC Slabs with Hybrid FRP-HPC Retrofit Systems" Materials 16, no. 2: 755. https://doi.org/10.3390/ma16020755
APA StyleNguyen, H. Q., Han, T. H., Park, J. K., & Kim, J. J. (2023). A Design Process for Preventing Brittle Failure in Strengthening RC Slabs with Hybrid FRP-HPC Retrofit Systems. Materials, 16(2), 755. https://doi.org/10.3390/ma16020755