KR101182541B1 - Multi-Span Continuous Prestressed Concrete I-Girder Bridges and Construction Method of Such Bridges - Google Patents

Abstract

PURPOSE: A multi-span continuous PSC I-girder bridges and a construction method thereof are provided to secure bridge performance and long lifetime through tendons for maintenance. CONSTITUTION: A construction method for multi-span continuous PSC I-girder bridges is as follows. A primary prestress is applied by locating a primary tendon in a primary tendon sheath. A PSC I-girder for a primary span(40a) and a PSC I-girder for a secondary span(40b) are held on the primary span and the secondary span respectively. The PSC I-girders of the both sides of the spans are integrated with each other. A secondary tendon and a primary additional tendon(61) are arranged to form curvature. The PSC I-girder for a primary span and the PSC I-girder for a secondary span are covered to construct a slab. The continuously arranged secondary tendon is mounted on the non-continuous anchorage portions of the PSC I-girder for a primary span and the PSC I-girder for a secondary span. Each mounting part is protected with waterproofing mortar and a continuously arranged upper structure system is constructed by constructing concrete to a block-out portion.

Description

Multi-Span Continuous Prestressed Concrete I-Girder Bridges and Construction Method of Such Bridges}

The present invention relates to a prestressed concrete I-girder bridge and its construction method, specifically, a prestressed concrete I-girder (hereinafter abbreviated as "PSC I-girder") and slab In bridges with a composite structural system, the entire span of the bridge is efficiently continuous, and additional prestressing (hereinafter referred to as the term "tension") is introduced in order to reduce the load capacity and usability of the bridge in common. By providing the plan from the construction stage, not only can the construction and structural efficiency be improved, the economical efficiency and the driving and maintenance of the vehicle can be greatly improved, and the effect of improving the bridge performance and life extension in common by the continuous tendon for maintenance The present invention relates to a PSC I-girder multi-span continuous bridge and its construction method.

The most conventional construction method of the conventional PSC I-girder bridge is to design and manufacture the girders as simple girders respectively. After completing all the tensions to resist dead and live loads at the production site, they are transported to the site and mounted on the pier. The bridges have been completed by the construction of the slab, and even in the case of two-stage continuous construction, the girders have been designed, manufactured and mounted as simple girders, respectively, and only two slabs have been continuously installed.

According to the prior art as described above, the slab can be continuous, but since the girder, which is the main member, does not play the role of the continuous beam, it cannot be a true continuous bridge. Recently, a method of implementing a form of a continuous bridge by installing a continuous tendon on both side girders that are continuously disposed adjacent to each other has been proposed, and the present inventors have disclosed the first span of the bridge through the Republic of Korea Patent No. 10-1129911 (left side). After the first tendon is tensioned in the first span from the shift, the second spanning tendon placed on the first span PSC girder is installed after mounting the prestressed concrete (PSC) girder for the first span and the slab concrete. By using tension to set the left discontinuous fixing part of the first span and the continuous fixing part of the right part to complete the first span girder and slab construction, and subsequently to the second span PSC girder for which the primary tendon is strained. Mounted on the span and connected to the 2nd continuous tendon for the continuity with the 1st span at the right fixing part of the 1st span and placed in the 2nd span PSC girder and slab on the 2nd span PSC girder After the construction and the secondary tension and fixing a continuous wire from the right side of the second fixing portion disposed on the PSC girder span for the second span proposed a method of completing a two-span continuous bridge.

Despite the technology proposed by the present inventors, in the actual bridge construction, there is still a need to reduce the construction period and construction cost, and furthermore, the necessity of reducing the joint portion through the simultaneous simultaneous construction of the girder and the slab between two spans There is a need to prepare for a decrease in performance during public and public use.

Republic of Korea Patent Registration No. 10-1129911 (Notice date 2012. 3.27.)

The present invention was developed to solve the above problems, and in a bridge using a PSC I-girder, provided with a maintenance fixing unit suitable for the working load and structural behavior of a multi-span continuous bridge, and a continuous tendon for maintenance. By constructing the first span and the second span at the same time, two spans can be rapidly formed at the same time, and from the third span that follows, a more reasonable PSC I-girder multi-span continuous bridge is formed to efficiently continuous the entire bridge. It aims to provide the construction method.

Specifically, in the present invention, in a bridge having a composite structural system of PSC I-girder and slab, the first two spans of the bridge (first span and second span from the left shift) are simultaneously constructed and continuous, followed by the following From the third span, construction is continued one by one in succession, so that the entire span of the bridge can be efficiently continually installed, and a continuous tendon for maintenance is installed at the construction stage to further reduce the load capacity and usability during the common use of the bridge. In addition, the PSC I-girder multi-span continuous bridge and its construction method are provided to increase the construction and structural efficiency, greatly improve the economics, the driving and the ease of maintenance, and to extend the performance and the life of the bridge.

In particular, in the present invention, by installing a maintenance fixing unit for additional tension in common on the side of the PSC I-girder at the construction stage, and the maintenance continuous tendon is arranged in the girder cross section suitable for the structural behavior of the continuous bridge In order to improve the load capacity and usability during the use of the bridge, and to optimize the cross-section of the PSC I-girder, the tension is divided into the primary tendon and the secondary tendon for each stage of construction and mounting. Tension the primary tendons to resist slabs of slabs and simultaneously mount them on the piers of the first two spans, namely the first span and the second span, and resist the additional dead load (packing) and live load (vehicle load) in these two spans. After the secondary tendons are installed in series and the slabs are installed at the same time, the secondary tendons are simultaneously tensioned at the left anchorage of the first span and the right anchorage of the second span. High settling and sequential construction of the two spans are carried out at once, followed by the construction of the subsequent third span girders and slabs, and then connecting the secondary tendons to the right continuous fixtures of the second spans. By tensioning, the third span is continuous, and the subsequent spans below the fourth span are also constructed in the same way as the third span, and are continuously continuous by one span. The multi-span continuous bridge using the PSC I-girder and its construction method are greatly improved, and the economical efficiency and maintenance efficiency are greatly improved by improving the performance and extending the service life by the continuous tendon for maintenance.

In the present invention, in order to achieve the above object, the primary tendon fixing unit is provided at both ends of the girder, and the secondary tendon discontinuous fixing unit is provided on the upper surface of each alternating end, and the alternate end of the girder is provided. Both sides are equipped with a fixing block for fixing additional tension tendons that can be additionally tensioned for maintenance during public use, and a sheath for primary tendons, a secondary tendon sheath and an additional tension tendon sheath are embedded in the interior. The secondary tendon sheath and the additional tendon tendon sheath are buried in a curved shape so as to be located at the bottom of the girder and at the upper slab at the pier position of the continuous point, and the protruding cast iron bars at the pier end of the continuous point. Manufacturing a first spanning PSC I-girder and a second spanning PSC I-girder, each of which is provided with a girder connecting steel sheet at an end portion thereof; After the primary tendons are placed on the sheath for primary tendons so as to resist the girder weight and the slab dead weight on each of the first span PSC I-girder and the second span PSC I-girder, The first spanning PSC I-girder and the second spanning PSC I-girder are mounted simultaneously on the first span and the second span, respectively, and on the bridge piers, which are continuous points, are mounted on a single bridge support and the first span PSC I-girder. Directly connect the end protruding main reinforcing bars of the second span PSC I-girder facing the end protruding main reinforcing bars of the girder, and fix the lower part of the pier end of both PSC I-girders to the girder connecting steel plate to integrate them. Thereby continuously integrating the PSC I-girder between the two sides of the span; The secondary tendon and the first additional tension tendon are inserted into the secondary tendon sheath and the first additional tension tendon, respectively, and are continuously arranged in a curve so as to be continuous between the first span and the second span. In the position, the slab passes through the inside of the slab and is positioned below the center of the first span and the second span, and concrete is placed on the first span PSC I-girder and the second span PSC I-girder. Constructing the slab at the same time, so that a blockout portion for tension of the secondary tendon is present in the slab; And discontinuous fixing portions of the first spanning PSC I-girder and the second spanning PSC I-girder, the secondary tendons disposed in succession to the first spanning PSC I-girder and the second spanning PSC I-girder. After the tension and fixation at the discontinuous fixing part at the same time, and protect each fixing part with a waterproof mortar and construct concrete at the block-out part to build an integrally continuous superstructure system. There is provided a PSC I-girder continuous bridge construction method characterized in that the construction of the bridge.

In addition, in the present invention, in order to construct a three-span continuous bridge in the above manner, in the above-described configuration, during the fabrication of the second span PSC I-girder, in the central side side of the additional tension tendon which is continuous with the third span Fixing block is further provided for, and further comprising a protruding cast steel reinforcement and a girder connecting steel plate at the end of the third span direction, so that the continuous fixing portion is also formed at the end of the third span direction, the second span PSC I-girder is Manufacturing to be a medium span PSC I-girder; Girder side of the alternate end of the third spanning PSC I-girder is made of a third spanning PSC I-girder to be installed after the second spanning PSC I-girder. In the second span PSC I-girder is provided with a fixing block for the fixing of the second additional tension tendon is disposed in succession, the second span PSC I-girder is provided in the end direction of the protruding cast reinforcing bar and the girder connecting steel plate Fabricating the third spanning PSC I-girder so as to; To face the second spanning PSC I-girder, a third spanning PSC I-girder is mounted on the third span after the second spanning PSC I-girder, and the second spanning PSC I-girder and the second spanning Secure the opposite ends of the three-span PSC I-girder to the girder connecting steel plate, connect the protruding cast bars of the opposite ends to each other, and then cast concrete on the girder connections between the opposite ends to Continuously integrating the girder; In the position of the girder connection, the secondary tendon and the additional tension tendon are respectively disposed in the third span PSC I-girder so as to pass through the inside of the slab and be positioned downward in the center of the third span PSC I-girder. One end of the secondary tendon of the spanning PSC I-girder is arranged in connection with the tendon coupler at the continuous anchoring portion of the second spanning PSC I-girder, and the additional tensioning tendon is the central portion of the second spanning PSC I-girder. Connecting and arranging from the fixing block installed on the side to the fixing block provided on the side of the alternating end of the third spanning PSC I-girder, and then constructing the slab on the third spanning PSC I-girder; And tensioning and fixing the secondary tendons disposed in the third span PSC I-girder at the discontinuous fixing portions formed at the alternating end portions of the third span, and then protecting each fixing portion with a waterproof mortar and PSC I-girder continuous bridge construction method is characterized in that the bridge is constructed in a three-span continuous form, including the step of constructing an integrally continuous superstructure system by pouring.

In addition, in the present invention, as a method for constructing a continuous bridge of four spans or more, in the above-described configuration, in the fabrication of the second span PSC I-girder, a fixing for fixing an additional tension tendon continuous with the third span on the side of the center portion Blocks are further provided, and protruding cast steel bars and girder connecting steel plates are further provided at the end portions of the third span direction, and continuous fixing parts are formed at the end portions of the third span direction so that the second span PSC I-girder is used for the intermediate spans. Fabricating to be a PSC I-girder; Intermediate spanning PSC I-girder to be installed after the second spanning PSC I-girder, the longitudinal fixing portion is formed on the rear end in the longitudinal direction, and the subsequent span on the central side of the intermediate spanning PSC I-girder And a fixing block for fixing the additional tension tendon to be continued with the second step, and manufacturing the intermediate span PSC I-girder so that the projecting cast steel and the girder connecting steel plate are provided at the end of the subsequent span. The intermediate span PSC I-girder subsequent to the second spanned PSC I-girder, the connection between the projecting cast steel bar between the second spanned PSC I-girder and the subsequent intermediate spanned PSC I-girder, girder connecting steel sheet To perform continuous integration of the PSC I-girder on both sides by concrete placement at the fixed and girder connection at the end of the bridge, and to arrange the secondary tendon and the additional tension tendon on the intermediate span PSC I-girder, The secondary tendons are connected by a tendon coupler at the continuous fixation part of the PSC I-girder for the PSC I-girder. The fixing block installed on the central side of the second spanning PSC I-girder to the fixing block installed on the end side of the intermediate spanning PSC I-girder in the same form as the secondary tendon, and then Construct a slab on the intermediate span PSC I-girder, tension the secondary tendons disposed on the subsequent intermediate span PSC I-girder at the continuous anchorage of the intermediate span, and fix the first span PSC I-girder. A final spanning PSC I-girder having the same configuration as the above is manufactured, and the final spanning PSC I-girder is subsequently mounted on the intermediate spanning PSC I-girder, and the intermediate spanning PSC I-girder and the final span PSC I-girder between the projecting reinforcing bars between the PSC I-girder, fixed on the girder connecting steel plate, and concrete placing at the girder connection, performs continuous integration operation of the PSC I-girder for the intermediate span Secondary tendons and additional tension tendons are placed between the final spanning PSC I-girder and the first slab is constructed, and then the secondary tendons are tensioned and settled at the discontinuous anchorages of the final spanning PSC I-girder, respectively, for settlement. Protect the wealth with waterproof motor The PSC girder I- multi-span continuous bridge construction method is provided, characterized in that the block construction of the span continuous bridge having a plurality of span-span for more than 4 by the end of the cast-in-place concrete in-out portion.

In addition, the present invention provides a PSC I-girder multi-span continuous bridge which is constructed by the above-described construction methods.

In the present invention, the first two spans of the bridge, that is, the first span and the second span are divided and constructed, and then not continuously formed, but are directly connected to each other by simultaneously mounting the first span and the second span of the PSC I-girder. Two slabs at once (first span and second span) by simultaneously tensioning and fixing the sequential tendons of two spans for this composite section at the left anchorage of the first span and the right anchorage of the second span. Will be completed). Therefore, it is possible to greatly shorten the construction period of the bridge than the prior art, and also has a great effect in terms of structural integrity and continuity and reducing the construction joint. In other words, according to the present invention, the continuous tendon of the PSC I-girder bridge is capable of tensioning only the tendon in a single span at one anchorage due to the curve arrangement of the dendon, and thus, the first span and the second span at the second span. By constructing girders and slabs at the same time and simultaneously tensioning at the left end of the slab between the first span and the right side of the slab between the second span, the two spans can be quickly and continuously integrated and integrated to shorten the construction period and provide better structural integrity than the prior art. It will be secured.

In the case of continuous bridges of 3 spans or more, as described above, the first two spans are constructed at the same time to achieve two-sequence continuity, followed by the construction of the following third span girders and slabs, and the continuous tendon second span, which is the last span. By connecting to the right continuous fixing part of the tension and fixation in the right fixing unit of the third span, it is possible to achieve the continuity up to the third span quickly and conveniently. Continuous bridges of more than 4 spans are constructed and sequentially constructed one by one in the same process and method as the third span. Therefore, the entire bridge can be freely constructed as the number of spans as desired. Therefore, according to the present invention, it is possible to eliminate the expansion joint that is a maintenance problem in the bridge, thereby reducing the maintenance cost and easy maintenance, and also obtain the maximum continuous cross-sectional effect structurally It also has a much better driving performance.

As bridges are used continuously, they reduce load-carrying capacity and serviceability. Therefore, effective countermeasures should be considered in the construction stage. In the present invention, in preparation for the reduction in load capacity and usability during the use of the bridge, by providing an additional tension system for maintenance suitable for the structural behavior of the multi-span continuous bridge from the initial construction stage, it is convenient to add additional tension during use In this way, it is possible to secure the improved bridge performance of multi-span continuous bridges and to extend the life of the bridges. Therefore, it has a great effect on the national industry and economy through the smooth transportation of personnel and industrial traffic.

Furthermore, in the present invention, when the construction of the bridge, by tensioning the continuous tendon at the block-out of the slab, there is no need for provision for tension and easy to work, and the direct connection of both PSC I-girder, single connection to the continuous point piers By installing bridge bearings, clear continuous bridge behavior is realized, and two separate bearings are reduced to a single bearing, thereby reducing construction costs.

1A to 1D are side views illustrating the step-by-step process of sequentially constructing and continuously constructing two-span continuous bridges of a PSC I-girder according to an embodiment of the present invention.
Figure 2 is a schematic perspective view of the end of the PSC I-girder showing the fixing block and the fixing unit installed on the side of the PSC I-girder in the construction stage for further tension in common in accordance with the present invention.
3A to 3D are side views illustrating the step-by-step process of constructing the PSC I-girder bridges in three spans and four spans, respectively, according to an embodiment of the present invention.
Figure 4 is a side view showing the arrangement of the tendon in the cross section and the fixing unit installed on the side of the PSC I-girder in the initial manufacturing and construction stage for the additional tension in common in the PSC I-girder three-span continuous bridge according to an embodiment of the present invention to be.
Figure 5 is a side view showing the arrangement of the tendon in the cross-section and the fixing unit installed on the side of the PSC I-girder in the initial manufacturing and construction stage for further tension in common in the PSC I-girder four-span continuous bridge according to an embodiment of the present invention to be.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, which are described as embodiments, whereby the technical idea of the present invention and its core configuration and operation are not limited.

1A to 1D, respectively, as a first embodiment of the PSC I-girder continuous bridge of the present invention, each step process of constructing and sequentially continually constructing both side spans of a bridge composed of two-span continuous bridges including tendons for maintenance. A schematic side view is shown. In particular, FIG. 1D illustrates a maintenance fixing block including a fixing unit installed at the end side of the PSC I-girder at an initial construction stage and an additional tension tendon disposed in the cross section therefrom for further tensioning of the load capacity and usability deterioration of the bridge. Side view showing the arrangement. In FIGS. 1A-1D, the tendon is shown in solid lines, but is actually disposed inside the PSC I-girder. And, as will be described later, the maintenance fixing block is provided in the form protruding on the end side of the PSC I-girder.

 FIG. 2 is a perspective view showing a fixing fixing block and a fixing unit installed on the side of the PSC I-girder in the construction stage for further tension in common with respect to the present invention in connection with FIG. 1d. As shown in FIG. 2, in the present invention, the PSC I-girder 40 has a fixing block 60 formed on the side for tensioning and fixing additional tension tendons for maintenance during public use from the time of manufacture. The tension tendon sheath is made to be buried.

Throughout this specification, the first span "first span", the second span "second span", the third span "third span", and the fourth span from the left shift 10a in the accompanying drawings. The spans are named "fourth spans", respectively. However, in the case of two span continuous bridges, the second span is the final span. In the case of three span continuous bridges, the second span is only the intermediate span, and the third span is the final span. In the case of the four span continuous bridge, the second span and the third span are respectively intermediate spans, and the fourth span is the final span. The reference numeral 10b is the right shift 10b located opposite the left shift 10a in the longitudinal direction. In addition, in this specification, the direction toward the left shift 10a is represented with "front", and the direction toward the right shift 10b is represented with "rear" with respect to drawing.

In the PSC I-girder 40 of the present invention, the sheath of the first tendon that is strained after the construction of the girder and the second tendon that is strained after the slab is constructed after being mounted on the pier before the pier is installed in the longitudinal direction (the longitudinal direction) Is embedded from the time of manufacture of the girder, and the primary tendon fixing part 41 is provided at both ends of the longitudinal ends of the PSC I-girder 40, and the secondary tendon fixing part is provided at the upper surface of the longitudinal one side end. It is manufactured to be provided. In particular, in the case of the first spanning PSC I-girder 40a, The fixing part is located at the alternating side end and is no longer continuous, and thus consists of a discontinuous fixing part 46. The final spanning PSC I-girder, which is located in the final span, has the same configuration as the first spanning PSC I-girder, but is disposed in a mirror-symmetric relationship with the first spanning PSC I-girder. . On the other hand, in the middle span PSC I-girder, such as the second span PSC I-girder on the three span bridge, the second span PSC I-girder and the third span PSC I-girder on the bridge over four spans. All of the fixing units formed at the rear ends are made of the continuous fixing unit 47 (see FIGS. 3C and 3D).

On the other hand, in the present invention, out of the longitudinal both ends of the PSC I-girder 40, at the end facing the PSC I-girder of the subsequent span, the protruding cast bar 43 for direct connection with the PSC I-girder of the subsequent span. ) And a girder connecting steel sheet 44 is provided.

The PSC I-girder 40 may be made of a single girder in the longitudinal direction according to the span length, but combines a plurality of segments with a shear key and integrates the plurality of segments longitudinally in a single member by primary tension. It may be a girder made.

In constructing the PSC I-girder bridge according to the present invention, as shown in the figure, the weight and slab of the PSC I-girder 40 before mounting the PSC I-girder 40 to the alternating and piers 20. Primary prestress is introduced into the PSC I-girder 40 by tensioning the primary tendon 42 to resist the dead load of 50. As described later, after the PSC I-girder 40 is mounted on the piers 20 and the slab 50 is constructed, the synthesis of the PSC I-girder 40 and the slab 50 is resistant to the additional pavement and live loads. Secondary prestress is introduced to tension the secondary tendon 48 relative to the cross section to obtain the maximum structural cross-sectional effect.

 As a first embodiment of the present invention, in the case of a two-span continuous bridge, the construction of the bridge by the construction method according to the present invention will be described in more detail with reference to FIGS. 1A to 1D sequentially. As shown in, the primary tendon 42 simultaneously mounts the tensioned PSC I-girder 40 over the piers 20 between the first and second spans, respectively. Here, for convenience, when it is necessary to refer to the first span PSC I-girder and the second span PSC I-girder by dividing the spans as described below, the accompanying drawings and the present specification respectively refer to " first span PSC I- Girder 40a "," second span PSC I-girder 40b "," third span PSC I-girder 40c ", and" fourth span PSC I-girder 40d " However, when all the PSC I-girders for each of these spans are collectively referred to as " PSC I-girder 40 " On the other hand, in the case of the three-span continuous bridge, the second span PSC I-girder 40b becomes the "mid span PSC I-girder", and the third span PSC I-girder 40c is the "final span" PSC I-girder ". In the case of four span continuous bridges, the second spanning PSC I-girder 40b and the third spanning PSC I-girder 40c are both "middle spanning PSC I-girder", and the fourth spanning PSC I-girder 40d becomes " final span PSC I-girder ".

1A, 1B and 1D, the first span PSC I-girder 40a provided with the fixing block 60 and manufactured with the primary prestress introduced by the primary tendon 42. And simultaneously mounting the second spanning PSC I-girder 40b on the first span and the second span, respectively, and then the first spanning PSC I-girder 40a and the second spanning PSC I-girder 40b. Position the end of the first span PSC I-girder 40a in a direction facing each other by placing a girder connecting steel plate 44 having a U-shaped cross section on the piers 20 of the continuous point portion to directly connect the two to each other. The lower end and the lower end of the end portion of the second spanning PSC I-girder 40b are fitted into the girder connecting steel sheet 44, respectively, and the protruding reinforcing bars 43 of the continuous points of the first spanning PSC I-girder 40a are fixed. After connecting the protruding cast reinforcing bar 43 of the PSC I-girder 40b for the second span with welding or mechanical joints, it corresponds to the gap between the end faces of the PSC I-girder between the two spans. By pouring concrete in girder connection 45, thereby integrating the I- PSC girder on both sides of each span. In the figure, reference numeral 31 is an alternating bridge support 31 that is placed on the alternation, and reference numeral 32 is a bridge support 32 for the bridge that is placed on the bridge 20.

Subsequently, as shown in FIG. 1B, the first spanning PSC I-girder 40a and the second spanning PSC I-girder 40b, that is, the first spanning PSC I-girder 40a and the final spanning PSC The second span PSC I starting from the discontinuous fixing part 46 located above the front end of the first span PSC I-girder 40a to be installed simultaneously in the I-girder at the same time. -It is installed in the tendon sheath continuously up to the discontinuous fixing part 46 on the upper surface of the rear end of the girder 40b, but in order to maximize the cross-sectional performance and prestress effect of the bridge superstructure, In the center, the position of the secondary tendon 48 is placed under the girder, and at the position of the girder connecting portion 45 which is a continuous point, the secondary tendon 48 is curved so as to pass through the inside of the slab 50 above the girder. In FIG. 1B, since the secondary tendon 48 is not in tension, the secondary tendon 48 is illustrated in a dotted line.

On the other hand, the first additional tension tendon 61 for maintenance is also similar to the secondary tendon 48 as shown in Fig. 1d, the first span PSC I-girder 40a and the second span PSC I-girder. Curved continuously to 40b, the concrete of the slab 50 of the 1st span and the slab 50 of the 2nd span is poured simultaneously, and it is constructed. When constructing the slab 50, in order to tension the secondary tendon 48, the block-out part 51 is formed in the bridge slab 50 at the position of the discontinuous fixing part 46 in advance.

As shown in FIG. 1C, the slab 50 between the first span and the second span is simultaneously constructed, and then the secondary tendon 48 disposed between the first span and the second span is used for the first span. The discontinuous fixing part 46 of the PSC I-girder 40a and the discontinuous fixing part 46 of the second spanning PSC I-girder 40b are simultaneously tensioned and fixed. In this way, after both ends of the secondary tendon 48 are fixed, a protective waterproof mortar is poured into each fixing unit, and concrete is poured into the block-out unit 51 to finish the structural system of the integrated two-span continuous bridge. This is done.

It is necessary for the bridge to make the additional tension system necessary in the initial construction stage due to the decrease in load capacity and usability during use, and FIG. 1D shows the arrangement of the additional tension system of the two-span continuous bridge, and FIG. A schematic perspective view is shown showing an end of a girder in which a fixing block is formed. As shown in the figure, in the present invention, the fixing fixture is included in each of the front end both sides of the first span PSC I-girder 40a and the rear end both sides of the second span PSC I-girder 40b. The block 60 is made together at the time of girder fabrication, and the first additional tension tendon 61 continuous in both spans from the fixing block 60 into the girder cross section is the center of the first span and the second span as shown in FIG. 1D. In the bottom of the girder, and in the position of the girder connecting portion 45, which is a continuous point portion, arranged in a curve so as to pass through the slab 50 on the girder, to the additional tension system in common suitable for the load acting on the two-span continuous bridge The two span continuous bridge provided is completed.

3A to 3D are schematic side views showing the step-by-step process for constructing a bridge consisting of four span continuous bridges, respectively, as a second embodiment of the PSC I-girder continuous bridge of the present invention. 4 and 5, respectively, for the case of constructing a 3-span continuous bridge and the case of constructing a 4-span continuous bridge, the maintenance fixing block for additional tension in common is installed on the side of the PSC I-girder A side view is shown showing the arrangement of additional tension tendons disposed in the cross section.

3A to 3D, first, referring to FIGS. 3A, 3B, and 3C, a case in which a bridge is constructed by successive three spans according to the construction method of the present invention will be described. Through the same process as that of the continuous bridge construction method, as shown in FIG. 3A, the first span PSC I-girder 40a and the second span PSC I-girder 40b are simultaneously constructed and continuous. However, in the case of the continuous bridge having more than three spans, the protruding cast reinforcing bar 43 and the connecting steel plate 44 are provided at the rear end of the second span PSC I-girder 40b for continuity with the third span. Further, the third spanning PSC I-girder 40b has a third as well as a fixing block 60 for fixing the ends of the first additional tensioning tendons 61 for maintenance continuous in the first span. A fixing block 60 is provided for fixing the end portion of the second tension tendon 62 for maintenance, which is continuous in the span (see FIG. 5). In addition, in the case of a continuous bridge having more than three spans, the third span is provided with a fixing block 60 of the additional tension tendon 62 for maintenance in the third span following the second span PSC I-girder 40b. A spanning PSC I-girder 40c is disposed to be continuous with the second spanning PSC I-girder 40b, and a discontinuous fixing portion 46 is provided at the rear end of the second spanning PSC I-girder 40b. In addition, the continuous fixing part 47 in which the tendon coupler is installed is formed, and is also a difference from the bridge in which only two spans are continuous.

On the other hand, when the three-span continuous bridge is completed, the protruding cast reinforcing bar 43 and the connecting steel plate 44 is not installed at the rear end of the third span PSC I-girder 40c, as shown in Figures 3b to 3d. As shown in the figure, in the case of continuous up to four spans, the projection for connection with the fourth span PSC I-girder 40d is provided at the rear end of the third span PSC I-girder 40c. The main reinforcing bar 43 and the connecting steel plate 44 is installed.

As shown in FIG. 3B following the state shown in FIG. 3A, the third span PSC I-girder 40c having completed the primary tension by the primary tendon is transferred to the second span PSC I-girder 40b. Subsequently mounted. At this time, the rear lower end of the second spanning PSC I-girder 40b and the third spanning PSC I-girder 40c for connecting the girder between the second span and the third span at the pier which are the continuous points. The front lower end is positioned on the girder connecting steel plate 44, and the protruding reinforcing bar protruding the front end of the rear end protruding main reinforcing bar 43 of the second spanning PSC I-girder 40b and the third spanning PSC I-girder 40c. (43) is connected by welding or mechanical joint, and after fixing the girder connecting steel plate 44 at the bottom of the girder to pour concrete into the girder connecting portion 45 to integrate. Subsequently, as shown in FIG. 3C, the second tendon 48 is formed using the tendon coupler at the continuous fixing part 47 formed at the rear of the second span PSC I-girder 40b. The secondary tendon 48 of the third span is disposed in the third span PSC I-girder 40c in connection with the secondary tendon disposed in the PSC I-girder 40b for the third span. The secondary tendon 48 also passes through the inside of the slab 50 at the position of the girder connecting portion 45, which is a continuous point, in order to maximize the resistance of the cross section and the prestress effect, and is positioned below the girder at the center of the third span. Post it. Also for the 3rd span PSC I-girder 40c, the 2nd additional tension tendon 62 for maintenance is arrange | positioned in the same arrangement as the 2nd tendon 48, and the 3rd span slab 50 is constructed. .

In FIG. 3C, it is shown that the discontinuous fixing portion 46 is formed at the rear of the third spanning PSC I-girder 40c. In the case of the bridge having only three spans in succession, The discontinuous fixing part 46 is formed behind the PSC I-girder 40c, and after the slab 50 of the third span is constructed as described above, the secondary tendon 48 is used for the third span. After tensioning and fixing in the discontinuous fixing part 46 formed at the rear of the PSC I-girder 40c, the concrete is poured into the protective waterproof motor and the block-out part 51 at each fixing part, and then paved. Construction of the continuous PSC I-girder bridge is completed.

Figure 4 shows a maintenance tendon system for installing in advance in the construction stage the additional tension system required in common in such a three-span continuous bridge, two span continuous additional tension system between the first span and the second span is shown in FIG. As in the case of the two-span continuous bridge, the first additional tension tendon 61 continuous in both sections into the girder section in the fixing block 60 of the front end side of the first span PSC I-girder 40a is connected to the first span. At the center of the center and the second span, it is located under the girder, and at the position of the girder connecting portion 45, which is a continuous point, it is arranged in a curve so as to pass through the slab 50 on the girder, but the second span PSC I-girder 40b is installed. Fixing block 60 installed on the rear end side of the) is to be installed above the side of the girder for efficient continuity behavior with the third span. As shown in Fig. 4, another second tension tendon 62 for the continuity behavior between the second span and the third span begins at the settling block 60 on the side of the center of the second span girder, and then at the continuous point. The three-span continuous bridge, which is equipped with additional tension system in common suitable for the load acting on the three-span continuous bridge, is installed by placing and installing it to the fixing block 60 at the rear end side of the girder of the third span. Is completed.

On the other hand, in the case of constructing a four-span continuous bridge, as shown in FIG. 3D following the state shown in FIG. 3C, the fourth span PSC I-girder subsequent to the third span PSC I-girder 40c. 40d are provided continuously. As described above, in the case of the four-span continuous bridge, the protruding cast reinforcing bar 43 and the connecting steel plate 44 are provided at the rear end of the third span PSC I-girder 40c for continuity with the fourth span. In addition to the fixing block 60 of the second additional tension tendon 62, which is disposed in succession to the second span, the three-span PSC I-girder 40c is provided for maintenance. The fixing blocks 60 of the additional tension tendons 63 are provided respectively (see FIG. 5).

As described above, the fourth span PSC I-girder 40d, which is provided with the fixing block 60 for the third additional tension tendon 63 for maintenance, is placed in the fourth span after the third span. In the girder connecting portion 45 facing the span PSC I-girder 40c, the protruding cast reinforcing bars 43 are connected to each other, and both girders are fixed to the girder connecting steel plate 44 at the bottom of the girder, and then the concrete to the girder connecting portion 45 Integrate by pouring. Subsequently, the secondary tendon 48 disposed in the fourth spanning PSC I-girder 40d is connected to the tendon coupler of the continuous fixing part 47 formed at the rear of the third spanning PSC I-girder 40c. To place. The secondary tendon 48 disposed in the fourth spanning PSC I-girder 40d is disposed in the same manner as the third spanning PSC I-girder 40c described above. Further, the third additional tension tendon 63 is disposed in the same manner as described above with respect to the fourth span PSC I-girder 40d, and then the slab 50 of the fourth span is constructed. After constructing the slab 50 of the fourth span, the secondary tendon 48 is tensioned and fixed in the discontinuous fixing part 46 behind the fourth span PSC I-girder 40d, and then fixed to each fixing unit. When the concrete is poured into the protective waterproof motor and the block-out part 51 and paved, the construction of the 4-span continuous PSC I-girder bridge is completed.

FIG. 5 illustrates a tendon system in which an additional tensioning system required in common in such a four-span continuous bridge is installed at a construction stage, and includes a third span PSC I-girder 40c and a fourth span PSC I-girder. Also between 40d, a third additional tension in the same manner as the second additional tension tendon 62 between the second spanning PSC I-girder 40b and the third spanning PSC I-girder 40c. The tendon 63 is installed. Through this process, the four-span continuous bridge equipped with additional tension system in common suitable for the load acting on the four-span continuous bridge is completed very efficiently.

 On the other hand, the present invention is not limited to the four-span continuous bridge in this way, it can be applied to construct a continuous bridge having a plurality of spans of more than five spans. That is, before the fourth span PSC I-girder 40d and the fifth span PSC I-girder are integrated and continuous, the subsequent intermediate span having the same configuration as the third span PSC I-girder 40c. The fourth span is produced in the same manner as the method described above, that is, the number of PSC I-girders required and connected between the second spanning PSC I-girder 40b and the third spanning PSC I-girder 40c. Connect the PSC I-girder 40d for the next intermediate span and the PSC I-girder for the subsequent intermediate span, connect the subsequent intermediate span PSC I-girder as many times as necessary in the same manner, and finally the fourth span PSC By connecting the final span PSC I-girder in the same manner as the I-girder 40d, a continuous bridge having a plurality of spans can be constructed.

As described above, the present invention provides a continuous additional tension system suitable for the working load of a multi-span continuous bridge to reduce the load-bearing force and the lowering of usability that occur during the use of the bridge. Located in the slab on the girder and installed at the initial stage of manufacture and construction, it is easily tensioned during the use of the bridge to improve its performance and ensure the longevity, thus allowing the industrial traffic to be transported smoothly and without delay, showing great economic and economic effects. do.

In addition, the present invention is the construction of the first and second span girders 40 and the slab 50 at the same time, the unified continuous tendon is located below the girder at the center of the span and the slab on the girder at the continuous point. Placed inside the 50, at the same time in the left anchoring portion of the first span and the right anchoring portion of the second span to simultaneously sequential two spans to shorten the construction period and to reduce the construction cost, and then to follow the third span After the continuous construction, the third span is continuous by using the tendon coupler at the continuous fixing part on the right side of the second span, and the subsequent spans are constructed one by one in turn, and the other ones are automatically continuously continuous by one span. Since the whole can be constructed as a continuous bridge, the maximum continuous bridge effect can be obtained structurally, and by eliminating the expansion joint Along with the reduction of the maintenance cost, the vehicle has an effect of improving the running performance.

10a: left shift
10b: right shift
20: piers
46: discontinuous fixation
47: continuous fixing part
48: 2nd tendon
50: slab
60: fixing block
61: first tension tendon

Claims (4)

Primary tendon fixing portions 41 are provided at both ends of the girder, and secondary discontinuous fixing portions 46 for secondary tendons are provided on the upper surfaces of the respective alternating end portions, and on both sides of the alternating end portions of the girder. A fixing block 60 is provided for the fixing of the first additional tension tendon 61 which may be further tensioned for maintenance during public use, and a sheath for primary tendon, a sheath for secondary tendon and a sheath for additional tension tendon. The secondary tendon sheath and the additional tender tendon sheath are buried in a curved shape so as to be located at the bottom of the girder and to the upper slab at the position of the piers 20, which is a continuous point, and the continuous points The first span PSC I-girder 40a and the second span PSC I-girder 40b, each having a protruding cast steel 43 and a girder connecting steel plate 44 at the lower end thereof, are provided at the end of the side of the bridge piers 20. Producing each;
A primary tendon 42 is placed on a sheath for primary tendons so as to resist girder weight and slab dead weight on each of the first span PSC I-girder 40a and the second span PSC I-girder 40b. After introducing the first prestress, the first span PSC I-girder 40a and the second span PSC I-girder 40b are simultaneously mounted on the first span and the second span, respectively, and are piers that are continuous points. (20) the end protruding cast reinforcing bar 43 of the second span PSC I-girder 40b mounted on a single bridge bearing and facing the end protruding cast bar 43 of the first spanning PSC I-girder 40a. Directly connecting the two ends of the PSC I-girder to the girder connecting steel plate 44 to the lower part of the girder connecting steel plate 44, and then placing concrete on the girder connecting part 45 to continuously integrate the PSC I-girder between the two spans;
The secondary tendon 48 and the first additional tension tendon 61 are inserted into the secondary tendon sheath and the first additional tension tendon sheath, respectively, and are continuously arranged in a curve so as to be continuous between the first span and the second span. In the position of the girder connecting portion 45, which is a continuous point portion, it passes through the inside of the slab 50 and is disposed below the center of the first span and the second span, and the first span PSC I-girder 40a and Construct the slab 50 at the same time by placing concrete on the second span PSC I-girder 40b, so that the block-out portion 51 for tension of the secondary tendon 48 is present in the slab 50. Constructing the slab 50; And
Discontinuous of the first tendon PSC I-girder 40a and the second tendon 48 disposed in succession to the second span PSC I-girder 40b. At the same time, after tensioning and fixing at the discontinuous fixing part 46 of the fixing part 46 and the PSC I-girder 40b for the second span, each fixing part is protected by a waterproof mortar and the concrete in the block-out part 51. PSC I-girder continuous bridge construction method comprising the step of constructing the bridge in the form of a continuous two-stage structure comprising the step of constructing an integrally continuous superstructure system.
The method of claim 1,
At the time of manufacturing the second spanning PSC I-girder 40b, a fixing block 60 for fixing the additional tension tendon that is continuous with the third span is further provided on the side of the center and at the end in the third span direction. Protruding cast reinforcing bar 43 and the girder connecting steel plate 44 is further provided, so that the continuous fixing portion 47 is also formed in the end of the third span direction so that the second span PSC I-girder 40b for the intermediate span Fabricating to be a PSC I-girder;
The third span PSC I-girder 40c to be installed after the second span PSC I-girder 40b is manufactured as the final span PSC I-girder, and the third span PSC I-girder ( On the side of the girder at the alternate end of 40c), there is provided a fixing block 60 for fixing the additional tension tendon disposed in succession to the second spanning PSC I-girder 40b, and the second spanning PSC I-. Manufacturing the third spanning PSC I-girder (40c) such that a protruding cast steel bar (43) and a girder connecting steel plate (44) are provided at an end portion of the girder (40b) direction;
The third span PSC I-girder 40c is mounted on the third span after the second span PSC I-girder 40b so as to face the second span PSC I-girder 40b. The opposite ends of the two span PSC I-girder 40b and the third span PSC I-girder 40c are fixed to the girder connecting steel plate 44, and the protruding cast reinforcing bars 43 of the opposite ends are connected to each other. Thereafter, pouring concrete into the girder connections 45 between the ends facing each other to continuously integrate the PSC I-girder between the two side spans;
At the position of the girder connection 45, the secondary tendons 48 and the second additional tension tendons 62 pass through the interior of the slab 50 and are positioned below the center of the third spanning PSC I-girder 40c, respectively. ) Is disposed in the third span PSC I-girder 40c, and one end of the secondary tendon 48 of the third span PSC I-girder 40c is the second span PSC I-girder 40b. The second additional tension tendon 62 is formed from the fixing block 60 installed on the central side of the second spanning PSC I-girder 40b. Connecting and arranging up to the fixing block 60 installed on the alternating end side of the three-span PSC I-girder 40c, and then constructing the slab 50 on the third span PSC I-girder 40c. ; And
After the secondary tendons 48 disposed on the third span PSC I-girder 40c are tensioned and fixed at the discontinuous fixing portions 46 formed at the alternate end portions of the third span, each fixing unit is waterproofed. PSC I-girder continuous bridge construction, characterized in that to construct the bridge in a three-span continuous form, including the step of protecting and to build a superstructure system integrally by placing concrete in the block-out unit 51 Way.
The method of claim 1,
At the time of manufacturing the second spanning PSC I-girder 40b, a fixing block 60 for fixing the additional tension tendon that is continuous with the third span is further provided on the side of the center and at the end in the third span direction. Protruding cast reinforcing bar 43 and the girder connecting steel plate 44 is further provided, so that the continuous fixing portion 47 is also formed in the end of the third span direction so that the second span PSC I-girder 40b for the intermediate span Fabricating to be a PSC I-girder;
An intermediate spanning PSC I-girder to be installed subsequent to the second spanning PSC I-girder 40b, wherein a continuous fixing portion 47 is formed on an upper surface of the longitudinal rear end, and the intermediate spanning PSC I-girder. In the central side of the intermediate section is further provided with a fixing block 60 for fixing the additional tension tendon to be continued with the subsequent span, the protruding cast reinforcing bar 43 and the girder connecting steel plate 44 at the end of the subsequent span direction Manufacturing a PSC I-girder;
A second spanning PSC I-girder 40b followed by the intermediate spanning PSC I-girder;
Connection between the protruding cast reinforcing bar 43 between the second spanning PSC I-girder 40b and the subsequent intermediate spanning PSC I-girder, fixing in the girder connecting steel plate 44 and concrete placing in the girder connection 45 PSC I-girder on both sides by the continuous integration operation,
A secondary tendon 48 and an additional tension tendon are disposed in the intermediate span PSC I-girder, and the secondary tendon is interlocked by a tendon coupler in the continuous fixing part 47 of the second span PSC I-girder 40b. (48) is connected to pass through the inside of the slab 50 in the continuous point portion and positioned in the lower side of the girder at the center of the subsequent span, the additional tension tendon of the second span PSC I-girder (40b) From the fixing block 60 installed on the side of the central portion to the fixing block 60 provided on the end side of the PSC I-girder for the subsequent intermediate span in the same shape as the secondary tendon 48, and then for the subsequent intermediate span Construct a slab 50 on the PSC I-girder, and tension the second tendon 48 disposed in the PSC I-girder for subsequent intermediate spans in tension in the continuous anchoring section 47 of the intermediate span,
By manufacturing the final span PSC I-girder having the same configuration as the first span PSC I-girder 40a,
Subsequent mounting of the final spanning PSC I-girder to the intermediate spanning PSC I-girder,
PSC I-girder between the intermediate span PSC I-girder and the connection between the projecting cast reinforcing bar 43, fixed on the girder connecting steel plate 44, and both sides of the PSC by concrete casting in the girder connecting portion 45 Perform continuous integration work on the I-girder,
A secondary tendon 48 and an additional tension tendon are disposed between the intermediate span PSC I-girder and the final span PSC I-girder, between the intermediate span PSC I-girder and the final span PSC I-girder. The additional tension tendon is arranged by connecting from the fixing block provided on the center side of the intermediate span PSC I-girder to the fixing block installed on the side of the alternate end of the final spanning PSC I-girder and constructing the slab. Tendon 48 is tensioned and fixed at the discontinuous fixing part 46 of the PSC I-girder for the final span, protecting each fixing part with a waterproof mortar, and placing concrete on the block-out part 51 to finish it for more than four spans. A PSC I-girder multi-span continuous bridge construction method comprising constructing a multi-span continuous bridge having a plurality of spans.
PSC I-girder multi-span continuous bridge which was constructed by the construction method according to any one of claims 1 to 3.

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