Application of Tensioned CFRP Strip Method to an Existing Bridge

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SP-230 66 Application of Tensioned CFRP Strip Method to an Existing Bridge by A. Tateishi, A. Kobayashi, Y. Hamada, T. Takahashi, and H. Yasumori Synop nopsis: s: Tensioned carbon fiber reinforced polymer (CFRP) strip method or Outplatemethod TM was applied to the 28 years old reinforced concrete (RC) box girder bridge in order to rehabilitate and increase the load capacity of the bridge. The Chofu Bridge had been deteriorated by 28 years of heavy traffic and had many cracks on the underside of the main girders. Before and after the CFRP application, on-site load tests of the bridge were conducted using a 45 ton-weight vehicle. Results of the tensioned CFRP strip application to the bridge girders proved effective to reduce the stress in the reinforcing bars and to reduce crack widths. Keywords: anchor; prestress; stiffness; strengthening method; tensioned CFRP strip 1177

1178 Tateishi et al. Akihiro Tateishi is a member in the technical development department at Nippon steel composite Co., Ltd. His research interests relate to the durability of concrete structures and generated aged deterioration. He is a member of JSCE and JCI. Akira Kobayashi is a manager in the technical developing department at Nippon steel Composite Co., Ltd. His current research interest is retrofitting of concrete members of bridge structures with continuous fiber sheets or FRP plates. He is a member of JSCE and JCI. Yuzuru Hamada is a manager at the Research and Development Center of DPS Bridge Works Co., Ltd. He received his Doctor of Engineering Degree from Ritsumeikan University in 2002. His research interests relate to the durability and maintenance of prestressed concrete structures. He is a member of JPCEA, JCI and JSCE. Terumitsu Takahashi is a manager in the maintenance team of technical development department of DPS Bridge Works Co., Ltd. His current research interest is the durability and maintenance of prestressed concrete structures. He is a member of JPCEA, JCI and JSCE. Hiroshi Yasumori is a manager in the design department of DPS Bridge Works Co., Ltd. His current research interest is application of tensioning systems and maintenance of prestressed concrete structures. He is a member of JPCEA and JSCE. INTRODUCTION Recently in Japan, many bridges have experienced damage and deterioration resulting from heavy traffic and many years of natural exposure. Many rehabilitation methods, such as steel plate bonding, concrete overlays, externally bonded carbon fiber sheets, and external cable method such as post-tensioning, have been tried. At the Chofu bridge, which is reinforced concrete (RC) box girder bridge, many cracks had formed and water leakage from the cracks was observed at several locations (shown in Photograph 1). Also, the deflection of the main girders caused by the heavy traffic increased and the decreased stiffness of the bridge became obvious. In order to rehabilitate this bridge, passive applications such as steel plate or carbon fiber sheet bonding methods without prestressing is not enough. In order to both increase the load capacity and decrease the crack width, an external cable post-tensioning would have been used. But in this case, restriction of the application spaces, flat surface terrain, and weak concrete not suitable for attaching the brackets, made it impossible to apply external cables. Also, in-situ application was needed because the bridge has interchange ramps and it was very difficult to stop the traffic. So, the new prestressing method was needed. Tensioned CFRP strip method (Outplate Method TM ) The tensioned CFRP strip method consists of a tension plate, base plates, and

FRPRCS-7 1179 intermediate anchoring devices. The tension plate is a carbon fiber reinforced polymer (CFRP) strip that has anchoring devices at both ends. Base plates are steel frame which are attached to the concrete surface for anchoring the tension plate and for holding the specially modified hydraulic jack. And intermediate anchoring devices are simple stainless steel plates and anchor bolt (Shown in Figure 1). First, the concrete at both ends of the main girders is chipped away and the base plates are attached with anchor bolts. Then, the hydraulic jack, which is specially modified for this application, is set onto one of the base plates. One of the anchoring devices of the tension plate is bolted to the other base plate, and the other anchoring device is attached to the hydraulic jack. Before tensioning the tension plate, adhesive paste is put on the upper surface of CFRP strip. By tensioning the tension plate, compressive stress is introduced to the concrete girder. The CFRP strip is then adhered to the concrete surface. After tensioning, intermediate anchoring devices are attached with anchor bolts. Using this procedure, tensioned CFRP strips are applied in-situ to the underside of the main girders inside the bridge span as shown in Photograph 2. Advantages One of the most advantageous points of this method is that by applying prestress to the concrete member, this method is effective in increasing not only the live load but also the dead load capacity of the member. Therefore, crack widths caused by dead load can be decreased by applying this method, which is very difficult by applying carbon fiber sheets passively. Another advantage is that by introducing a prestress, a redundant force is introduced to the upper surface of the continuous bridge girder, so the tensile stress on the intermediate fulcrum is decreased. In other words, the upper surface of the intermediate fulcrum is also reinforced by this underside application. The distribution of bending moment is schematically shown in Figure 2. A tension plate is a thin material, so it can be applied to very narrow spaces. Also, since the introduced prestress is not too large (around 140 kn), the concrete damage at the anchoring area is minimal. In the case of external cable post-tensioning, concrete damage at the anchoring area is sometimes so large that additional reinforcement at the anchoring area is required. Specification of tension plate The CFRP strip is 2mm thick and 50mm wide. Each end of the strip is inserted into an anchoring device which is made of steel. Both ends are embedded and anchored by an expansive paste. The CFRP strip is made up of high strength carbon fibers and thermo-setting resin, fabricated using a Pultrusion method. Characteristics of the CFRP strip are shown in Table 1. The expansion pressure and the embedment length were determined from the results of the tensile test [2]. Tensioning system A hydraulic jack is specially designed for this application. It is divided into two parts (a reaction block and a cylinder) and each part is very light weight, so each one can be handled by one person. Also the weight of a base plate is saved in order to handle it by

1180 Tateishi et al. two persons. This tensioning system does not need reaction frame. The hydraulic jack is attached directly to the base plate so the girder itself becomes the reaction frame [3]. Application At the Chofu bridge, the Outplate Method TM was adopted because of its effectiveness to reduce dead load stress and dead load deflection, because the prestress level of this method is suitable to the present condition, it is reasonably economical, and it s application period is dramatically short. The number of tension plates (CFRP strips) was determined by matching the allowable tensile stress in the longitudinal reinforcing bars considering the dead and live load bending moments, compressive stress, eccentric bending moment, and redundant force introduced by prestressing. As a result, six pieces of CFRP strip were installed at the bottom of each of the RC box girders at each of the bridge spans. Only under the center span of the bridge was the carbon fiber sheet method also applied because tensioned CFRP strip method alone was not adequate to increase the load bearing capacity of the span sufficiently. Allocation of CFRP strips and application procedure are shown in Figure 3 and Figure 4, respectively. OUT LINE OF TESTS A load test of the existing bridge was carried out to verify the strengthening effect. A prestress introducing test was also conducted to examine the soundness of the concrete at the anchoring devices. Finite Element (FE) analysis was done and results were compared with measured values. Load test A 45 ton-weight vehicle (shown in Photograph 3) was placed statically at three different positions, shown in Figure 5.The stress in the longitudinal reinforcing bars, concrete crack width and depth, and deflection of the main girder were measured during the load test, which were performed both before reinforcing and after the tensioned CFRP strip application. The 450kN (45 ton-weight) load corresponds to 26.3% of the design live load at the center of the side span. Measurement points are shown in Figure 6. In addition to static load tests, dynamic load tests were also conducted by driving 45 ton-weight vehicle at a speed of 50km/h in the traffic lane, while all other traffic was stopped. The test was performed at night. During the dynamic load test, the natural frequency of the main girder was measured. Prestress introducing test A prestress introducing test was carried out at the two CFRP strips applied to the center web. Each CFRP strip was tensioned to a 160kN force. The stress in the longitudinal reinforcing bars and concrete, and crack widths in the concrete were measured at the center of the span and at the vicinity of the anchoring devices. Measurement points are shown in Figure 7.

RESULTS AND DISCUSSION FRPRCS-7 1181 Load test Tensile stress in the longitudinal reinforcing bars -- Observed tensile stresses in the longitudinal reinforcing bars under loading are shown in Table 2. Stresses in the longitudinal reinforcing bars were calculated by multiplying the measured strain with its Young s Modulus of Elasticity 200,000N/mm 2. At point S1 (center of the span, center in the direction of span-width), the tensile stress before reinforcing was 9.8N/mm 2 and after the tensioned CFRP plate application was 7.8N/mm 2. The latter was 20% smaller than the former. It was confirmed that the stress in the longitudinal reinforcing bar was decreased with the introduction of prestress by the tensioned CFRP strip method. Concrete crack width and depth -- Observed concrete crack width and depth under loading are shown in Table 3 and Table 4, respectively. At point C2 (center of the span, center in the direction of span-width) the crack width decreased from 0.226mm to 0.188mm after reinforcing (16.8% smaller) and, also the crack depth decreased from 153mm to 138mm after reinforcing (9.8% smaller). It was confirmed that crack opening and extension were restricted with the introduction of prestress by the tensioned CFRP strip method. Deflection -- Observed deflections under loading are shown in Table 5. At point D1 (center of the span, center in the direction of span-width) deflection after reinforcing was decreased by 30% from 1.53mm to 1.07mm. Deflection was decreased by 40% from 1.88mm to 1.12mm at point D2 (center of the span, edge side in the direction of span-width). Thus, it is clear that the stiffness of main girder improved dramatically. Natural frequency -- Observed natural frequency of the primary mode was improved from 4.4Hz before reinforcing to 5.2Hz after reinforcing. This increase of natural frequency corresponds to a mean decrease of amplitude, in other words, decrease of deflection. Therefore, this dynamic load test result corresponds to the observed reduction in deflection during the static loading test. An eigenvalue analysis was conducted with a Finite Element Method (FEM) model calculated assuming that there is no cracking of the concrete, shown in Figure 8. The natural frequency of the primary mode was determined to be 5.393Hz and this value was found to be very close to the measured value after reinforcing application. This result implies that the rigidity of the main girder was improved by this reinforcing method. Prestress introducing test Compressive Stress in the longitudinal reinforcing bar -- Observed results are shown in Table 7. The stress in the longitudinal reinforcing bar was calculated by multiplying measured strain by its Young s Modulus of Elasticity 200,000N/mm 2. The compressive stress in the longitudinal reinforcing bar at the center of the span (S1) was 2.4N/mm 2

1182 Tateishi et al. after tensioning two CFRP strips. This value agreed well with the 2.56N/mm 2 stress calculated in the FEM analysis. Therefore, it was confirmed that required prestress was introduced by tensioning two CFRP strips. Concrete Crack width -- Observed results are shown in Table 8. Concrete crack width at the center of the span (C2) was decreased 0.015mm after tensioning two CFRP strips. In order to verify this result, the crack width was calculated by using the crack width equation reported in reference [4]. Taking into account the effect of introducing prestress into the CFRP strip, the crack width was calculated to be 0.02mm. There was an excellent agreement between measured value and calculated value. Tensile stress in concrete -- The tensile stress in the concrete at the vicinity of the anchoring devices is shown in Table 9. Concrete stress was calculated by multiplying measured strain by its Young s Modulus of Elasticity 25,000N/mm 2. After the CFRP strips are tensioned, tensile stress occurs in the concrete behind the anchoring devices. This stress was a maximum of 0.55N/mm 2. Compared with a stress of 1.4N/mm 2 calculated with the FEM analysis and cracking limit of 1.9N/mm 2 reported in reference [4], the measured value was small enough and very far from the stress which induces concrete cracking. Therefore, it was confirmed that the tensioned CFRP strip method is a safe method for the concrete even when the concrete strength is relatively small. CONCLUSION Load tests of an existing bridge reinforced with the tensioned CFRP strip method were carried out and the strengthening effect was evaluated. The most distinguished effects of this repair were the decrease of deflection at the center of the span and an increase in the natural frequency of the primary mode. These effects imply that the stiffness of the main girder was improved. Load-carrying capacity and durability of the main girder is expected to improve due to the reduction in stress in the reinforcing bars and reduction in concrete cracking. Moreover, it was confirmed that the concrete in the vicinity of the anchoring area was sound enough even after the CFRP strip was tensioned, because the induced tensile stress into the concrete is quite small compared with the cracking limit. Therefore, the tensioned CFRP strip method is considered to be a very effective strengthening method for reinforced concrete bridges.

REFERENCES FRPRCS-7 1183 [1] Fujita, M.; Matsuda, Y.; Takahashi, T.; Imura, M.; and Komada, K., 2004, October, Retrofit of Chofu Viaduct by Out Plate Method and its Loading Test, Bridge and Foundation Engineering, pp.15-19 (in Japanese) [2] Kojima, T.; Takagi, N.; Inoue, M.; Hamada, Y.; and Kobayashi, A., 2001, Flexural Strengthening of Bridge by Using Tensioned Carbon Fiber Reinforced Polymer Plate, Proceedings of Third International Conference on Concrete under Severe Conditions Environment and loading, Vol. 3 [3] Yasumori, H.; Takahashi, T.; Hamada, Y.; and Kobayashi, A., 2003, October, Development of Tensioning System with Carbon Fiber Reinforced Polymer, Prestressed Concrete Engineering Association, The 12th symposium, (in Japanese) [4] Japan Society of Civil Engineers: Standard Specifications for Concrete Structures-2002 Structural Performance Verification, Mar. 2002 (in Japanese)

1184 Tateishi et al.

FRPRCS-7 1185 Photograph 1 State of damages Photograph 2 Applied tensioned CFRP strip Photograph 3 45 ton-weight vehicle

1186 Tateishi et al. Figure 1 Tensioning system Figure 2 Distribution of bending moment

Figure 3 Allocation of CFRP strips FRPRCS-7 1187

1188 Tateishi et al. Figure 4 Application Procedure Figure 5 Loading points

FRPRCS-7 1189 Figure 6 Measurement points of load test Figure 7 Measurement points of prestress introducing test Figure 8 Primary mode (FEM)

1190 Tateishi et al.

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