KR101199731B1 - Bridge and Constructing Method thereof - Google Patents

Abstract

According to the present invention, a plurality of bottom plate units made of a precast concrete member are continuously installed at a lower surface of a girder installed between shifts in an axial direction between shifts to form a bottom plate, whereby a girder exists above the bottom plate. It minimizes the encroachment of the mold space due to the girders, and enables the girders to function as a barrier to prevent the vehicle from falling down, as well as reducing the number of girders required, thereby reducing the number of bridge supports. The present invention relates to a low height barrier wall bridge having a new structure configured to be constructed and a construction method thereof.
In the present invention, a pair of PC girders 10 in which the projecting catching projections 12 are formed to protrude in the lateral direction from the inner side facing each other at the lower side between the two side shifts 100 side by side at intervals in accordance with the width in the transverse direction. Or disposed between alternation 100 and pier 200; A bottom plate unit 20 spans the protruding locking jaw 12 protruding from the bottom of the PC girder 10; The bottom plate unit 20 is continuously arranged in the longitudinal direction so that the bottom plate is constructed; A bottom plate is located at a lower height of the PC girder 10, and the PC girder 10 is provided with a low height barrier wall bridge and a construction method thereof, which serve as a support wall and a barrier.

Description

Low height high barrier bridge and construction method

TECHNICAL FIELD The present invention relates to a low height barrier wall bridge and a construction method thereof. Specifically, a low-precision barrier bridge and a construction method thereof are manufactured as a precast concrete member at a lower surface position of a pair of girders installed side by side with each other, between shifts and between piers. By installing a plurality of bottom plate units in succession to form a bottom plate, the majority of the girder is present above the bottom plate, to minimize the encroachment of the die space due to the girder, and to prevent the girder from falling In addition to functioning as a barrier, the present invention relates to a low height barrier wall bridge and a construction method of a new structure that can be economically constructed by reducing the number of required girders and reducing the number of bridge supports.

In the conventional art of constructing bridges using prestressed concrete girders (hereinafter, abbreviated as "girders"), the girders are mounted in the axial direction (longitudinal direction) between two side shifts or between shifts and piers, The bottom plate will be installed at the top. Therefore, in such a conventional bridge constructed by the prior art, the girder encroaches the space under the bottom plate of the bridge, that is, the mold space.

In consideration of the encroachment of the loading space by the girder, in order to secure sufficient loading space such as vehicle traffic, the installation position of the bottom plate, that is, the linear position of the bridge, becomes considerably higher from the ground. As a result, the height of the bridge connection is increased according to the high linear position of the bridge, thereby increasing the construction cost of the bridge.

In addition, both sides of the bridge deck is required to prevent the fall of the vehicle in the longitudinal direction, such as a barrier, in the conventional bridge, such a barrier must be installed separately on the top of the bottom plate, there is a disadvantage that additional construction cost is required.

The present invention was developed to solve the above problems of the prior art, and ultimately, when constructing a bridge using prestressed concrete girder, the girder is located under the bottom plate, which is generated by encroaching the geometry space. It was developed to solve problems.

Specifically, the present invention, the girder is located under the bottom plate to encroach the mold space, the height of the bottom plate and thus the height of the overall bridge linearity is high, for this purpose, the construction cost of the bridge connection is increased to increase the construction cost To solve the problem.

In addition, the present invention, to prevent the construction cost is increased by installing a separate protective equipment, etc., and to prevent the inconvenience of construction and the increase in the number of use of the bridge support and the increase in construction cost by using a large number of girders The purpose.

In order to achieve the above object, in the present invention, a pair of PC girders protruding from the inner side facing each other protruding in the transverse direction is formed in the lower side in the transverse direction at intervals in accordance with the gap between the two sides alternately or alternately Disposed between and the piers; Both transverse ends of the bottom plate unit made of precast are spread over the protruding locking jaws protruding from the bottom of the PC girder; A bottom plate unit in which the both ends of the transverse direction span the protruding locking jaw is continuously disposed in the longitudinal direction to construct a bottom plate; A bottom plate is located at a lower height of the PC girder, and the PC girder is provided with a low height barrier bridge and a method for constructing the low height barrier bridge, characterized in that it functions as a support wall and a barrier.

In the present invention, the bottom plate unit is a flat top plate, a closing plate installed to face each other at right angles to the top plate to the bottom of the top plate at both ends in the transverse direction of the top plate, and the closing plate yarn at the bottom of the top plate The vertical support plate is installed perpendicular to the finishing plate to support the top plate; In the corner portion between the outer surface and the lower surface of the closing plate, a lower cutout portion having a size corresponding to the protruding locking jaw of the PC girder is formed, and the locking protrusion is formed to protrude on the outer surface of the closing plate by the lower cutout portion. ; When the bottom plate unit is disposed so as to span in the transverse direction between the PC girder, the locking projection may have a configuration that spans the protruding locking step of the PC girder.

In addition, in the present invention as described above, the edge portion between the upper surface of the top plate and the outer surface of the finish plate at both transverse ends of the bottom plate unit is formed with an upper cutout; In the state in which the bottom plate unit is disposed over the protruding engaging jaw of both PC girders, a space extending in the longitudinal direction is formed between the inner side of the PC girder and the upper surface of the top plate at the upper cutout portion; The filling material may be filled in the space so that the bottom plate unit and the PC girder are integrally bonded to each other.

In addition, in the present invention as described above, when the PC girder is installed between the alternation and the piers, the stepped portion is formed on the longitudinal side of the coping portion formed on the upper portion of the piers; One longitudinal end of the PC girder is installed over the stepped portion; The central portion of the coping portion existing between the stepped portions is at the same height as the bottom plate unit, and when the bottom plate unit is continuously disposed on the PC girder, the upper surface of the center portion of the coping portion and the top surface of the bottom plate unit form a continuous plane. May be

In the present invention, the bottom plate formed by the bottom plate unit is located at the lower height of the PC girder. That is, the PC girder is not placed under the bottom plate, but rather the upper surface of the bottom plate is located lower than the upper surface of the PC girder. As described above, according to the present invention, since the height of the bridge bottom plate is lowered, the height of both side shifts is also lowered, and thus the height of bridge linearity is lowered as a whole, so that the fill height of the connection part connected to the bottom plate and the shift is lowered. do. As the height of the fill is lowered, the amount of soil used for filling, the amount of compaction, and the height of the retaining wall for reinforcing the connection are also lowered, thereby simplifying the construction, reducing the construction cost, and shortening the construction period. do.

In addition, in the present invention, since the encroachment of the mold space under the bottom plate is minimized, the bridge plan is not high, and there is an advantage that it is very advantageous when crossing a railway or an existing road.

In addition, since the PC girder exists above the bottom plate, the PC girder functions as a barrier for preventing the vehicle from falling down, so that a separate protective device is not required, and the cost can be reduced.

Furthermore, since the number of PC girders required for the bridge construction is only two arranged side by side in the lateral direction, there is an advantage in that the economical efficiency is reduced because the bridge device to be installed at the end of the PC girder is reduced.

1 is a schematic view showing a state in which the shifts are installed at both ends of the bridge span in accordance with the present invention.
2 is a schematic perspective view showing a state where the PC girder is spanned between shifts.
FIG. 3 is a schematic enlarged view of a portion A of FIG. 2.
4A is a schematic perspective view illustrating a state in which two PC girders are sequentially arranged so as to cover the bottom plate unit on a protruding latching jaw of a PC girder in a state where two PC girders are arranged side by side between two shifts.
4B is a cross-sectional view taken along the line BB of FIG. 4A.
5A is a schematic perspective view from above of the bottom plate unit.
5B is a schematic perspective view of the bottom plate unit viewed from below.
6 is a schematic perspective view showing a process in which the bottom plate unit is disposed in succession.
7 is a schematic perspective view showing a state in which the bottom plate unit is disposed in succession.
8 is a schematic perspective view showing a state in which a filler is filled in the space between the bottom plate unit and the PC girder between batteries.
9 is an enlarged view of a circle C portion of FIG. 8.
10 is a schematic perspective view showing a state in which a expansion joint device is installed between the bottom plate unit and the shift.
FIG. 11 is a schematic perspective view showing a state in which alternating and intermediate piers on both sides are installed in order to construct a two-span continuous bridge. FIG.
12 is a schematic perspective view showing a state where the PC girder is disposed between the piers and the shifts respectively.
FIG. 13 is a schematic perspective view illustrating a state in which the bottom plate unit is sequentially disposed between the PC girders in the state shown in FIG. 12.
FIG. 14 is a schematic perspective view illustrating a state in which a bottom plate unit is disposed between cells after the state shown in FIG. 13.
FIG. 15 is a detail of circle D in FIG. 14.

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, it is to be understood that the technical idea of the present invention and its essential structure and operation are not limited thereby.

1 to 10 as an example of a low height barrier bridge according to the present invention, there is shown a schematic diagram showing each step of constructing a low height barrier wall bridge between short spans.

1 is a schematic view showing a state in which the shift 100 is installed at both ends of the bridge span. In Fig. 2, a prestressed concrete girder 10 (hereinafter, abbreviated as "PC girder") that functions as a barrier to prevent a vehicle passing through the bridge from falling out of the bridge and simultaneously supports a bottom plate. A perspective view showing a state spanning the alternate 100 is shown, and FIG. 3 schematically shows an enlarged view of the circle A portion of FIG. 2. For reference, the term "longitudinal" is used herein to indicate an axial direction, and the term "lateral direction" is used to indicate a direction perpendicular to the longitudinal direction, ie, perpendicular to the longitudinal direction. "Vertical direction" was used to indicate the height direction of the bridge perpendicular to the longitudinal direction.

As shown in Figures 2 and 3, the PC girder 10 used in the present invention has a shape extending in the axial direction as in the general girder used in the general bridge, the inner end of both ends in the axial direction A fixing unit 11 is formed in which the tension member disposed in the fixing unit is fixed. However, as will be described later in the present invention, since the bottom plate of the bridge is supported across the lower portion of the PC girder 10, the lower portion of the PC girder 10 protrudes from the inner side facing each other is formed protruding in the transverse direction have. The protruding locking jaw 12 is formed in the entire axial length of the PC girder 10. As will be described later, since both ends of the bottom plate extend in the protruding stopper 12, the reinforcing bars 13 are laterally disposed in the protruding stopper 12 so as to have sufficient rigidity to support the bottom plate. It can be placed inside.

On the other hand, as described later, the bottom plate unit 20 spans the PC girder 10 and penetrates the PC girder 10 and the bottom plate unit 20 in a transverse direction. Fixing recesses 14 may be formed on the outer side of the PC girder 10 as shown in the figure to facilitate fixing to the outer side of the PC girder 10. The through hole through which the tension material penetrates is formed through the PC girder 10 in the transverse direction in the fixing recess 14.

When constructing a bridge between short diameters, a pair of PC girders 10 made of precast so as to have the configuration described above are disposed between the two side shifts 100 side by side at intervals in the transverse direction in accordance with the width of the bridge.

In FIG. 4A, in the state where two PC girders 10 are arranged side by side between the two shifts 100, the bottom plate unit 20 covers the bottom plate unit 20 on the protruding latching jaw 12 of the PC girder 10. A schematic perspective view showing a state of sequentially arranging 20 is shown, and FIG. 4B is a cross-sectional view taken along the line BB of FIG. 4A, with the bottom plate unit 20 installed across the PC girder 10. A longitudinal cross section is shown. 5A and 5B show a perspective view from above and a perspective view from below of the bottom plate unit 20, respectively.

In the bridge of the present invention, as described above, the bottom plate is supported by the PC girder 10 by the bottom plate unit 20 made of precast is spanned over the protruding engaging jaw 12 of the PC girder 10. 4A, 4B, 5A, and 5B, a plurality of bottom plate units 20 are continuously arranged in the longitudinal direction to form a bottom plate. In the embodiment shown in the drawing, the bottom plate unit 20 is installed at right angles to the top plate 21 below the top plate 21 at each of the flat top plate 21 and the transverse opposite ends of the top plate 21. A vertical plate 22 perpendicular to the closing plate 22 and the upper plate 21 between the closing plate 22 and the closing plate 22 at the lower portion of the upper plate 21 to support the upper plate 21. It is comprised by the support plate 23. In the drawing, although the vertical support plate 23 is shown as being provided with two, the number of the vertical support plate 23 can be increased or decreased as necessary, the closing plate 22 and the vertical support plate 23 may be omitted. have. The bottom plate unit 20 may be made of a precast concrete member, and the finishing plate 22 and the vertical support plate 23 may be formed through the tension material through-holes through which the tension material extends in the extending direction thereof.

Both end portions in the transverse direction of the bottom plate unit 20 having such a configuration are disposed over the protruding engaging jaw 12 of both PC girders 10. The bottom surface of the closing plate 22 is placed on the protruding engaging jaw 12, the bottom plate unit 20 may be installed to cross the transverse direction between the two PC girder 10. However, in the exemplary embodiment shown in the drawing, the lower cutout portion 231 having a size corresponding to the protruding engaging jaw 12 of the PC girder 10 is formed at the corner between the outer surface and the lower surface of the closing plate 22. The lower cutting portion 231 is formed so that the locking protrusion 232 protrudes to the outer surface of the closing plate 22, and the locking protrusion 232 is projected on the protruding locking step 12 of the PC girder 10. Has a straddling configuration. As such, when the bottom plate unit 20 in which the locking protrusions 232 are formed is disposed so as to span the horizontal direction between the PC girders 10, the lower end of the horizontal plate 22 in the horizontal direction is the protruding locking jaw 12. The upper surface of the bottom plate unit 20 can be lowered as compared to the case where the bottom plate unit 20 is installed transversely between both PC girders 10 on both sides, so that the height of the PC girder 10 can be lowered. It is possible to fully utilize the function of the barrier using the function, and to minimize the encroachment of the space under the floor plate.

On the other hand, the upper cutout portion 233 is formed at the corners between the surface of the top plate 21 and the outer surface of the finishing plate 22 at both transverse ends of the bottom plate unit 20. Therefore, a space is formed between the inner side surface of the PC girder 10 and the upper surface of the upper plate 21 in a state in which the bottom plate unit 20 is disposed over the protruding engaging jaw 12 of both PC girders 10. The space is extended in the longitudinal direction. By filling the space 235 such as non-shrink mortar, the bottom plate unit 20 and the PC girder 10 are integrally bonded to each other (see FIG. 9 to be described later).

The bottom plate unit 20 shown in FIGS. 5A and 5B is located at the start and end portions in the longitudinal direction connected to the shift 100, and the top plate in the shift 100 direction for installation of the expansion joint. (21) The longitudinal cutout part 29 is formed in the upper edge of the edge part over the horizontal length. The said longitudinal cutout part 29 is mentioned later. The longitudinal cutout 29 is sufficient to be formed only in the bottom plate unit 20 in a position that is connected to the alternate 100, it is not necessary to be formed in the bottom plate unit 20 in another position.

6 and 7 are schematic perspective views illustrating a process in which the bottom plate unit 20 is continuously arranged and a state in which the arrangement is completed. As described above, as shown in FIG. 6, the transverse both ends of the bottom plate unit 20 are disposed to extend over the protruding engaging jaw 12 of both PC girders 10, and thus, the plurality of bottom plate units 20 are provided. By continuously installing in the longitudinal direction, as shown in Fig. 7, the bottom plate is formed by the continuous arrangement of the bottom plate unit 20 between all the shifts.

8, a filler 235 such as non-condensed mortar is formed in a space between an upper cutout 233 formed on the top plate 21 surface of the bottom plate unit 20 and an inner side surface of the PC girder 10. A schematic perspective view showing a filled state over the liver is shown, and FIG. 9 shows an enlarged view of the circle C portion of FIG. 8. 10 is a schematic perspective view showing a state in which the expansion joint is installed between the bottom plate unit and the shift.

As shown in FIG. 8, in a state in which a plurality of bottom plate units 20 are continuously installed in the longitudinal direction to form a bottom plate over the entire period, upper cutouts 233 formed on upper surfaces of both ends of the bottom plate unit 20. And the bottom plate unit 20 and the PC girder 10 are integrally bonded to each other by filling the filling material 235 such as non-contraction mortar in the space between the inner side surface of the PC girder 10 and the battery. After placing the tension member through the PC girder 10 and the bottom plate unit 20 in the lateral direction and fixing the end portion of the tension member on the outer side of the PC girder 10, the PC girder 10 is applied by applying tension in the lateral direction. ) And the bottom plate unit 20 may be further integrated.

Meanwhile, as shown in FIGS. 8 and 9, in the bottom plate unit 20 positioned at the start and end portions in the longitudinal direction connected to the shift 100, the upper portion of the upper end of the upper plate 21 in the shift 100 direction is shown. The edge is formed with the longitudinal cut-out part 29 over the horizontal length. The alternating cutout 102 is also formed at the upper side of the side face facing the bottom plate unit 20 in the vertical plate 101 of the alternating 100 facing this. Thus, as shown in FIG. 9, the longitudinal cutout is located at the upper portion of the bottom plate unit 20 positioned at the longitudinal start and end portions of the bottom plate and the vertical plate 101 of the alternate 100. A space extending in the transverse direction is formed by the 29 and the alternate cutout 102, and the expansion joint 110 is provided in this space (see FIG. 10). To this end, the upper height of the vertical plate 101 in the shift 100 should be equal to the height of the upper surface 21 when the bottom plate unit 20 is installed in the PC girder 10. In FIG. 10, the filler 235 is filled between the batteries between the transverse end of the bottom plate unit 20 and the inner side surface of the PC girder 10, and the vertical plate 101 and the bottom of the shift 100 are alternately formed. A schematic perspective view showing a state in which the expansion joint device 110 is installed between the plate units 10 is shown. Since there is no limitation on the type and configuration of the expansion joint device 110 in the present invention, in Figure 10 for convenience, expansion joint device 110 is shown in a shaded state without showing the detailed configuration.

As described above, in the present invention, the bottom plate formed by the bottom plate unit 20 is located at the lower height of the PC girder 10. That is, the PC girder 10 is not placed under the bottom plate, but rather the upper surface of the bottom plate is positioned lower than the upper surface of the PC girder 10. Since the height of the bottom plate is lowered as described above, the height of both side shifts is also lowered, so that the height of the bottom plate as a whole, that is, the height of the bridge linearity is lowered, and the fill height of the connection part connected to the bottom plate and the shift is low. You lose. Since the height of the fill is lowered, the amount of soil used for filling, the amount of compaction, and the height of the retaining wall for reinforcing the connection are also lowered, thereby simplifying the construction and reducing the construction cost and shortening the construction period.

In addition, since the encroachment of the mold space under the bottom plate is minimized, the bridge plan is not high, which is very advantageous when crossing railroads or existing roads.

In addition, since the PC girder 10 exists above the bottom plate, the PC girder 10 functions as a barrier for preventing the vehicle from falling down, and thus does not require a separate protective equipment, thereby reducing the cost. The effect is exerted.

Furthermore, since the number of PC girders 10 required for the bridge construction is only two, the device to be installed at the end of the PC girder 10 is reduced as well, so there is an advantage in that the economy is excellent.

Next, with reference to Figures 11 to 15 as another example of the low height barrier bridge according to the present invention will be described for the low height barrier wall bridge in the form of a two-span continuous bridge. 11 to 15 are schematic views showing the construction stages of the low height barrier bridge of the two-span continuous bridge type. In the embodiment shown in Figures 11 to 15, the same reference numerals are used in the drawings and specifications for the same configuration as the embodiment shown in Figures 1 to 10, and repeated description thereof will be omitted.

FIG. 11 is a schematic perspective view showing a state in which the alternating bridges 100 and the intermediate piers 200 are installed to construct a two-span continuous bridge. In the two-span continuous bridge of the present invention, the coping portion 201 formed on the upper portion of the bridge 200 forms a part of the bottom plate. That is, stepped portions 202 are formed at both sides in the longitudinal direction of the coping portion 201 formed on the top of the piers 200, and end portions of the PC girders 10 extend in the longitudinal direction, and between the stepped portions 202. The central part of the coping part 201 which exists in becomes a part of the bottom plate of a bridge as mentioned later. FIG. 12 is a schematic perspective view showing a state where the PC girder 10 is disposed between the pier 200 and the shift 100, respectively, as shown in FIG. 12, one end of the girder 10 is the pier. 200 is placed on the stepped portion 202 above.

FIG. 13 is a schematic perspective view illustrating a state in which the bottom plate unit 20 is sequentially disposed between the PC girders 10 after the state shown in FIG. 12, and FIG. 14 is illustrated in FIG. 13. A schematic perspective view is shown showing the state in which the bottom plate unit 20 is disposed across cells following the state. FIG. 15 shows a detail of circle D of FIG. 14.

As shown in FIGS. 13 to 15, the bottom plate unit 20 is continuously disposed between the PC girders 10 at both sides, and an inner side surface of the PC girder 10 and an upper surface of the bottom plate unit 20 are provided. Filler 235 is filled between (21), and the expansion joint is installed between the vertical plate 101 of the alternate 100 and the bottom plate unit 20 located in the longitudinal start and end. This is the same as the contents described above with reference to FIGS. 1 to 10.

As shown in detail in FIG. 15, where the pier 200 is located, the central portion of the coping portion 201 is at the same height as the bottom plate unit 20, and thus the upper surface of the central portion of the coping portion 201 and the bottom plate unit. The upper surface of 20 forms a continuous plane. In FIG. 15, it is shown that the space between the PC girders 10 disposed between both sides is vacant. After fixing the tension member disposed in the longitudinal direction of the PC girders 10 at the ends of the PC girders 10, the both sides are fixed. Between the girder 10 disposed in the space between the girder 10 to install the formwork in the empty space to install the concrete or to install a railing or the like to prevent the fall of vehicles or pedestrians.

In the above, the two-span bridge has been described as an example, but the present invention can be equally applied to multi-span bridges over three-span bridges.

As described above, the multi-span bridge of the present invention enjoys the same effects as described above with respect to the short-span bridge, and the coping portion 201 of the pier not only serves to support the girder but also the bottom plate. As a part of the configuration, the structural utilization is increased.

10: PC girder 20: bottom plate unit 100: shift

Claims (7)

delete A pair of PC girders 10 having protruding locking jaws 12 protruding in the transverse direction from the inner side facing each other at the lower side are alternately arranged between the two side shifts 100 or alternately with the alternate 100 in a transverse direction. Disposed between 200;
Both transverse ends of the bottom plate unit 20 made of precast span the protruding locking jaw 12 protruding from the bottom of the PC girder 10;
The bottom plate unit 20 is continuously arranged in the longitudinal direction so that the bottom plate is constructed;
A bottom plate is positioned at a lower height of the PC girder 10, and the PC girder 10 performs a function of supporting the bottom plate and a barrier;
The bottom plate unit 20 includes a flat top plate 21 and a closing plate 22 installed at right angles to the top plate 21 below the top plate 21 at both ends of the top plate 21 in the lateral direction. In the lower part of the upper plate 21 between the closing plate 22 and the orthogonal to the closing plate 22 and the upper plate 21 is composed of a vertical support plate 23 for supporting the upper plate 21 and ;
A lower cutout 231 is formed at an edge portion between the outer surface and the lower surface of the closing plate 22 so that the locking protrusion 232 protrudes on the outer surface of the closing plate 22 by the lower cutting part 231. Formed;
When the bottom plate unit 20 is disposed so as to span in the transverse direction between the PC girder 10, the locking projection 232 is a configuration that spans the protruding locking step 12 of the PC girder 10 Low height firewall bridge, characterized by having.
The method of claim 2,
An upper cutout portion 233 is formed at edges between the surface of the upper plate 21 and the outer surface of the closing plate 22 at both transverse ends of the bottom plate unit 20;
In the state in which the bottom plate unit 20 is disposed over the protruding engaging jaw 12 of both PC girders 10, the inner side of the PC girder 10 and the top plate 21 in the upper cutout 233. Spaces extending in the longitudinal direction are formed between the upper surfaces of the "
Filler 235 is filled in the space, the bottom plate unit 20 and the low barrier wall bridge, characterized in that the structure having a structure that is integrally bonded to each other.
The method of claim 2,
In the PC girder 10 is installed between the shift 100 and the piers 200,
A stepped portion 202 is formed at the longitudinal side of the coping portion 201 formed on the top of the piers 200;
One longitudinal end of the PC girder 10 is installed across the stepped portion 202;
When the center portion of the coping portion 201 existing between the stepped portion 202 is present at the same height as the bottom plate unit 10, when the bottom plate unit 10 is continuously disposed on the PC girder 10 , The upper surface of the central portion of the coping portion 201 and the upper surface of the bottom plate unit 20 forms a continuous plane, characterized in that the high security barrier bridge.
In the lower part, a pair of PC girders 10 in which the protruding engaging jaw 12 protrudes in the lateral direction from the inner side facing each other are arranged side by side at intervals in the transverse direction or alternately 100. Disposed between and the piers 200;
The top plate 21 is made of precast, the top plate 21, the finishing plate 22 is installed at right angles to the top plate 21 to the lower side of the top plate 21 at both ends in the transverse direction of the top plate 21, and the top plate It consists of a vertical support plate 23 is installed orthogonally to the closing plate 22 and the upper plate 21 between the closing plate 22 in the lower portion of the 21 to support the upper plate 21, the finish A lower cutout 231 is formed at an edge portion between the outer surface and the lower surface of the plate 22 so that the locking protrusion 232 protrudes on the outer surface of the closing plate 22 by the lower cutout 231. Between the pair of PC girders 10 so that the locking projections 232 at both ends of the transverse direction extend over the protruding locking jaws 12 protruding from the bottom of the PC girder 10. Mounting on; And
Repeating the mounting step between the PC girder 10 of the bottom plate unit 20 to form the bottom plate by continuously placing the bottom plate unit 20 in the longitudinal direction, of the PC girder 10 A bottom plate is located at a lower height, and the PC girder (10) is a construction of a low height firewall wall bridge is to construct a low height firewall wall structure having a structure to perform the function of the support and the barrier wall.
The method of claim 5,
An upper cutout portion 233 is formed at edges between the surface of the upper plate 21 and the outer surface of the closing plate 22 at both transverse ends of the bottom plate unit 20;
In the state in which the bottom plate unit 20 is disposed over the protruding engaging jaw 12 of both PC girders 10, the inner side of the PC girder 10 and the top plate 21 in the upper cutout 233. Spaces extending in the longitudinal direction are formed between the upper surfaces of the "
Filling the filling material in the space 235, the bottom plate unit 20 and the construction method of the low height barrier bridge, characterized in that it further comprises the step of integrally bonding to each other.
The method according to claim 5 or 6,
A stepped portion 202 is formed at a longitudinal side of the coping portion 201 formed on an upper portion of the piers 200 on which one longitudinal end of the PC girder 10 is mounted;
Disposing the PC girder (10) between the shift (100) and the pier (200), such that one longitudinal end of the pc girder (10) is installed across the stepped portion (202);
When the center portion of the coping portion 201 existing between the stepped portions 202 is at the same height as the bottom plate unit 10, when the bottom plate unit 10 is continuously disposed on the PC girder 10, Method of constructing a low height barrier bridge, characterized in that the upper surface of the central portion of the coping portion 201 and the upper surface of the bottom plate unit 20 forms a continuous plane.

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