KR100766888B1 - Fabricated bridge using pile pillars coupled by pillar connecting member as the coping of pier, omitting the foundation and constructing method thereof - Google Patents

Abstract

An assembling bridge using pile columns connected by a column connecting member as coping of a pier without foundations and a construction method thereof are provided to reduce the construction period and to cut down expenses by installing the pile column in the ground, inserting the pile column to the column connecting member, pouring concrete and mounting a bridge seat, an elastic support and a girder. A pile column(20) is driven into a ground(12), and an upper projection of the pile column is inserted to a penetration hole of a column connecting member. Coping of a pier is formed by pouring concrete, and a bridge seat block is installed on the coping of the pier. An elastic support is mounted thereon, and a girder(11) is installed in the upper part of the elastic support. A connection portion of the girders is placed in a vertical part(31), and a longitudinal girder connection part is formed between the girders. Non-shrinkage concrete is poured, and a bridge is assembled by finishing an upper part(13) of the bridge. The weight of the bridge is decreased by forming a recessed part.

Description

Fabricated bridge using pile pillars coupled by pillar connecting member as the coping of pier, omitting the foundation and constructing method approximately}

        1 is a side view of a prefabricated bridge of the present invention.

        2 shows the prefabricated bridge of FIG. 1 from above;

        3 is connected to the pile pillar of the prefabricated bridge of the present invention with a connecting member, and

Cross-sectional view of the part where girders are installed.

        4 is a view showing a pillar connecting member of the present invention.

        Figure 5 is a view showing a side connecting member of the present invention from the side.

        Figure 6 is a view showing the pile pillar of the prefabricated bridge of the present invention.

        Figure 7 (a) (b) is a shear root installed on the upper projection of the pile pillar of the present invention

Showing drawings.

        8 is a view showing another embodiment of the shear root of the present invention.

        Figure 9 is an upper projection of the pile pillar in the through hole of the pillar connecting member of the present invention

Drawing showing insertion.

        10 is connected to the upper projection of the pillar connecting member and the pile pillar of the present invention

Figure showing the side forming the bridge coping portion.

        Figure 11 (a) (b) (c) is a view showing the construction sequence of the prefabricated bridge of the present invention.

        12 is a view showing portion A of FIG. 11 (c) in detail;

        FIG. 13 shows a section B-B in FIG. 11 (c).

        14 shows the girder longitudinal connection of FIG. 13;

        <Explanation of symbols for main parts of the drawings>

        10: prefabricated bridge 11: girder

        12: Ground 13: Bridge Upper Finish

        14: support base block 15: elastic support

        20: pile pillar 21: upper projection

        22: through hole 23: protruding jaw

        24: shear root 25: pillar body

        26: column tip 27: reinforcing bar

        28: strip reinforcing bar 29: vertical connecting bar

        30: pillar connecting member 31: vertical part

        32: horizontal connecting body 33: shear member

        34: connection portion 35: groove portion

        36: through hole 37: stepped groove

        38: concrete

        40: girder longitudinal connection 41: non-concrete concrete

        42: groove 43: U-shaped rebar

        50: pier coping part

        The present invention is to be applied to all bridges, such as pedestrian bridges, general bridges, etc. installed on the river or the sea in the sea, the steel pipe pillars, steel pillars, pre-stressed concrete pile pillars and preflex introduced in the ground or seabed The pile pillar, which is one of the multiplex columns, may be typed or inserted into the ground in the width and length directions at regular intervals at the width and length of the designed bridge, and then fixed by penetrating the upper protrusion protruding from the top of the pile pillar. Penetrate the upper projection of the pile pillar in the through hole of the column connecting member formed with a plurality of through holes, and cast concrete to form a pier coping part, and then install an brace support block on the pier coping part to support the elastic support thereon. Install and install the girder on the elastic support but the girder and the girder are installed adjacent to each other The part is hypothesized to be located inside the vertical part installed on both sides of the column connecting member in the width direction, and the girder and the girder are installed in the longitudinal direction to form a girder longitudinal connection part to form non-concrete concrete. Prefabricated bridges using the upper part of the girder as it is or the upper part of the girder, or skipping the foundation part of the bridge to the upper end of the girder prefabricated, and connecting the pile to the column connecting member It is a construction method.

        As described above, the purpose of installing the bridges in the prefabricated manner is to install the bridges in the water, and to install the foundations, the work of excavating the ground of the riverbed to install the foundation and the work of installing the columns thereon are all installed in the water or Alternatively, in order to improve the problem that a lot of air and construction cost are required to install the bridge, which is made on the soft ground, a pile pillar that can be used as a bridge pier directly on the lower bed of the river is typed or inserted into the ground, and then Fixing the pillar of pillar from the top with a column connecting member, to install a bridge device to the pillar connecting member, to form a pier coping portion to install a girder thereon, and to install a bridge support block and elastic support on the pier coping portion And install the girder on it to prefabricate the bridge It is to provide a bridge construction method to drastically reduce the construction period as well as the construction period by simply installing and assembling them by simply assembling them using pile pillars, girders, and pillar connecting members prepared in advance in the factory. .

        Conventionally, in order to install a bridge in a river or a beach, a temporary tent is installed to form a foundation, and the foundation is searched by reinforcing reinforcement and concrete to form a foundation by excavating the ground in which the existing tent is installed. Next, as the bridge pier is installed on it, the bridge device is installed on it, and the girder is installed on it, so that the construction period is excessive, and the construction cost is excessive. Problems have existed.

        The present invention has been proposed to provide an economical and efficient bridge construction method that can reduce the construction cost while reducing the construction period more efficiently while improving the above problems, the bridge of the bridge directly on the soft ground of the bed A piling which can be utilized as a piling in the ground type or penetrated, and then fixed a piling pillar from the top with a pillar connecting member thereon, to install the bridge device on the pillar connecting member, and to install a girder thereon After the formation of the part, the material for pre-fabricating the pile pillar, the girder and the pillar connecting member, which are the materials necessary for installing the bridge support block and the elastic bearing on the bridge coping portion and installing the bridge for installing the girder thereon. It is necessary to construct a bridge by simply assembling it, almost eliminating concrete work. Is a way to bridge construction to significantly reduce the cost and shorten the construction period.

        The present invention is to be applied to all bridges, such as pedestrian bridges, general bridges and the like installed on the river or the sea of the sea, concrete pile pillars and pre-plex in which steel pipe columns, steel columns, prestresses are introduced into the ground (12) The pile pillar 20, which is one of the multiplexed pillars, is introduced or typed into the ground 12 in the width direction and the longitudinal direction at regular intervals at the width and length of the designed bridge, and then The upper protrusion 21 of the pile pillar 20 is formed in the through hole 36 of the column connection member 30 in which a plurality of through holes 36 are formed to penetrate and fix the upper protrusion 21 protruding from the upper portion. Penetration, cast concrete fixed 38 to form a pier coping portion 50, and then install an elastic support 15 thereon while installing a bridge support block 14 on the pier coping portion, the elastic Hanging on the base (15) (11) is installed, but the girder 11 and the girder 11 is installed adjacent to each other, and then hypothesized to be located inside the vertical portion 31 installed on both sides in the width direction of the column connecting member 30, In the gap formed by the girder 11 and the girder 11 installed in the longitudinal direction, the girder longitudinal connection portion 40 is formed to pour the non-concrete concrete 41, and then the upper portion of the girder 11 is bridged as it is. Construction of the prefabricated bridge 10 utilized as a pier coping by connecting the pile column to the column connection member by omitting the upper part of the girder or the bridge top finishing 13 on the upper part of the girder, or by installing the bridge in a prefabricated manner. Way.

        Hereinafter, the configuration and operation of the present invention will be described in detail by the accompanying drawings.

        1 and 2 is a view showing the prefabricated bridges of the present invention from the side and from above, in which the steel pipe column, steel column, prestressed concrete pile column and preflex are introduced into the ground 12 of the riverbed or seabed of the river. The pile pillar 20, which is one of the multiplex columns, is typed or inserted into the ground 12 in the width direction and the longitudinal direction at regular intervals at the width and the length of the designed bridge, and then protrudes on the top of the pile pillar 20. Penetrating the upper protrusion 21 of the pile pillar 20 into the through hole 36 of the column connection member 30 formed with a plurality of through holes 36 so as to penetrate and fix the upper protrusion 21, After pouring concrete 38 to form the pier coping portion 50, the bridge support block 14 is installed on the pier coping portion 50, the elastic support 15 is installed thereon, and Install the girder (11) on the elastic support (15) The girder 11 and the girder 11 are installed adjacent to each other, and the hypothesis is placed inside the vertical portion 31 provided on both sides of the column connecting member 30 in the width direction, and then the girder 11 and The girder 11 is installed in the longitudinal direction to form a girder longitudinal connecting portion 40 to form a non-concrete concrete 41, and then use the upper portion of the girder 11 as the upper portion of the bridge or bridge The bridge was installed prefabricated by the upper finish (13).

       The upper portion of the bridge may be selectively installed according to the type of the bridge to be installed, or may be selectively applied to the upper surface of the girder as it is.

       When used as a sidewalk among the types of bridges, it means that the upper part of the bridge is a block or pavement that allows people to walk, such as a sidewalk block or a block that can alleviate the impact on the girder.

       In the case of allowing the vehicle to pass the bridge, paving with asphalt or concrete on the girder is the upper part of the bridge, and allowing the sidewalk and the vehicle to pass at the same time is optional depending on the situation. To do that.

       In addition, the omission of the upper portion of the bridge as described above, it is also clear that the upper surface of the girder can be utilized as the upper portion of the bridge as it is.

        3 is a cross-sectional view of a portion of a prefabricated bridge of the present invention with a connecting member and a girder installed thereon, wherein a steel pipe column, a steel column, and a prestress are introduced into the ground 12 of the bed or seabed. The pile pillar 20, which is one of the pillars and the multiplex pillars into which the pillar is introduced, is typed or inserted into the ground 12 in the width direction and the longitudinal direction at regular intervals at the width and length of the designed bridge, and then the pile pillar The upper protrusion of the pile pillar 20 in the through hole 36 of the pillar connection member 30 in which a plurality of through holes 36 are formed so as to penetrate and fix the upper protrusion 21 protruding from the upper portion of the upper portion 20. (21) is inserted, and the concrete 38 is poured into it to form a pier coping part 50, and then a bridge support block 14 is installed in the pier coping part 50, and the elastic support 15 is placed thereon. ), And the elastic support (15) Install the girder 11, but install the girder 11 and the girder 11 adjacent to each other so as to be located inside the vertical portion 31 installed on both sides of the column connecting member 30 in the width direction. In the gap formed by the girder 11 and the girder 11 installed in the longitudinal direction, the girder longitudinal connecting portion 40 is formed to pour the non-concrete concrete 41, and then the upper portion of the girder 11 is left as it is. It is used as the upper part of the bridge or the bridge top finish 13 is to install the bridge prefabricated.

        The girder 11 of the present invention means that all kinds of girders such as prestressed concrete girder, multiplex girder, girder, steel box girder and concrete girder can be used.

        Figure 4 is a view showing a column connecting member of the present invention, a precast product manufactured in advance in the factory, while having a predetermined thickness and area on both sides formed by penetrating through the through hole 36 to a certain size in the center The lower surface of the through hole 36 constitutes a horizontal connecting body 32 to form a stepped groove 37, and the horizontal connecting body 32 is connected to each other by the connecting part 34 so that the center is concave. The vertical part 31 is manufactured in an eight-shaped structure having a groove part 35 formed therein, and connected to both end surfaces of the horizontal connection body 32 provided on both sides with the connection part 34 interposed therebetween. It is a pillar connecting member (30) consisting of.

        The groove 35 is formed to be concave in the center as described above, so as to reduce the overall weight and not affect the strength.

        The shear member 33 is formed to protrude from the entire wall surface of the through hole 36, and the through hole 36 may be installed in various shapes such as a rectangle, a circle, a polygon, and the inside of the through hole 36. Protruding jaw 23 of the pile pillar 20 in the stepped groove portion 37 formed in the lower surface of the through hole 36, so that the upper projection 21 of the pile pillar 20 to be described later. When the upper projection 21 of the pile pillar 20 is inserted into the through hole 36 is inserted into the through hole 36 to prevent the whole of the pile pillar 20 from coming out. When the connecting member 30 acts as a load on the pile pillar 20, the supporting member 30 is supported by the protruding jaw 23 of the pile pillar 20 inserted in the stepped groove 37 so that the acting load is smoothly transmitted to the pile pillar. For sake.

        5 is a view showing the pillar connecting member of the present invention from the side, showing the perspective view of FIG. 4 from the side, as a precast material prepared in advance by arranging the reinforcing bar 27 in the factory, curing the concrete The role of the stepped groove 37 formed in the lower portion of the through hole 36 of the pillar connection member 30 is as described above, and the shear member 33 protruding from the entire surface of the through hole 36 is a pile pillar. The upper protrusion 21 of the 20 is inserted into the through hole 36, and when the concrete 38 is poured into the through hole 36 to integrally operate, the pillar connecting member 30 and the pile pillar 20 This is to ensure that the upper protrusion 21 of the integrally strongly connected.

        Figure 6 is a view showing the pile pillar of the prefabricated bridge of the present invention, as the pile pillar 20 of all kinds that can be used as pillars such as steel pipe pile, H-shaped steel pile, multiplex pile, prestress pile and concrete pile It is to allow the upper bridge to be supported while eliminating the installation of the foundation which can support the conventional bridge by reaching the rock layer where the pile can be typed or penetrated into the ground and the supporting force to support the upper bridge can be achieved. .

        Type or penetrate the pile pillar 20 into the ground 12, but install the pile pillar 20 at regular intervals by the width and length of the bridge to be installed, the pile pillar 20 is installed adjacent to the width direction Insert the upper projection of the pile pillar 20 of the present invention into the through hole 36 formed in the horizontal connection body 32 of the column connecting member 30 so as to be fixed while interconnecting the upper portion of the concrete (38) To pour cured, to install the girder 11 installed on the upper end of the pile pillar so that the protruding jaw 23 of the pile pillar 20 is inserted into the stepped groove portion 37 installed on the lower surface of the through hole 36. This is to allow the pile pillar 20 to be smoothly transmitted to the pile pillar 20 while preventing the pile pillar 20 from protruding through the pillar connecting member 30 by a load acting upon the bridge.

        Therefore, the pile pillar 20 of the present figure is manufactured so that the column tip portion 26 is formed at the lower portion of the pillar body 25 so that it can be inserted into the ground smoothly, and the protruding jaw 23 at the upper portion of the pillar body 25. The upper projection 21 is formed in the cross-section in which the protruding jaw 23 is formed so that the upper projection 21 is formed in the horizontal connection body 32 of the pillar connecting member 30. 36 is inserted into the stepped groove 37 formed in the lower end surface of the column connecting member 30 so that the column connecting member 30 is installed on the pile pillar 20 when the penetrating jaw 23 is inserted through. to be.

        In addition, a through hole 22 having a predetermined size is formed in the body of the upper protrusion 21 of the pile pillar 20 inserted into the through hole 36 so that the reinforcing bar bundle is inserted into the through hole 22 to penetrate the through hole. The pillar connecting member 30 is inserted into and protruded into the through hole 22 in various forms such as to protrude a predetermined length outwardly or to insert steel into the through hole and to protrude outward. When the upper projection 21 in which the shear root 24 protrudes is inserted into the through hole 36, and the concrete 38 is poured into the through hole 36, the shear root 24 is the shear member 33. It is to make a stronger connection by acting as).

        In particular, in the through hole 36 in which the shear member 33 is formed over the entire surface, the through protrusion (21) through which the shear root 24 protrudes into the body of the upper protrusion 21 is inserted therethrough. When the concrete 38 is poured into the concrete 36, the concrete 38, the upper protrusion 21, and the pillar connecting member 30 that are poured into the through hole 36 by the shear member 33 and the shear root 24 are formed. Is to be connected more strongly so that it behaves integrally when a load is applied to the bridge.

        Figure 7 (a) (b) and Figure 8 is a view showing various embodiments of the shear root installed on the upper projection of the pile pillar of the present invention, as described in Figure 6 a constant size in the body of the upper projection 21 After forming the through hole 22 of the reinforcing bar 27 is cut into a predetermined length in the through hole 22 and the reinforcing bar bundle fixed by the band reinforcing bar 28 through the through hole 22 to the outside Shear root 24 is installed so as to protrude a predetermined length, so that the shear root 24 is inserted through the through hole 36 formed in the pillar connecting member 30.

       In another embodiment, the reinforcing bar (27) is attached to the reinforcement (27) in a predetermined length across the entire body of the upper protrusion (21) to protrude to the outside of the body and then installed up and down reinforcing bars 29 at regular intervals Shear roots (24) installed in the through hole (36) is inserted into the through hole (36) to pour the concrete 38 shear shear member 33 and shear roots installed in the upper projection (21) installed in the through hole (36) In order to be able to act integrally when the load is applied to the stronger integral by (24).

       9 is a view showing that the upper projection of the pile pillar is inserted into the through hole of the pillar connection member of the present invention, while having a predetermined thickness and area on both sides to be formed through the through hole 36 to a certain size in the center The lower surface of the through hole 36 constitutes a horizontal connecting body 32 to form a stepped groove 37, and the center of the horizontal connecting body 32 is connected to each other by the connecting part 34. It is made of an eight-shaped structure formed with a groove portion 35 so as to be concave, and connected to both end surfaces of the horizontal connecting body 32 installed on both sides with the connecting portion 34 therebetween and installed vertically at a constant width and height. The shear member 33 is formed to protrude on the entire wall surface of the through hole 36 of the pillar connecting member consisting of 31,

        The through hole 36 may be installed in various shapes such as a rectangle, a circle, a polygon, and the like, so that the upper protrusion 21 of the pile pillar 20 is inserted through the through hole 36, as shown in FIG. 7. The through hole 21 is formed in the body of the upper protrusion 21 and the shear root 24 is inserted into the protrusion, or as shown in FIG. 8, the rebar 27 is spaced up and down at regular intervals on the body of the upper protrusion 21. The upper protrusions 21 having the shear roots 24 fastened to the upper and lower connecting bars 29 are inserted, and the concrete 38 is placed in the through holes 36. It was to cure.

       FIG. 10 is a view showing a piercing coping portion formed by connecting an upper protrusion of a pillar connecting member and a pile pillar of the present invention from the side. The through hole 36 has a constant size in the center while having a constant thickness and area on both sides. The horizontal connection body 32 is formed to penetrate the lower surface of the through hole 36 so as to form the stepped groove 37, and the horizontal connection body 32 is connected to each other by the connection part 34. To form a concave shape having a groove portion 35 formed so that the center is concave, and connected to both end surfaces of the horizontal connecting body 32 provided on both sides with the connecting portion 34 interposed therebetween. It is a pillar connecting member 30 consisting of a vertical portion 31 installed as.

       The shear member 33 is formed to protrude from the entire wall surface of the through hole 36, and the through hole 36 may be installed in various shapes such as a rectangle, a circle, a polygon, and the inside of the through hole 36. The upper projection 21 of the pile pillar 20 is to be inserted through, to form a through-hole 22 in the body of the upper projection 21, as shown in Figure 7 to insert and project the shear roots 24, or As shown in FIG. 8, the reinforcing bar 27 is attached to the upper and lower parts of the upper protrusion part 21 at regular intervals so that both sides of the reinforcing bar protrude out of the body of the upper protrusion part. The upper projection 21 provided with the 24 is inserted, and the concrete 38 is poured into the through hole 36 while being poured.

       The upper projection 21 of the pile pillar 20 in the through hole 36 is inserted into the protrusion jaw 23 of the pile pillar 20 in the stepped groove 37 formed on the lower surface of the through hole 36. When inserted, the whole of the pile pillar 20 into the through hole 36 is firmly assembled so as not to escape, and when the column connecting member 30 acts as a load on the pile pillar 20 by a load acting on the bridge This is to allow the load to be smoothly transferred to the pile pillar 20 by the protrusion jaw 23 of the pile pillar 20 fitted in the groove portion 37.

       Figure 11 (a) (b) (c) is a view showing the construction sequence of the prefabricated bridge of the present invention, Figure (a) is a steel pipe column, steel column, prestressed concrete introduced into the ground 12 of the bed or seabed It is shown that the pile pillar 20, which is one of the pillars and the preflex introduced pillars 20, is typed or penetrated into the ground 12 at regular intervals at the width and length of the designed bridge.

        At this time, the pile pillar 20 supports the load acting on the bridge so as to be firmly typed or penetrated into the ground so as not to affect the safety of the bridge.

        (B) shows a plurality of through holes 36 formed in the ground 12 so as to penetrate and fix the upper protrusion 21 protruding from the upper portion of the pile pillar 20 installed in the width direction and the longitudinal direction at regular intervals. The pier coping portion 50 is formed by penetrating the upper protrusion 21 of the pile pillar 20 into the through hole 36 of the pillar connection member 30.

        At this time, the shear member 33 formed in the through hole 36 of the pillar connection portion 30 and the front end formed in various shapes in the body of the upper protrusion 21 of the pile pillar 20 inserted into the through hole 36 The root 24 is to be able to be firmly integrated with the concrete 38 cast in the through-hole 36.

        Fig. (C) shows that after the concrete 38 placed in the through hole 36 has completed curing, the seat support block 14 is installed, and the elastic support 15 is mounted thereon, and then the girder thereon. (11) is installed on both sides of the horizontal connecting body 32 connected by the connecting portion 34 in a pair of pillar connecting member 30, the girders 11 are installed vertically and horizontally along the width and the longitudinal length of the bridge. The girder of the part where the girder is in contact with each other between the girder 11 and the girder 11 installed in the longitudinal direction is installed so that the vertical portion 31 installed at a constant area and height is installed in the width direction of the portion where the girder is continuously installed. (11) forming a groove portion in the longitudinal direction of the upper portion to form a groove portion 42 of a constant size in contact with a groove portion of an adjacent girder, and both branches of the U-shaped reinforcement 43 in the groove portion 42 having the constant size are adjacent to each other. The part connecting both branches while being inserted in the girder body After the cross section is arranged in the groove 42 as shown in FIG. 14, the non-concrete concrete 41 is poured to form the girder longitudinal connecting portion 40, and then the upper portion of the girder is used as the upper portion of the bridge or The bridge top finishing 13 is installed on the girder to install the prefabricated bridge 10.

       FIG. 12 is a view showing part A of FIG. 11 (c) in detail, and is formed by penetrating through holes 36 with a predetermined size in the center while having a predetermined thickness and area on both sides, but a stepped groove part on a lower surface of the through holes ( 37 to form a horizontal connecting body 32 to form, and the horizontal connecting body 32 is connected to each other by a connecting portion 34 to form an eight-shaped structure formed with a groove portion 35 so that the center is concave It is made of, and connected to both sides of the horizontal connecting body 32 installed on both sides with the connecting portion 34 therebetween is a column connecting member 30 consisting of vertical portions 31 installed at a constant width and height.

        The shear member 33 is formed to protrude from the entire wall surface of the through hole 36, and the through hole 36 may be installed in various shapes such as a rectangle, a circle, a polygon, and the inside of the through hole 36. The upper projection 21 of the pile pillar 20 to be inserted through, the shear root 24 to form a through-hole 22 in the body of the upper projection 21, the insertion of the reinforcement bundle as shown in Figure 7 Or install the mutually attached rebar 27 up and down at a predetermined interval on the body of the upper protrusion 21, as shown in Figure 8, so that both ends of the reinforcement protrudes to the outside of the upper protrusion and the upper and lower connecting bars 29 The upper projection 21 provided with the shearing roots 24 bound to each other is inserted, and the concrete 38 is poured into the through hole 36, and then the support base block 14 and the elastic bearings thereon ( 15) is installed, and the girder 11 is installed on it, as shown above.

        As described above, the girder 11 and the girder 11 are connected to the pillar connecting member 30 so that the vertical portion 31 of the pillar connecting member 30 is installed on the side of the installed portion. The present invention allows the girder and the girder to be installed one after another so as to prevent the girder from falling out due to shock waves on the left and right and up and down, such as an earthquake, while preventing the installation of the girder. Since the bridge can be installed in the river or the sea of the sea, so that the sea water by the water or waves of the river prevents the girder and the girder from entering the installed portion by the elastic support 15 and the bridge support block 14 fresh water In particular, it has a multi-purpose function to simultaneously serve as a protective film to prevent deterioration or corrosion easily by salts of seawater. In order to install.

       FIG. 13 is a cross-sectional view of the cross-section BB of FIG. 11 (c), which has a predetermined thickness and area on both sides, and is formed by passing through holes 36 with a constant size in the center thereof, but the lower surface of the through holes 36 is shown in FIG. A horizontal connecting body 32 is formed so as to form the stepped groove 37, and the horizontal connecting body 32 is connected to each other by the connecting part 34, and the groove part 35 is formed so that the center is recessed. Pillar connecting member 30 made of a vertical structure 31 formed in a constant width and height by connecting to both end surfaces of the horizontal connecting body 32 installed on both sides with a connecting structure 34 and the connecting portion 34 therebetween The shear member 33 is formed to protrude on the entire wall surface of the through hole 36 of the through hole 36, and the through hole 36 may be installed in various shapes such as a rectangle, a circle, a polygon, and the inside of the through hole 36. The upper protrusion 21 of the pile pillar 20 is inserted through As shown in FIG. 7, the through hole 22 is formed in the body of the upper protrusion 21, and the shear root 24 is inserted and protruded, or at regular intervals in the body of the upper protrusion 21 as shown in FIG. 8. Reinforcing bar (27) is attached to each other up and down, but the outer projection of the reinforcement to the outside of the upper projection of the upper projection 21 and the upper projection (21) provided with a shearing root (24) bound by the upper and lower connecting bars 29 is a through hole ( 36 to be inserted into, and to pour the concrete 38 into the through hole 36,

       The upper projection 21 of the pile pillar 20 in the through hole 36 is inserted into the protrusion jaw 23 of the pile pillar 20 in the stepped groove 37 formed on the lower surface of the through hole 36. Stepped groove portion 37 when the column connecting member 30 acts as a load on the pile pillar 20 by a load acting while being firmly assembled so that the whole of the pile pillar 20 does not escape into the through hole 36 when inserted. By the protruding jaw 23 of the pile pillar 20 is inserted in the) to allow the load to be transmitted to the pile pillar smoothly.

       After the concrete 38 placed in the through hole 36 has completed curing, the bridge support block 14 is installed, the elastic support 15 is mounted thereon, and the girder 11 is bridged thereon. The girders 11 are installed vertically and horizontally along the width direction and the length of the longitudinal direction, and a constant area and height on both side cross-sections of the horizontal connection body 32 connected by the connection part 34 as a pair of pillar connection members 30. The vertical portion 31 is installed so that the girder 11 is installed in the width direction of the portion installed successively, and then the groove portion in the longitudinal direction of the girder upper portion of the girder in contact with each other between the longitudinally installed girder and the girder. Forming a groove portion 42 of a predetermined size in contact with the groove portion of the adjacent girder, and both branches of the U-shaped reinforcement 43 are inserted into the adjacent girder body, and a portion connecting both branches is formed in the groove portion 42. Cross-aligned like 14 Well, the non-concrete concrete 41 is casted to form a girder longitudinal connecting portion 40, and then the upper portion of the girder is used as the upper portion of the bridge or the upper portion of the bridge is finished on the girder to form a prefabricated bridge ( 10) is installed.

       FIG. 14 is a view showing the girder longitudinal connecting portion of FIG. 13, after the concrete 38 placed in the through hole 36 of the pillar connection member 30 has completed curing, the bridge support 14 is installed. After mounting the elastic bearing 15 thereon, the girder 11 is installed thereon longitudinally and horizontally along the width direction and the longitudinal length of the bridge, and between the girder and the girder installed in the longitudinal direction The grooves are formed in the longitudinal direction of the upper part of the girder of the portion where the girder is in contact with each other to form a groove portion 42 of a constant size in contact with the groove portion of the adjacent girder, and both branches of the U-shaped reinforcement 43 are inserted into the adjacent girder body. While the part connecting both branches to be arranged in the groove portion 42, and then to pour the non-concrete concrete 41 to form a girder longitudinal connecting portion (40).

       The present invention omits the installation of the foundation supporting the bridge when installing the bridge on the river and the river bed, and install the pile pillar directly in the ground, and install the column connecting member thereon, the pile in the through hole of the column connecting member After the upper projection of the column is inserted through, the concrete is poured into the through hole, the bridge support block is installed, the elastic support is installed thereon, and the girder is installed thereon to install the bridge in a prefabricated manner. Efficient and economical bridge installation method to reduce the installation cost while minimizing the concrete installation work by simply assembling and installing girders, pile columns and column connecting members, which are manufactured at It is

Claims (8)

           Type or penetrate the pile pillar in the ground of the riverbed or the seabed of the sea in the width direction and the longitudinal direction at regular intervals with the width and length of the designed bridge, and fix it by penetrating the upper protrusion formed on the top of the pile pillar. Penetrating the upper projection of the pile pillar in the through hole of the column connecting member formed with a plurality of through holes, and cast concrete into the through hole to form a bridge coping portion, and install a bridge support block on the bridge coping portion. While installing the elastic support thereon, and install the girders on the elastic support, the girders and girders are installed adjacent to each other, the hypothesis to be located inside the vertical portion installed on both sides in the width direction of the column connecting member, The girder and the girder are formed in the groove portion formed in the longitudinal direction to form a girder longitudinal connecting portion By a pouring concrete, and then, Either leverage the bridge girder to the top bridge or the upper closing over the girder according to a prefabricated bridge to serve as upper bridge,         The girder longitudinal connecting portion is the concrete placed in the through hole of the column connecting member after curing curing, install the bridge support block, mounted on the elastic bearing thereon, and then the girder on the width and longitudinal direction of the bridge The girders are installed longitudinally and horizontally along the length of the girders, and then grooves are formed in the longitudinal direction of the upper part of the girders between the girders installed in the longitudinal direction and the girders in contact with each other to form grooves of a constant size in contact with the grooves of the adjacent girders. , While both branches of the U-shaped rebar are inserted into the adjacent girder body, the portions connecting the two branches are arranged in the grooves, and then the foundation, which is characterized by pouring non-concrete concrete, is omitted. Prefabricated bridge that used piling coping part by connecting pile column with column connection member.         The method of claim 1,         The pillar connecting member is formed by penetrating a through hole with a predetermined size in the center while having a constant thickness and area on both sides, and constitutes a horizontal connecting body to form a stepped groove in the lower surface of the through hole, and the horizontal connecting body It is made of an eight-shaped structure formed with a groove part to be connected to each other by a connecting part so that the center is concave, and the vertical part installed at a constant width and height by connecting to both end surfaces of the horizontal connection body installed on both sides with the connecting part interposed therebetween. A prefabricated bridge that utilizes as a pier coping part by connecting pile columns with pillar connecting members, omitting the foundation part characterized by being installed.         The method according to claim 1 or 2,         Shear members protrude from the entire wall surface of the through hole, and the shape of the through hole omits the foundation, which is characterized in that it is installed in one of a variety of forms, such as a square, a circle, and a polygon, and the pile pillar is a column connecting member Prefabricated bridge used as bridge pier coping part by connecting         The method of claim 1,         The pile pillar is formed so that the lower end of the pillar body is formed to be smoothly inserted into the ground, the protruding jaw is formed on the upper portion of the pillar body, and a predetermined length of the upper protrusion is formed in the protruding jaw surface. A prefabricated bridge that uses the pile column as a pier coping part by omitting the foundation and connecting the pile column with a column connecting member.         The method according to claim 1 or 4,         A through hole of a predetermined size is formed in the body of the upper protrusion, and the rebar cut into a predetermined length is disposed in the through hole, and then the reinforcing bar bundle fixed with a band reinforcing bar is protruded outward by a predetermined length through the through hole. Alternatively, the reinforcing bars are horizontally attached to a predetermined length across the entire body of the upper protrusion to protrude to the outside of the body, and then the steel bars installed at regular intervals up and down are bound with vertical connecting bars, or the steel is inserted into the through holes. The prefabricated bridge utilized as a pier coping part by connecting the pile column with the column connection member, omitting the foundation part characterized by one shearing root. delete         The method according to claim 1 or 2,         The vertical portion is to be installed on the side of the girder and the girder is installed on the through hole of the pillar connecting member so that the vertical portion of the pillar connecting member is installed from the outside so that the girder and the girder are installed in succession, while improving the aesthetics, The girder is installed in succession to serve as a girder drop-off prevention function that prevents the girder from falling out due to shock waves on the left and right and top and bottom such as an earthquake. Omitted to the base, characterized by having a multi-purpose function that also serves as a protective film to prevent the inflow of the elastic bearing and the bridge support block to be easily deteriorated or corroded by salts of fresh water, especially seawater Connect the pillar to the column connecting member A prefabricated bridge.         Type or penetrate the pile into the ground at regular intervals in the width and length of the designed bridge in the ground of the riverbed or seabed of the sea;         In the stepped groove portion provided in the lower end of the through hole of the pillar connecting member formed with a plurality of through holes so as to penetrate and fix the upper protrusion protruding from the upper portion of the pile pillar installed in the width direction and the longitudinal direction at regular intervals in the ground. Installing a protruding jaw to penetrate the upper protrusion of the piling in a through hole formed in the pillar connecting member to form a pier coping portion;         It is installed so that the shear member formed in the through hole of the pillar connection member and the shear root inserted into the body of the upper protrusion of the pile pillar inserted into the through hole can be integrally integrated with the concrete cast in the through hole. Step of doing;         After the concrete placed in the through hole finishes curing, the elastic support is mounted thereon while installing the bridge support block, and then the girder is installed vertically and horizontally along the width and length of the bridge. A vertical member installed on both sides of the horizontal connection body connected by the connection part as a pair of girder connecting members so as to have a vertical material installed in a width direction of the part in which the girder is successively installed;         Between the girder installed in the longitudinal direction and the girder to form a groove in the longitudinal direction of the upper part of the girder in contact with each other to form a groove of a constant size in contact with the groove of the adjacent girder, both branches of the U-shaped reinforcement is adjacent to the girder body The part connecting the two branches while being inserted into the cross section is arranged in the groove, and then Forming the girder longitudinal connecting portion by pouring axial concrete, and then using the upper part of the girder as it is the bridge upper part or by installing the prefabricated bridge by finishing the upper bridge on the girder The construction method of the prefabricated bridge using the pier coping part by connecting the pile column with the column connecting member without omitting the part.

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