KR101522229B1 - Non studded girder type bridge - Google Patents

Abstract

The present invention is a semi-integral type-bridge, wherein an end separation wall (20) of an upper end of an abutment (10) and an end of a girder (30), facing the abutment (10), are integrally assembled with each other to allow an expansion joint device at an entrance part of the bridge to be omitted. A mounting groove (31) with a concave-convex shape is formed in a side end surface of the girder (30), which faces the abutment (10), a coupling part (21), which has a shape in an equal plan with the end of the girder (30), which has the mounting groove formed therein, and the end of the girder (30) and the coupling part (21) of the end separation wall (20) are fixedly coupled with each other. According to the present invention, the end separation wall (20) and the girder (30) are fixedly coupled with each other without forming any protrusion type-mounting fitting (39) at the end of the girder (30) of the semi-integral type bridge, and there is an effect to simplify a manufacturing facility and a manufacturing process.

Description

NON STUDDED GIRDER TYPE BRIDGE Non-

The present invention relates to a half-girder bridge in which an end partition wall 20 at an upper end of an alternation 10 and an alternate side 10 side end of a girder 30 are integrated to omit a bridge entrance stretch joint, The end portion side wall of the end partition wall 20 is formed with a fixing groove 31 at the side of the end portion of the alternate long side wall 30 and the end portion side wall of the end partition wall 20, The end portion of the girder 30 and the engaging portion 21 of the end partition wall 20 can be tightly engaged with each other.

The half girder bridges are constructed by integrating the girders 30 supported by the quadrangles 11 at the upper end of the shift 10 and the end partitions 20 provided at the upper rear side of the shift 10, A connection slab 12 of a bridge entrance road is connected to an upper rear portion of the girder 30 so that an expansion joint between the upper plate slab 13, the end partition 20 and the connecting slab 12 on the upper surface of the girder 30 is omitted, A deformation backfill section is formed in the rear portion of the partition wall 20 to absorb the deformation of the girder 30 and the top plate slab 13.

By omitting the expansion joint of the entrance part of the bridge, it is possible to improve the feeling of driving and reduce the noise, to prevent the structural transformation of the impact applied to the expansion joint device when passing through the vehicle, It is possible to prevent the corrosion of the calibration apparatus 11 due to a snow remover or the like. In the prior art related to such a semi-solid bridge, Patent No. 1389285 can be mentioned.

FIG. 1 schematically shows the basic structure of a conventional half-girder bridge including the patent No. 1389285. As shown in the figure, in the conventional half-girder bridge, the girder 30 supporting the upper slab 13 has an end The end of the girder 30 on the alternating side 10 is supported by the coordinate system 11 at the upper end of the alternating system 10 in a state of being fixed to the end wall 20 and joined thereto.

The integrated connection between the end portion of the girder 30 on the alternating 10 side and the end portion partition wall 20 is the same as the enlarged portion in the ellipse in Fig. 1 and the end portion of the girder 30 in which the fixing metal ball 39 is embedded The end portion of the girder 30 is embedded in the end partition wall 20 by pouring concrete into the recessed portion 29 after filling into the recessed portion 29 formed in the end partition wall 20, The method of joining the end partition wall 20 and the girder 30 in the half-body type bridge has the following problems.

2, a fixing bracket 39 is protrudingly formed at an end of the girder 30 joined to the end partition wall 20 by forming a girder (not shown) in the recessed portion 29 formed in the end partition wall 20, 30 is inserted and then the concrete is poured to fill the recessed portion 29 to ensure the adhesion between the concrete to be laid and the end portion of the girder 30. It is an essential constitution in the conventional half- .

The type of girder 30 that is used in the girder 30 including the half-girder bridges is a concrete girder 30 that is more economical than the steel bridge and easy to maintain, particularly a girder made of precast concrete 30 is a prestressed concrete girder in which a tensioned stranded wire is embedded in a main body to press both ends of the girder 30. In this concrete girder 30, In order to install the fixing metal tool 39 protruding from the side surface of the end portion of the girder 30 as described above, it is necessary to largely modify the formwork 40 for manufacturing the girder 30, There is a problem that needs to be managed.

That is, in the end portion of the formwork 40 for forming the girder 30, whether it is pre-cast or in-situ, there is a separate space for accommodating or supporting the concrete installation fixture 39, (40), it is necessary to provide not only airtightness means between elements constituting the formwork (40) but also vibration Or a complicated casting auxiliary operation such as pressurization.

The construction of the end partition wall 20 and the girder 30 in the conventional half-body bridge is the same as the construction of the end partition wall 20 after the end partition wall 20 is mounted on the top of the alternator 10, The girder 30 is inserted into the recessed portion 29 formed on the front surface of the girder 30 so that the bottom surface of the girder 30 is seated on the upper surface of the turntable 11 installed at the upper end of the shift 10, The end portion partition wall 20 is mounted on the upper end of the alternating portion 10 after the end portion partition wall 20 is seated on the coordinate system 11, A method in which the girder 30 is mounted on the coordinate system 11 after the end partitions 20 are first mounted on the alternating system 10 or the girder 30 is mounted on the coordinate system 11 And the end partition wall 20 is mounted on the alternating portion 10 after the first portion is mounted. Until the concrete placed in the recessed portion 29 is cured, There is no means for restraining the girder 30 in the case of the present invention.

As described above, the girder 30 is pre-fabricated with precast concrete and is transported to the site or manufactured at a site such as a batch plant built around the site or site, The end partition wall 20 on which the recessed portion 29 is formed is also a barbed structure which has been cured at a predetermined strength before bonding with the girder 30, The integrated part between the end partition wall 20 and the girder 30 can be referred to as an assembling operation between the existing structures in the half-length bridge. The girder 30 is provided with a recessed portion 29 formed in the end partition 20 as shown in FIG. There is no means for suppressing the lateral conduction of the girder 30 in a state where only the end portion of the girder 30 is inserted.

The girder 30 is formed as a single structure over the entire width of the bridge cross section and fixed tightly to the end partition wall 20 provided at the upper end of the alternation 10, A structure in which a plurality of girders 30 are connected to the slabs 13 is constructed as in the sectional view taken along the line B 'in FIG. 3B. In the completed bridge, lateral conduction of the girder 30 is suppressed, The outer surface of the girder 30 and the inner surface of the concave portion 29 of the end partition wall 20 are spaced apart from each other simply by being inserted into the concave portion 29 of the end partition wall 20, (30) is exposed to the lateral external force in a defenseless state.

Therefore, in the conventional half-bridge type bridge, it is necessary to carry out the operation of placing the girder 30 and the end wall, as well as the complicated construction of supporting the girder 30 at the time of curing and curing concrete with respect to the laterally inserted portion 29, As a result, not only a large amount of material is consumed but also an air delay due to the construction and demolition of the hypotheticals is caused, thereby increasing the overall construction cost.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems and it is an object of the present invention to provide a bridge structure in which an end partition wall 20 at an upper end of an alternating- In the bridge, a vertical fixing groove 31 is recessed on the side of the alternate 10 side of the girder 30. The shape of the fixing groove 31 is formed in a plane of the rectangular girder 30 The side surface of the girder 30 around the fixing groove 31 is flat and the flat section of the fixing groove 31 is formed to be inwardly inward. The front surface of the end partition wall 20 and the fixing grooves 31 Is fixedly coupled to an end portion of the girder (30) formed with the non-projecting end fixed girder bridge.

The width of the engaging portion 21 is formed to be equal to the width of the girder 30, and the width of the engaging portion 21 is formed to be equal to the width of the girder 30. Further, A coupling key 21 having a shape matching with the fixing groove 31 of the girder 30 is formed on the inner side wall of the coupling portion 21 so as to protrude to the inside of the coupling portion 21, 30 are tightly coupled to the coupling part 21 of the end partition wall 20 and the coupling key 22 of the coupling part 21 is inserted into the fixing groove 31 of the girder 30, So that the girder 30 and the end partitions 20 are fixed to each other.

The fixing rods 35 that are rods that cross the fixing grooves 31 are provided in the fixing grooves 31 of the girders 30. Both ends of the fixing rods 35 are fixed to the fixing grooves 31 The front end portion of the end partition wall 20 on the side of the girder 30 is formed with an engaging portion 21 which is inwardly recessed. The width of the engaging portion 21 is set to be smaller than the width of the girder 30 And the end of the girder 30 on which the fixing grooves 31 are formed on the side of the end partition wall 20 is tightly coupled to the coupling portion 21 of the end partition wall 20 and the end partition wall 20 The concrete is filled between the inner wall of the coupling part 21 of the girder 30 and the inner wall of the fixing groove 31 of the girder 30 so that the girder 30 and the end partitions 20 are mutually fixed. The lower end of the coupling key 22 of the end partition wall 20 is spaced upward from the lower end of the coupling portion 21 of the end partition wall 20 and is fixed to the fixing groove 31 of the girder 30 A support end 37 is formed, The end portion of the girder 30 on the side of the end partition wall 20 is tightly coupled to the coupling portion 21 of the end partition wall 20 and the coupling key 22 of the coupling portion 21 is coupled to the girder 30 And the lower end of the jogger key 22 is in close contact with the support end 37 of the fixing groove 31 so that the girder 30 and the end partition wall 20 are fixed to each other It is a non-projecting end fixed-girder bridge.

A closing plate 27 is formed at an upper end of the coupling part 21 of the end partition wall 20 so that the upper end of the coupling part 21 is closed and the bottom of the closing plate 27 protrudes inwardly of the coupling part 21 And a flat surface 38 having a shape matching the flat key 28 is formed on the upper surface of the end portion of the side of the alternation 10 side of the girder 30, 30 are tightly coupled to the coupling part 21 of the end partition wall 20 and the coupling key 22 of the coupling part 21 is inserted into the fixing groove 31 of the girder 30, Characterized in that the flat key (28) of the closing plate (27) is coupled to the groove (38) of the girder (30) such that the girder (30) and the end partition It is a fixed girder type bridge.

According to the present invention, it is possible to firmly and firmly bond the end partition wall 20 and the girder 30 without forming the integral protruding fixing metal piece 39 at the end of the girder 30 of the half-gird bridge, 30) can be obtained.

The end portion of the girder 30 can be supported by the coupling portion 21 formed on the end partition wall 20 even after construction of the bridge as well as during the construction of the bridge so that the construction of the girder 30 The stability can be maintained, and the size of the hypothetical structure required during the construction can be reduced, thereby reducing the air and reducing the construction cost.

Particularly, by applying the engaging portion 21 of the end portion partition wall 20 formed with the reed key 22, the concrete pouring, filling and curing processes for joining the girder 30 and the end portion partition wall 20 can be omitted, It is possible to shorten the total air, reduce the construction cost, and achieve a high quality control through the preliminary production of the main members, thereby improving the structural stability and durability of the completed bridge.

1 is a structural diagram of a conventional half-
2 is an exploded perspective view of a conventional half-
3 is a schematic view of the structure of the present invention
4 is an exploded perspective view of the present invention under construction
Fig. 5 is a cross-sectional exploded perspective view of the main part of the embodiment of the present invention,
Fig. 6 is a schematic view of a die for making a girder according to the present invention
Fig. 7 is a cross-sectional exploded perspective view of the main portion of the embodiment of the present invention,
Fig. 8 is an example of a die for making a girder in the embodiment of Fig. 7
Fig. 9 is a perspective view of the main part of the embodiment of the present invention,
Fig. 10 is a plan view of a cutaway exploded portion of the embodiment of the present invention,

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A detailed configuration of the present invention will be described with reference to the accompanying drawings.

3 schematically shows a basic structure of a half-body bridge to which the present invention is applied. As shown in the figure, a fixing groove 31 is formed in the end portion of the alternating- And the girder 30 and the end partition wall 20 are integrated with each other in such a manner that the portion where the fixing groove 31 of the girder 30 is formed is embedded or joined to the end partition wall 20 at the upper end of the alternation 10, Respectively.

That is, the present invention relates to a half-girder bridge in which an end partition wall 20 at an upper end of an alternation (10) and an alternate (10) side end of a girder (30) As in the excerpted enlarged portion, a vertical fixing groove 31 is recessed on the side of the alternate 10 side of the girder 30. The fixing groove 31 has a rectangular shape The side surface of the girder 30 surrounding the fixing groove 31 in the plane section is planarized while the flat section of the fixing groove 31 is formed inwardly. And the end of the girder 30 on which the groove 31 is formed is coupled and fixed.

In the illustrated embodiment, a small-sized short-span bridge is illustrated in which both ends of the girder 30 are directly supported by the alternation 10 provided in both sides of the river. However, a separate bridge bridge is added between the alternation 10 and the alternation 10 The present invention can be applied to a multi-span bridge where one end of the girder 30 is supported by the alternation 10 and the other end is supported by a bridge bridge at the start and end points of the bridge. In the case of a span bridge, a fixing groove 31 is formed at an end of the alternating girder 30 on the alternating-side 10 side.

The fixing groove 31 formed on the side surface of the end portion of the girder 30 in the present invention is a structure for fixing the fixing groove 31 to the alternating upper end partition wall 20, It is possible to firmly and firmly attach the end partition wall 20 and the girder 30 even if the fixing metal fixture 39 which is essentially installed at the end of the girder 30 of the body bridge is excluded.

The girder 30 and the end partition wall 20 of the present invention in which the fixing grooves 31 are formed are assembled by joining the ends of the girders 30 formed with the fixing grooves 31 to the coupling portions 21 formed on the end partition walls 20 The concrete is injected into and filled in the space between the surface of the end portion of the girder 30 including the fixing groove 31 and the inner surface of the recessed portion 29 or the shape of the engagement portion 21 formed in the end partitioned wall 20 It can be formed in the same manner as the end portion of the girder 30 where the fixing grooves 31 are formed and can be joined in such a manner that the engaging portion 21 of the end partition wall 20 and the end portion of the girder 30 are tightly engaged with each other.

That is, the girder 30 according to the present invention, in which the fixing grooves 31 are formed on the side surfaces of the end portions, is bonded to the end partition walls 20 in a manner similar to that of the conventional end partition walls 20 indicated by imaginary lines in the ellipse- A concave portion 29 having a width greater than the width of the girder 30 is formed in the end partition wall 20 and the end of the girder 30 is inserted into the concave portion 29. Then, But the entirety of the fixing metal piece 39 and the like is eliminated from the girder 30 of the present invention. As shown by the broken line in the enlarged part of the ellipse in Fig. 3, And the end portion of the girder 30 having the fixing groove 31 formed thereon is coupled to the end portion partition wall 20 and then the inside of the fixing groove 31 and the inside of the coupling portion 21 It can be bonded by injecting and filling concrete into the space between the surfaces.

As described above, in the present invention, since the projections are integrally formed on the side surface of the end portion of the girder 30, the coupling portion 21 of the end portion barrier 20 can be formed to coincide with the girder 30, And the girder 30 can be tightly coupled with each other during completion as well as during construction, and the conduction of the girder 30 during construction can be effectively suppressed without constructing a separate guide for restraining the girder 30 from being conducted.

In order to firmly fix the girder 30 and the end partition 20 to each other, concrete is injected into the joint or a conventional grouting technique is applied to the end surface of the girder 30 and the end partition wall 20 to achieve a firm adhesion between the inner surfaces of the engaging portions 21 of the first and second plates.

4 shows a state in which the shape of the coupling part 21 is formed so as to coincide with the end of the girder 30 in which the fixing groove 31 is formed in the manufacturing of the end partition wall 20, And the end portion of the girder 30 is tightly engaged with the end portion 21 of the engaging portion 21 so that the engaging portion 22 of the engaging portion 21 coincides with the fixing groove 31, As shown in Fig.

5, which is a detailed view of the meshing structure of the end partition wall 20 and the girder 30, the engaging portion 21, which is recessed inwardly in the front portion of the end partition wall 20 on the side of the girder 30, The width of the engaging portion 21 is formed to be equal to the width of the girder 30 and the inner side wall of the engaging portion 21 is formed with a fitting groove 31 having a shape corresponding to the fixing groove 31 of the girder 30. [ The end portion of the girder 30 on which the fixing grooves 31 are formed is provided with an end portion on the side of the end portion partition wall 20 which is tightly coupled to the engaging portion 21 of the end portion partition wall 20 The coupling key 22 of the coupling part 21 is tightly coupled to the fixing groove 31 of the girder 30 so that the girder 30 and the end partition wall 20 can be fixed to each other will be.

As shown in Fig. 5, the girder 30 having the fixing part and the end partition wall 20 having the jamming keys 22 are formed so as to have a flat cross section of the same shape, It is possible to effectively resist the axial external force of the girder 30 and to act as a single structure.

As described above, in the prior art in which the fixing bracket 39 protruding to the side of the girder 30 is applied as the fixing means when the girder 30 is joined to the end partition wall 20, in order to embed the fixing bracket 39, The girders 30 of the present invention in which the fixing grooves 31 are formed need not be entirely modified to the molding dies 40, , It is possible to produce the insert 41 having the shape of the fixing groove 31 only by a simple action of installing the insert 41 inside the mold 40 as shown in FIG. 6, thereby reducing the production cost of the girder 30 .

In particular, unlike the prior art mold 40, to which the fixture fitting 39 is applied, there is no need to form an integral through-hole or opening through the mold 40, thereby simplifying the structure of the mold 40 However, it is possible to fundamentally prevent leakage of concrete which may occur in the casting process.

7 shows an embodiment in which the end portion of the girder 30 in which the fixing groove 31 is formed and the end portion partition wall 20 having the engaging portion 21 having the rectangular cross section with the width corresponding to the width of the girder 30 are joined and fixed In order to maximize the adhesion force between the injected concrete and the girder 30 in the curing by injecting the concrete into the fixing groove 31 after the joining of the joining portion 21 and the end of the girder 30, A fixing rod 35 is provided.

7, a fixing rod 35, which is a rod that crosses the fixing groove 31, is installed in the fixing groove 31 of the girder 30, 35 are embedded in both side wall portions of the fixing groove 31 and the engaging portion 21 is recessed inward in the front portion of the end partition wall 20 on the side of the girder 30, The end of the girder 30 on which the fixing grooves 31 are formed is provided on the side of the end partition wall 20 in the same manner as the width of the end portion of the end partition wall 20 Concrete is filled between the inner wall of the coupling portion 21 of the end partition wall 20 and the inner wall of the fixing groove 31 of the girder 30 so that the girder 30, (20) can be firmly fixed to each other.

The girder 30 of the present invention to which the fixing rods 35 are attached can be manufactured through the mold 40 as shown in Fig. 8. As shown in Fig. 8, After the concrete is cured, the girder 30 formed in the mold 40 is demolded, and the insert 41 is crushed to form the concrete And the like.

The insert 41 embedded in the mold 40 in the state where the fixing grooves 31 are coupled is a material such as foamed synthetic resin that can be easily broken after demolding the girder 30, The portion of the fixing rod 35 that is exposed to the outside of the insert 41 is buried in both side wall portions of the fixing groove 31 in the finished girder 30 and the portion of the insert 41 Is exposed to the inside of the fixing groove 31 through the subsequent fracture of the insert 41. [

The fixing rods 35 of the present invention can be installed in a manner that the fixing rods 35 are embedded in the mold 40 while being coupled to the insert 41. Unlike the fixing bracket 39 of the related art, There is an advantage that it is unnecessary.

9 and 10 show the girder 30 and the end partition 20 in such a manner that the girder 30 and the end partition 20 can be effectively resisted by a vertical external force acting directly on the end of the girder 30. [ Thereby suppressing vertical displacement of the joint portion.

9 shows a state in which the latching key 22 of the engaging portion 21 of the end portion barrier 20 is formed in a part of the upper portion of the coupling portion 21 not in the entire width of the upper and lower widths, Is formed in the fixing groove 31 so that the end partition wall 20 can press and fix the end portion of the girder 30 tightly.

9, the lower end of the coupling key 22 of the end partition wall 20 is spaced upward from the lower end of the coupling portion 21 of the end partition wall 20, and the fixing groove 31 (31 The end portion of the girder 30 on the side of the end partition wall 20 is tightly coupled to the coupling portion 21 of the end partition wall 20, The jig 22 of the part 21 is tightly coupled to the fixing groove 31 of the girder 30 so that the lower end of the jigming key 22 is brought into close contact with the supporting end 37 of the fixing groove 31 So that the girder 30 and the end partition 20 are mutually fixed so that the vertical displacement of the girder 30 can be suppressed.

10 shows a state in which the upper end of the coupling part 21 of the end partition wall 20 is closed so as to be able to press the upper surface of the end part of the girder 30. The bottom part of the closing plate 27 at the upper end of the coupling part 21, It is possible to form the flat key 28 and the flat groove 38 on the upper surface of the end portion of the end portion 30 of the girder 30 so that the flat key 28 and the flat groove 38 can be engaged with each other, And the like.

10, a closing plate 27 is formed at the upper end of the coupling section 21 of the end partition wall 20 to close the upper end of the coupling section 21, And a flat groove 38 having a shape matching the flat key 28 is formed on the upper surface of the end portion of the side of the alternating portion 10 of the girder 30 so as to form the fixing groove 31 The end portion of the girder 30 on the side of the end partition wall 20 is tightly coupled to the coupling portion 21 of the end partition wall 20 and the coupling key 22 of the coupling portion 21 is engaged with the coupling portion 21 of the girder 30 The girder 30 and the end partition wall 20 are fixed to each other by making the flat key 28 of the closing plate 27 engage with the groove 38 of the girder 30 The displacement of the girder 30 in various directions can be suppressed simultaneously.

10: Shift
11:
12: connecting slab
13: Slab of roof slab
20: end partition wall
21:
22: Chi Winky
27: Closing plate
28: Pirki
29:
30: Girder
31: Settlement home
35: Fixing rods
37: Supporting stage
38: Flats
39: Settlement bracket
40: Form
41: insert

Claims (5)

delete delete A half-body bridge in which an end partition wall 20 at an upper end of an alternating system 10 and an alternate side 10 side end of a girder 30 are integrated to omit a bridge entrance elastic expansion joint, The fixing groove 31 is formed in the side surface of the fixing groove 31 so as to have a shape in which the side surface of the girder 30 around the fixing groove 31 on the plane- The end face of the end portion barrier rib 20 and the end portion of the girder 30 formed with the fixing groove 31 are fixedly coupled to each other with the flat end face of the fixing groove 31 being flattened, In the non-projecting end fixed girder bridge,
The fixing groove 35 of the fixing groove 35 is provided in the fixing groove 31 of the girder 30. The both ends of the fixing rod 35 are fixed to both inner wall portions of the fixing groove 31, The fixing rods 35 are inserted into the mold 40 in a state of being coupled to the insert 41 in the shape of the fixing grooves 31 and the concrete cured in the mold 40 is cured The inserted part 41 of the fixing rods 35 is first exposed to the inside of the fixing groove 31 by being dismounted from the girder 30 formed in the mold 40, ;
The front end portion of the end partition wall 20 on the side of the girder 30 is formed with an engaging portion 21 which is recessed inwardly and the width of the engaging portion 21 is equal to the width of the girder 30;
The end portion of the girder 30 on which the fixing groove 31 is formed is on the side of the end partition wall 20 tightly coupled to the coupling portion 21 of the end partition wall 20 and the inner wall of the coupling portion 21 of the end partition wall 20 Wherein the concrete is filled between the inner walls of the fixing groove 31 of the girder 30 so that the girder 30 and the end partition 20 are fixed to each other.
A half-body bridge in which an end partition wall 20 at an upper end of an alternating system 10 and an alternate side 10 side end of a girder 30 are integrated to omit a bridge entrance elastic expansion joint, The fixing groove 31 is formed in the side surface of the fixing groove 31 so as to have a shape in which the side surface of the girder 30 around the fixing groove 31 on the plane- The end face of the girder 30 formed with the front face portion of the end partition wall 20 and the fixing groove 31 is fixedly coupled with the flat face of the fixing groove 31, And a coupling portion 21 recessed inward is formed in the front portion of the end partition wall 20 on the side of the girder 30. The width of the coupling portion 21 is formed to be equal to the width of the girder 30, A flange 22 having a shape corresponding to the fixing groove 31 of the girder 30 is formed on the inner side wall of the girder 21 so as to protrude to the inside of the coupling portion 21 and the girder 3 0 is tightly coupled to the engaging portion 21 of the end partition wall 20 and the engaging portion 22 of the engaging portion 21 is engaged with the fixing groove 31 of the girder 30. [ In which a girder 30 and an end partition 20 are fixed to each other,
The lower end of the jig (22) of the end partition (20) is spaced upward from the lower end of the coupling portion (21) of the end partition (20)
A supporting end 37 is formed at a lower portion of the fixing groove 31 of the girder 30;
The end portion of the girder 30 on which the fixing groove 31 is formed is tightly coupled to the coupling portion 21 of the end partition wall 20 and the coupling key 22 of the coupling portion 21 is coupled to the end of the girder 30, The lower end of the jogger key 22 is brought into tight contact with the support end 37 of the fixing groove 31 so that the girder 30 and the end partition wall 20 are mutually engaged with each other And the vertical displacement of the girder (30) is suppressed. delete

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