Study on the Structural Performance of UHPC Pavement and Hinge Joint Reinforcement for Hollow Slab Girder Bridges
Abstract
:1. Introduction
2. Background Engineering
3. Structural Method of Reinforcement and Construction Stages
3.1. Theoretical Basis of Hollow Girder Reinforcement
3.2. Reinforcement Method
- (1)
- The previous pavement layer is completely removed and replaced with UHPC and stone matrix asphalt (SMA).
- (2)
- Partial removal of the previous pavement, which is followed by the addition of a thin layer of UHPC and SMA is added.
3.3. Construction Stages
- (1)
- Traffic Closure
- (2)
- Removal of the top pavement and hinged concrete
- (3)
- Reinforcing bars
- (4)
- Laying rebar in the pavement layer
- (5)
- The surface of the slab girder was cleaned completely and the debris and rubbish generated by the planting rebar were removed (Figure 6b).
- (6)
- UHPC construction of the pavement layer
- (7)
- Adhesive layer structure
- (8)
- Curing
- (9)
- Bridge deck asphalt concrete paving construction
- (10)
- Clean up the site and open it up to traffic.
4. Verification and Monitoring of the Reinforcement Effect
4.1. Deflection Monitoring
4.2. Strain Monitoring of Hinge Joint
4.3. Adhesion between UHPC and the Girder
5. Data and Analysis
5.1. Strain Characteristics after Reinforcement
5.2. Changes in Structural Stiffness after Reinforcement
6. Conclusions
- (1)
- The designed bridge deck pavement adopted 8 cm thick UHPC and 4 cm modified asphalt concrete pavement, the transverse load-bearing performance of the beam slab was enhanced, and the overall bearing capacity was improved. Based on the conclusions of other researchers and the performance of UHPC, the UHPC thickness can be optimized.
- (2)
- Several researchers have already proved that the effect of planting reinforcement on the joint surface between the UHPC and the main girder is significant. This allows the original concrete layer and the UHPC layer to be more closely connected. Rebars planted at the hinge joint with UHPC greatly improve the transmission capacity of the transverse force between the slab girders.
- (3)
- In terms of the performance of the bond between the UHPC and the bridge, according to the stress analysis of the monitored rebar and UHPC, the change in the stress on the hinge joint was mainly tensile at less than 55 με and the amplitude was less than 10 με. Judging from the similarity of the strains of the two types of gauges, the rebar and the UHPC maintain a good synergistic effect.; The shear deflection of the hinged joint due to the change in the beam was not obvious, which proves that the UHPC pavement had a positive impact.
- (4)
- Monitoring the amplitude of the reinforced bridge deck proved that the overall performance of the bridge reinforced with UHPC was significantly improved. The minimum and maximum amplitudes after reinforcement (minimum −1.5~−1.0 mm, maximum 0.75~1.25 mm) were reduced by half compared to before reinforcement (minimum: −3.0~−2.0 mm, maximum 2.0~3.0 mm).
- (5)
- The improvement in the flatness of the bridge surface has a positive effect on reducing bridge vibration. The resistance to the deformation of the UHPC pavement layer was relatively excellent, and the bond between the UHPC and girders was also very strong without delamination. It should be noted that the bridge pavement and hinge joints were repaired at the same time, which affected their respective contributions to a certain extent.
- (6)
- Since the reinforced pavement with reinforced hinges already increased the mechanical performance and affected the load distribution of each girder, the new theoretical calculation method for the live-load distribution factor should be restudied. The monitoring data from real bridges can play an auxiliary role in static load testing to verify the theoretical method.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Item | Test Code | Performance Index | |
---|---|---|---|
Requirements | Measured Value | ||
Initial slump expansion/mm | GB/T50080 | 600–700 | 655 |
1 h slump expansion/mm | GB/T50080 | 550–650 | 637 |
Compressive strength/MPa | GB/T31387 | ≥120 | 133.6 |
Tensile strength of elastic section/MPa | Swiss SIA2052 | ≥7 | 10.1 |
Ultimate tensile strength/MPa | Swiss SIA2052 | ≥8 | 13.9 |
Ultimate tensile strain/% | Swiss SIA2052 | ≥0.2 | 0.45 |
Ultimate tensile strength/tensile strength of elastic section | Swiss SIA2052 | ≥1.1 | 1.38 |
Flexural tensile strength/MPa | GB/T31387 | ≥22 | 26.1 |
Shrinkage (28 d) | GB/T50082 | <250 | 136 |
Measuring Point | Maximum Amplitude | Minimum Amplitude | Average Amplitude | |||
---|---|---|---|---|---|---|
Before Reinforcement | After Reinforcement | Before Reinforcement | After Reinforcement | Before Reinforcement | After Reinforcement | |
1 | 2.204 | 1.047 | −4.502 | −1.155 | −0.766 | −0.373 |
2 | 2.822 | 1.123 | −2.830 | −1.241 | −0.140 | −0.154 |
3 | 2.301 | 0.807 | −1.978 | −1.274 | −0.632 | −0.468 |
4 | 3.183 | 0.854 | −2.977 | −1.291 | −0.641 | −0.414 |
5 | 2.067 | 1.107 | −2.746 | −1.344 | −0.729 | −0.309 |
6 | 2.822 | 1.186 | −2.830 | −1.382 | −0.140 | −0.229 |
7 | 2.197 | 1.334 | −1.978 | −1.624 | −0.634 | −0.265 |
8 | 2.822 | 1.290 | −2.830 | −1.152 | −0.140 | −0.016 |
9 | 3.099 | 1.220 | −2.667 | −1.246 | −0.145 | −0.036 |
10 | 2.282 | 1.068 | −2.830 | −1.288 | −0.304 | −0.216 |
11 | 2.822 | 1.049 | −2.830 | −1.397 | −0.259 | −0.216 |
12 | 3.073 | 1.101 | −2.630 | −1.037 | −0.124 | −0.051 |
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Ye, W.; Li, F. Study on the Structural Performance of UHPC Pavement and Hinge Joint Reinforcement for Hollow Slab Girder Bridges. Appl. Sci. 2022, 12, 12008. https://doi.org/10.3390/app122312008
Ye W, Li F. Study on the Structural Performance of UHPC Pavement and Hinge Joint Reinforcement for Hollow Slab Girder Bridges. Applied Sciences. 2022; 12(23):12008. https://doi.org/10.3390/app122312008
Chicago/Turabian StyleYe, Wenya, and Fangyuan Li. 2022. "Study on the Structural Performance of UHPC Pavement and Hinge Joint Reinforcement for Hollow Slab Girder Bridges" Applied Sciences 12, no. 23: 12008. https://doi.org/10.3390/app122312008
APA StyleYe, W., & Li, F. (2022). Study on the Structural Performance of UHPC Pavement and Hinge Joint Reinforcement for Hollow Slab Girder Bridges. Applied Sciences, 12(23), 12008. https://doi.org/10.3390/app122312008