KR101376517B1 - Integrated Wall-Concrete Slab for Bridge and Structure of Concrete Slab for Bridge - Google Patents

Abstract

The present invention relates to a bridge integrated bottom plate and a bridge bottom plate structure, the bottom plate member is connected in the longitudinal, transverse direction to form the bottom plate of the bridge, and integrally protrudes into the bottom of the bottom plate member And a girder member supported by and supporting the bottom plate member, wherein the girder member and the bottom plate member have a bottom plate integrated girder for bridges integrally formed of a concrete material, and one side connected to the bottom plate member of the bridge. And a side wall bottom plate member provided therein, and a barrier member projecting to the other side of the side bottom plate member, wherein the side wall bottom member and the wall member are integrally formed of a concrete material. It includes, A plurality of bridge bottom plate integrated girder for connecting in the longitudinal, transverse direction, a plurality of bridges connected in the transverse direction It is to complete the construction of the bridge bottom plate by assembling the bridge wall integral bottom plate to the bridge bottom plate integrated girders respectively located at both ends of the bottom plate integrated girders.

Description

Integrated Wall-Concrete Slab for Bridge and Structure of Concrete Slab for Bridge}

The present invention relates to a bottom plate integrated girder for bridges, and more particularly, to a bridge integrated bottom plate for bridges in which the bottom plate and the girder are integrated.

In general, a bridge includes a pier, a plurality of girders, each end of which connects the pier and is spaced apart in the width direction of the leg, and a bottom plate mounted on an upper portion of the girder.

The ordinary bottom plate is constructed by installing the bottom plate formwork on the girder after installing the girder in the piers and curing by pouring concrete to the bottom plate formwork.

Therefore, the bridge construction process of the bridge was complicated, there was a difficult problem, and the construction period takes a long time due to the concrete casting, curing time.

In addition, the construction process of the bottom plate of the bridge requires a lot of labor costs and caused a significant increase in the construction cost of the entire bridge.

In addition, when the construction of the bridge, curved bridge, etc., there was a big problem more difficult with the above-described bottom plate construction method.

The bridge is equipped with a barrier to prevent an accident that the vehicle driving the bridge falls under the bottom plate.

The protective wall is to cast concrete after installing the formwork on both sides of the bottom plate installed in the field after the bottom plate construction, there is a problem that the construction period takes a long time.

In addition, since the barrier does not act integrally with the bottom plate, it acts only as a part of the bridge itself and does not dynamically resist external loads.

The purpose of the present invention is the construction of the bottom plate and the barrier wall at the same time through the assembly at the bridge construction site, to simplify the construction of the bridge upper structure, shorten the construction period, reduce the construction cost, simply by using a prefabricated method It is to provide a bridge integral wall plate and bridge deck structure that can be constructed, and improved waterproofing against leaks.

The object of the present invention is connected to the longitudinal, transverse direction to form a bottom plate of the pier finishing bottom plate member;

It includes a firewall member protruding to the other side of the side surface bottom plate member,

The barrier member and the side finish bottom plate member is to be solved by providing a bridge integrated barrier bottom plate, characterized in that formed integrally with a concrete material.

And a connecting horizontal beam member protruding integrally from the lower surface of the side finishing bottom plate member at both ends in the longitudinal direction of the side finishing bottom plate member and disposed across the width of the side finishing bottom plate member. It is done.

It characterized in that it further comprises a reinforcing horizontal beam member protruding integrally to the lower surface of the side surface finishing bottom plate member between the connecting horizontal beam member and disposed across the width of the side surface finishing bottom plate member.

The side finish bottom plate member is characterized in that a plurality of first steel wire mounting holes penetrated in the longitudinal direction and spaced apart in the width direction, and a plurality of second steel wire mounting holes penetrated in the transverse direction and spaced in the longitudinal direction.

One side of the side surface finishing bottom plate member is characterized in that the finishing side surface portion is formed integrally extending to protrude to the lower surface of the side surface finishing bottom plate member.

One side of the side finishing bottom plate member is characterized in that a transverse shear key or a transverse key groove into which the transverse shear key is inserted in the longitudinal direction is formed.

The lateral key groove is characterized in that it is formed longer than the length of the lateral shear key in the longitudinal direction of the side finishing bottom plate member.

The outer periphery of the side surface bottom plate member is a sealing groove is dug in the longitudinal direction, characterized in that it further comprises a sealing member inserted into the sealing groove.

One side of the side closing bottom plate member is characterized in that the drainage guide groove is formed in the longitudinal direction on the upper, lower portion of the sealing groove.

The object of the present invention includes a bottom plate member connected in the lateral direction to form a bottom plate of the bridge, and a girder member integrally protruded to the bottom of the bottom plate member and supported by the pier to support the bottom plate member. The girder member and the bottom plate member are integrally formed with a bridge bottom plate integrated girder;

And a side closed bottom plate member having one side connected to the bottom plate member of the bridge, and a barrier member projecting to the other side of the side closed bottom plate member, wherein the side closed bottom plate member and the barrier member are made of concrete. It includes a bridge integral bottom plate integrally formed of a material,

A plurality of bridge bottom integrated girders are connected in the longitudinal and lateral directions, and the bridge barrier integrated girders are respectively integrated in the bridge bottom integrated girders positioned at both ends of the plurality of bridge bottom integrated girders connected laterally. It is solved by providing a bridge bottom plate structure characterized in that the bottom plate is assembled.

The bottom plate member has a transverse shear key protruding from one side of the side in the longitudinal direction and the transverse shear key is inserted into the other side, and one side of the side closing bottom plate member The transverse shear key inserted into the transverse key groove of the bottom plate member in the longitudinal direction or the transverse key groove into which the transverse shear key of the bottom plate member is inserted is formed.

The lateral key groove is characterized in that it is formed longer than the length of the lateral shear key.

The girder member and the bottom plate member is made of a concrete material, characterized in that formed integrally.

The bottom plate member is a concrete material and the girder member is characterized in that the steel beam of the H type or I type is fixed to the bottom surface of the bottom plate member is fixed and integrated.

The bottom plate member is a concrete material and the girder member is H-shaped or I-type steel beam is characterized in that the upper end is embedded in the bottom plate member is integrated.

The present invention has the effect of simplifying the construction process of the upper structure of the bridge by minimizing work in the field by simultaneously installing the protective wall and the bottom plate at the time of bridge construction, shortening the construction period, significantly reducing the construction cost.

The present invention has the effect of shortening the construction period by reducing the construction of the bridge or curved bridge, and reduces the construction cost.

The present invention is excellent in durability against the bending load, it is effective to block the occurrence of water leakage and easy maintenance.

1 is a perspective view showing the basic structure of the present invention
2 is a front view of the present invention
3 is a side view of the present invention
Fig. 4 is a plan view
5 is a schematic view showing an assembled state of the present invention;
6 is an enlarged view of a portion B of FIG. 5;
7 to 8 is a view showing the present inventors and bridge deck structure
9 is a perspective view of the bridge bottom integrated girder
10a to 10d is a front view showing an embodiment of the bridge bottom integrated girder
11 is a side view of the bridge bottom integrated girder
12 is a plan view of the bottom plate integrated girder for bridges
13 is a schematic view showing an assembled state of the bridge bottom integrated girder;
14 is an enlarged view of a portion A of FIG. 13;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 to 4, the bridge integrated bottom plate 2 has a side surface connected to the bottom plate member 10 of the bridge, and has side finishing bottom plate members connected in the longitudinal and transverse directions. 50 and a barrier member 60 protruding to the other side of the side finish bottom plate member 50.

The side finish bottom plate member 50 and the firewall member 60 is integrally formed of a concrete material.

As an example, the inventors of the bridge body integral bottom plate (2) for the bridge is to be produced integrally with concrete, and is mass-produced in various standards in a manufacturing plant.

If the barrier is manufactured integrally with the bottom plate, since the 'L' type structure is applied to both ends of the bridge, the bottom plate and the barrier are simultaneously mechanically resistant to external load, thereby having a structurally excellent function.

In other words, in addition to the function of the structure that prevents the departure of the vehicle, such as the past, the barrier is added to the resistance to the external load with the bottom plate.

 In addition, the present inventors bridge bottom plate integrated girder (1) is integrated with the side surface bottom plate member 50 and the barrier member 60 is mass produced in a variety of standards and can be assembled with the prefabricated bottom plate member (10) Since the structure is formed, it can be selectively assembled according to the bridge design to simplify the bridge construction process.

In addition, the present invention has the advantage that the side plate bottom plate member 50 and the barrier wall member 60 is integrated to install the bottom plate and the barrier wall of the bridge in one construction at the same time.

In addition, the present invention does not have a joint portion between the side finish bottom plate member 50 and the barrier member 60 is capable of blocking the leakage problem at the source.

Both end portions of the side surface finishing bottom plate member 50 in the longitudinal direction, that is, the front end side and the rear side back surface protrude integrally with the lower surface of the side surface finishing bottom plate member 50 and the side surface finishing bottom plate member 50. It is preferable that the connecting horizontal beam member 30 is formed across the width of the.

The connecting horizontal beam member 30 is to increase durability by increasing the contact area of the connecting portion connected in the longitudinal direction when the side finish bottom plate member 50 is connected in the longitudinal direction, that is, the longitudinal direction.

In addition, the connecting horizontal beam member 30 is to increase the rigidity of the side finish bottom plate member 50.

The lower portion of the side closing bottom plate member 50 crosses the width direction of the side finishing bottom plate member 50 between the connecting horizontal beam members 30 and the lower surface of the central portion of the side finishing bottom plate member 50. More preferably, the reinforcing horizontal beam member 40 protruding integrally therewith is formed.

The reinforcing horizontal beam member 40 is to increase the rigidity of the side finish bottom plate member 50.

The connecting horizontal beam member 30 and the reinforcing horizontal beam member 40 are manufactured integrally with the side finish bottom plate member 50 so that the connecting horizontal beam member 30 of the bridge bottom plate integrated girder 1 to be described later. And connected to the reinforcing horizontal beam member 40 reinforces the rigidity of the bottom plate member 10 of the side finishing bottom plate member 50 and the bottom plate integrated girder 1 for the bridge to be described later, as well as the field crossbeam installation The exclusion of the process can drastically shorten the construction period and reduce the construction cost.

The side finishing bottom plate member 50 is penetrated in the longitudinal direction, that is, the longitudinal direction and spaced apart in the width direction, and the plurality of first steel wire mounting holes 52 and penetrated in the width direction, that is, the transverse direction and spaced in the longitudinal direction. It is preferable that a plurality of second steel wire mounting holes 53 are formed.

 The first steel wire mounting hole 52 communicates with each other when the plurality of side finish bottom plate members 50 are connected in the longitudinal direction and is mounted through the prestressed steel wire.

The second steel wire mounting hole 53 communicates with the lateral steel wire hole of the bridge bottom integrated girder 2 to be described later, and is mounted through the prestressed steel wire.

The prestressed steel wire penetrates through the plurality of first steel wire mounting holes 52 which are in communication with each other, thereby compressing the side finish bottom plate member 50 so that dry assembly is possible without on-site casting work. By the load applied from the upper side of the side finish bottom plate member 50 through the generated prestress is to significantly increase the strength against bending or shear occurring in the longitudinal direction of the side finish bottom plate member 50.

In addition, the prestressed steel wire is mounted through the lateral steel wire hole 12 and the second steel wire mounting hole 53, thereby compressing the side finish bottom plate member 50 in the lateral direction to form a bridge bottom plate to be described later. The bottom plate member 10 is more tightly coupled to the bottom plate member 10 of the girder 2 and is simultaneously loaded by the bottom plate member 10 and the upper portion of the bottom plate member 10 through the prestress generated in the width direction. It is to dramatically increase the strength against bending or shear occurring in the width direction.

In addition, one side of the side surface finishing bottom plate member 50 is preferably formed integrally with the finishing side surface portion 51 extending to protrude to the lower surface of the side surface finishing bottom plate member 50 in the longitudinal direction.

One side of the side finish bottom plate member 50 is formed with a transverse shear key 70 or a transverse key groove 80 into which the transverse shear key 70 is inserted in the longitudinal direction.

The lateral key groove 80 is formed to be longer than the length of the lateral shear key 70 in the longitudinal direction of the side finishing bottom plate member 50.

In addition, the transverse shear key 70 and the transverse key groove 80 is preferably formed in plural to be spaced apart from the finish side surface portion 51 to distribute and support the load.

As shown in FIGS. 5 to 6, the lateral shear key 70 is inserted into the lateral key groove 80 of the bottom plate integrated girder 1 as shown in FIGS. Both sides of the plurality of bridge bottom plate integrated girders 1 connected in the lateral direction by inserting the transverse shear key 70 of the bridge bottom plate integrated girder 1 connected to the lateral key grooves 80. It is connected to complete the bottom plate structure of the bridge.

Further, the lateral key groove 80 of the bridge integral bottom plate 20 is longer than the lateral shear key 70 of the bridge bottom integrated girder 1, and the lateral shear key of the firewall integral type. 70 is shorter than the lateral key groove 80 of the bridge bottom integral girder 1, so that the bridge bottom integral girder 1 in the longitudinal direction can be connected laterally displaced in the longitudinal direction and simply socialize Of course, if you adjust the length of the cantilevered portion of the curve bridge can be easily installed.

In addition, the finishing side surface portion 51 of the side finishing bottom plate member 50 is provided with a plurality of transverse shear keys 70 or a height difference corresponding to the transverse shear keys 70. The lateral key groove 80 is formed.

The finishing side portion 51 is connected to the side portion 11 of the bottom plate integrated girder 1 for bridges to widen the contact area at the connecting portion, so that the wheel is positioned at the connecting portion and a direct load is applied thereto. The cross section at is reinforced and prevents sag.

In addition, a sealing groove 18a is dug in the longitudinal direction on the outer periphery of the side finishing bottom plate member 50, that is, both the side surface, the front end side, and the rear end side rear surface, and the sealing member 18 is formed in the sealing groove 18a. ) Is inserted.

The sealing member 18 is to prevent the leakage of water from the upper side of the lower side bottom plate member 50 to the bottom.

One side of the side finishing bottom plate member 50 is formed in the drainage guide groove 17 in the longitudinal direction above and below the sealing groove 18a.

The drain guide groove 17 moves water toward both ends of the bridge along the longitudinal direction of the side closing bottom plate member 50 when a leak occurs from the top of the side closing bottom plate member 50 to the bottom thereof. By draining, direct leakage is prevented from occurring in the gap between the side finish bottom plate member 50 and the bottom plate member 10.

The bottom plate structure of the bridge of the present invention includes a bridge bottom plate integrated girder 1 which is assembled in plural to form the bottom plate of the bridge.

The bridge bottom plate integrated girder 1 is the bottom plate member 10 and the bottom plate are connected in the longitudinal, transverse direction to form a bridge bottom plate as shown in Figure 10a to 10d and 12, It includes a girder member 20 which protrudes integrally into the lower portion of the member 10 and is supported by a pier to support the bottom plate member 10.

The bridge bottom plate integrated girders 1 of the present invention including the girder member 20 and the bottom plate member 10 are integrally manufactured with concrete as shown in FIG. 10A and mass-produced in various sizes in a manufacturing plant. Will be.

As shown in FIG. 10B, the bottom plate member 10 is made of concrete and the girder member 20 is fixed to the bottom surface of the bottom plate member 10 by a steel beam 20a of H type or I type. And may be integrated.

As shown in FIG. 10c, the bottom plate member 10 is made of concrete, and the girder member 20 is an H-type or I-type steel beam 20a. It may be embedded in the interior of).

The girder member 20 is difficult to connect in the longitudinal direction using the shear key in the case of the H-type or I-type steel beam 20a as described above.

When the steel beam 20a is connected to each other, as shown in FIG. 10D, the steel beams 20a overlap the two webs that are in contact with each other, and the first connection plate 20b is tightly attached to both sides of the web and mounted by bolting. By using a second connection plate 20c, which is attached to the upper and lower surfaces of the lower flange while being bolted to each other, overlapping the two lower flange portions to the connection portion of the lower flange for rigid reinforcement. It is preferable to connect.

 The present invention, the bridge bottom plate integrated girder 1 is integrated into the girder member 20 and the bottom plate member 10 to be mass-produced in a variety of sizes and to be assembled with each other, and thus selectively assembled according to the bridge design. This will simplify the bridge construction process.

In addition, the present invention has the advantage that the girder member 20 and the bottom plate member 10 is integrated to install the girder and the bottom plate of the bridge at the same time in one construction.

In addition, in the present invention, there is no joint portion between the girder member 20 and the bottom plate member 10, thereby preventing the leakage problem.

The girder member 20 is integrally formed with a web portion 21 perpendicular to the bottom surface of the bottom plate member 10 at the center of the bottom surface of the bottom plate member 10, and at the lower end of the web portion 21. And provided with a flange portion 22 formed to protrude on both sides in the longitudinal direction of the web portion 21.

The flange portion 22 has a lower surface formed in a plane and is formed to have a narrower width than that of the bottom plate member 10.

The web portion 21 is preferably provided with a plurality of hollow portions 21a penetrating both sides in the longitudinal direction so as to reduce the total weight of the bottom plate integrated girder 1 for the bridge of the present invention.

Both side ends of the bottom plate member 10 may preferably be integrally formed with side portions 11 extending to protrude to the bottom surface of the bottom plate member 10 in a longitudinal direction.

In addition, connecting horizontal beam members 30 protruding integrally from the bottom surface of the bottom plate member 10 at both ends in the longitudinal direction of the bottom plate member 10 and disposed across the width of the bottom plate member 10. Is preferably formed.

The connecting horizontal beam member 30 is connected to each other when the plurality of bottom plate members 10 are connected in the longitudinal direction, that is, the longitudinal direction, and the connecting horizontal beam member 30 of the integrated wall bottom plate (2) And increase durability by increasing the contact area of the connecting portion.

In addition, the connecting horizontal beam member 30 increases the rigidity of the bottom plate member 10 and the stiffness of the girder member 20, that is, the web portion 21, in particular the bottom plate member 10 and the It is to increase the rigidity of the connecting portion of the web portion 21.

Reinforcement is integrally projected to the lower surface of the center plate of the bottom plate member 10 across the width direction of the bottom plate member 10 between the connecting horizontal beam member 30 in the lower portion of the bottom plate member 10. More preferably, the horizontal beam member 40 is formed.

The reinforcing horizontal beam member 40 increases the rigidity of the bottom plate member 10 and the stiffness of the girder member 20, that is, the web portion 21, and in particular, the bottom plate member 10 and the web portion. By increasing the rigidity of the connecting portion of (21) serves to significantly increase the overall durability of the bridge deck integrated girders 1 of the present invention.

The connecting horizontal beam member 30 and the reinforcing horizontal beam member 40 are manufactured integrally with the bottom plate member 10 and the girder member 20, and are connected when connecting the integrated girder for bridges of the present invention in a lateral direction. The reinforcing stiffness of the bottom plate member 10, as well as the on-site crossbeam installation process is eliminated to significantly shorten the construction period, it is also possible to reduce the construction cost.

The side portion 11 reinforces the rigidity at the connecting portion when connecting the bridge bottom plate integrated girder 1 of the present invention in the lateral direction, in particular the bending strength due to the load applied from the top of the bottom plate member 10 To reinforce.

In addition, both side surfaces of the web portion 21 is preferably provided with a steel wire fixing device 24 for fixing the prestressed steel wire in the lower portion of the web portion 21.

The wire anchorage 24 is to enable the application of prestress in the middle of the bridge to be constructed by the present invention.

In addition, the girder member 20 is preferably formed with a plurality of longitudinal steel wire holes 23 penetrating in the longitudinal direction so as to apply prestress to the present invention connected in the longitudinal direction.

The longitudinal steel wire hole 23 may be inserted into a separate sheath tube through which the prestressed steel wire penetrates and the steel fixing fixture 24 is mounted at the end thereof.

The bottom plate member 10 is more preferably formed with a plurality of transverse steel wire holes 12 penetrating from one side of the longitudinal direction to the other side, that is, the transverse direction.

The lateral steel wire hole 12 is communicated when the bottom plate integrated girder 1 for bridges in the present invention are connected in the lateral direction, and the prestressed steel wire is passed and mounted.

The prestressed steel wire is mounted through the longitudinal steel wire hole 23 to compress the plurality of bottom plate members 10 connected in the longitudinal direction to be more firmly coupled, and at the same time, the bottom plate member through the prestress generated in the longitudinal direction. By the load applied from the upper portion of the (10) it is to significantly increase the strength against bending or shear occurring in the longitudinal direction of the girder member 20.

The prestressed steel wire is mounted through the lateral steel wire hole 12 to compress the plurality of bottom plate members 10 connected in the lateral direction so as to be more firmly coupled, and at the same time, the bottom plate member through the prestress generated in the width direction. By the load applied from the upper portion of the (10) it is to significantly increase the strength against bending or shear generated in the width direction of the bottom plate member 10.

The inventors of the bridge bottom plate integrated girder (1) through the longitudinal steel wire hole 23 and the transverse direction through the prestressed steel wire in the longitudinal direction and transverse direction, respectively, and set up dry assembly without on-site installation during construction This is possible, and will be able to secure the rigidity of the bridge superstructure.

On the other hand, the first longitudinal shear key 13 protrudes on one of the front end side and the rear end side rear surface of the bottom plate member 10, and the first longitudinal shear key 13 is inserted on the other side. A first longitudinal key groove 14 is formed.

In addition, a second longitudinal shear key 15 protrudes on one of a front end side and a rear end side rear face of the girder member 20, and the second longitudinal shear key 15 is inserted on the other side. The second longitudinal key groove 16 is formed.

The bridge bottom plate integrated girder 1 has the first longitudinal key groove of the bridge bottom plate integrated girder 1 different from the first longitudinal shear key 13 and the second longitudinal shear key 15. 14 and the second longitudinal key groove 16 are respectively continuously connected to each other in the longitudinal direction.

The bottom plate member 10 has a transverse shear groove 70 in which a transverse shear key 70 protrudes on one side of both sides in a longitudinal direction, and the transverse shear key 70 is inserted on the other side thereof. Is formed.

The lateral key groove 80 is formed to be longer than the length of the lateral shear key 70 in the longitudinal direction of the bottom plate member 10.

In addition, the transverse shear key 70 and the transverse key groove 80 are preferably formed in plural spaced apart from the side portion 11 to distribute and support the load.

As shown in FIGS. 13 to 14, the bridge bottom integrated girders 1 of the present invention are formed in the horizontal key grooves 80 of the bridge bottom integrated girders 1 with different transverse shear keys 70. By being inserted, they are continuously connected to each other in the transverse direction.

In addition, the bottom plate member 10 has a side portion 11 extending downward from both sides in the longitudinal direction, and the transverse shear key 70 having a height difference at one side portion 11 of both side portions 11. Is provided in plurality, and the other side portion 11 is formed with the transverse key groove 80 at a height difference corresponding to the transverse shear key 70 so that the wheels are positioned at the connecting portion to be directly loaded. At that time, the cross section at the connecting portion is reinforced and sag is prevented.

In addition, a sealing groove 18a is dug in an outer circumference of the bottom plate member 10, that is, both side surfaces, a front end side, and a rear end side rear surface, and the bottom plate integrated girder 1 for bridges of the present invention is the sealing groove. It is preferable to further include a sealing member 18 inserted into (18a).

The sealing member 18 is to prevent the leakage of water from the top to the bottom of the bottom plate member 10.

Both side surfaces of the bottom plate member 10 are formed with drainage guide grooves 17 in the longitudinal direction above and below the sealing groove 18a.

The drain guide groove 17 is to drain the water by moving the water toward both ends of the bridge along the longitudinal direction of the bottom plate member 10 when the leakage occurs from the top of the bottom plate member 10, It is to prevent the leakage directly occurs in the gap between the connection portion of the bottom plate member (10).

A simple prefabricated bottom plate structure which is not integrated with the girder as in the present invention can be extended and constructed only in one direction, ie, longitudinal or transverse direction, and joined with concrete or mortar by spot casting when joining the girder. There is a problem that requires a lot of field work because the construction of the wet joint is mostly, and the leakage problem at each connection has always occurred.

The bridge bottom plate integrated girder 1 is connected to a plurality of longitudinal and lateral directions as shown in FIG. 7 to be assembled to simplify the construction of the girder and the bottom plate at the same time.

The bridge bottom plate integrated girder (1) has a first longitudinal key groove (1) of the bridge bottom plate integrated girder (1), the first longitudinal shear key 13 and the second longitudinal shear key (15) 14) and the second longitudinal key groove 16, and the transverse shear key 70 is inserted into the transverse key groove 80 of the bottom plate integrated girder 1 for the other bridges. It is connected continuously in the direction.

In addition, the bridge deck structure of the present invention connects the plurality of bridge bottom plate integrated girder 1 in the longitudinal, transverse direction to construct the bottom plate of the bridge, and the plurality of the barrier wall integrated on both sides of the constructed floor plate It is completed by assembling the bottom plate (2).

As shown in FIG. 8, the bridge bottom plate structure of the present invention has a plurality of bridge bottom plate integrated girders 1 and the barrier wall integrated bottom plate 2 in a horizontal direction when connected in one direction to each other. Not only can it be socially constructed by displacing it, but also the curved bridge can be easily constructed if the length of the cantilever is adjusted.

It will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention.

1: Bridge bottom plate girder 2: Bridges integrated wall bottom plate
10 bottom plate member 11 side portion
12 transverse steel wire hole 13 first longitudinal shear key
14: first longitudinal key groove 15: second longitudinal shear key
16: 2nd longitudinal shear key 17: drainage guide groove
20: girder member 30: connecting horizontal beam member
40: reinforcing horizontal beam member 50: side finishing bottom plate member
60: barrier member 70: transverse shear key
80: transverse keyway

Claims (15)

A side finish bottom plate member connected in the longitudinal and transverse directions to form a bottom plate of the piers;
It includes a firewall member protruding to the other side of the side surface bottom plate member,
The barrier member and the side finish bottom plate member is integrally formed of a concrete material,
Further comprising connecting horizontal beam members integrally protruding from the bottom surface of the side finishing bottom plate member at both ends of the side finishing bottom plate member and disposed across the width of the side finishing bottom plate member,
One side of the side surface finishing bottom plate member is a bridge wall integral bottom plate, characterized in that the finishing side portion is formed integrally extending to protrude to the lower surface of the side surface bottom plate member along the longitudinal direction. delete delete The method according to claim 1,
The side finishing bottom plate member is a bridge, characterized in that formed in the longitudinal direction and the plurality of first steel wire mounting holes spaced apart in the width direction, and a plurality of second steel wire mounting holes penetrated in the transverse direction and spaced in the longitudinal direction Firewall integral bottom plate. delete The method according to claim 1,
One side of the side finishing bottom plate member is a bridge barrier bottom plate, characterized in that the transverse shear key or the transverse key groove is inserted into the transverse shear key is formed in the longitudinal direction. The method of claim 6,
And said transverse key groove is formed longer than the length of said transverse shear key in the longitudinal direction of said side finishing bottom plate member. The method according to claim 1,
Sealing grooves are dug in the longitudinal direction on the outer circumference of the side finish bottom plate member,
The bridge wall integrated floor plate, characterized in that it further comprises a sealing member inserted into the sealing groove. The method according to claim 8,
One side of the side surface finishing bottom plate member, the barrier wall integrated floor plate, characterized in that the drain guide groove is formed in the longitudinal direction on the upper and lower portions of the sealing groove. A girder member connected longitudinally and laterally to form a bottom plate of the bridge, and a girder member integrally projecting to the bottom of the bottom plate member and supported by a pier to support the bottom plate member. And the bottom plate member is integrally formed with a bridge bottom plate integrated girder;
And a side closed bottom plate member having one side connected to the bottom plate member of the bridge, and a barrier member projecting to the other side of the side closed bottom plate member, wherein the side closed bottom plate member and the barrier member are made of concrete. It includes a bridge integral bottom plate integrally formed of a material,
The bridge wall integrated bottom plate protrudes integrally with the lower surface of the side finish bottom plate member at both ends in the longitudinal direction of the side finish bottom plate member and is formed to be disposed across the width of the side finish bottom plate member. Further comprising a beam member,
One side of the side closing bottom plate member is integrally formed with a closing side portion extending to protrude to the lower surface of the side closing bottom plate member in the longitudinal direction,
A plurality of bridge bottom integrated girders are connected in the longitudinal and lateral directions, and the bridge barrier integrated girders are respectively integrated in the bridge bottom integrated girders positioned at both ends of the plurality of bridge bottom integrated girders connected laterally. Bridge deck structure, characterized in that the bottom plate is assembled. The method of claim 10,
The bottom plate member is provided with a transverse key groove in which a transverse shear key protrudes on one side of both sides in a longitudinal direction and the transverse shear key is inserted into the other side,
One side of the side finishing bottom plate member is formed with a transverse shear key inserted into the transverse key groove of the bottom plate member in the longitudinal direction or a transverse key groove into which the transverse shear key of the bottom plate member is inserted. Bridge deck structure, characterized in that. The method of claim 11,
The lateral key groove is bridge bottom plate structure, characterized in that formed longer than the length of the lateral shear key. The method of claim 10,
The girder member and the bottom plate member is a concrete material, the bottom plate structure for a bridge, characterized in that formed integrally. The method of claim 10,
The bottom plate member is a concrete material and the girder member is H-shaped or I-type steel beam beam bottom plate structure, characterized in that the integrated fixed to the bottom surface of the bottom plate member. The method of claim 10,
The bottom plate member is a concrete material and the girder member is H-shaped or I-type steel beams, the upper end is embedded in the bottom plate member, the bottom plate structure for a bridge, characterized in that the integrated.

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