KR200453460Y1 - Buried rail type expanasion joint system for a part of flexible coupling in bridge - Google Patents

Abstract

The present invention provides a rail-like frame embedded in a bridge slab from one side of a bridge slab located between the spacing or the side of the bridge slab between the boundary portion or the expansion joint of the slab post-concrete and the main concrete and the leakage from the periphery of the bridge slab. As it is induced and drained, the phenomenon that water leaked from the bridge deck generated at the expansion joint of the bridge flows into the bridge device or beam of the bridge can be fundamentally prevented. The present invention relates to a buried rail-type expansion joint device having a leakage preventing function of a bridge expansion joint, which can be installed either from or from the side of the flow side, thereby improving workability.

A buried rail type expansion joint device having a leakage preventing function of a bridge expansion joint according to the present invention is installed in a gap that refers to a space between bridge slabs of a bridge deck, and leaks are generated at the expansion joint between the bridge slabs. In the expansion joint device having a drainage function of the rail, both sides of the longitudinal direction is open and the rail structure is formed on one surface in the width direction of the continuous form along the longitudinal direction, and on one side of the two bridge slabs forming the flow gap It is formed in the form of a pair of fixed frames each installed in a state symmetric with each other, and the inclined surface inclined downward in both directions around the upper portion, the lower ends of the both side portions are open to the pair of fixed frames It is characterized in that it comprises a drain guide plate which is inserted through each of the parts is supported on the lower periphery of the opening.

Bridge, Expansion Joint, Leakage Prevention, Drainage, Landfill Rail, Drainage Induction Plate

Description

Buried rail type expanasion joint system for a part of flexible coupling in bridge

The present invention relates to a buried rail-type expansion joint device having a leakage preventing function of a bridge expansion joint, and more particularly, a leak between the post-casting concrete and the main concrete of the bridge slab or the expansion joint and its leakage. Water leaked from the bridge deck generated at the expansion joint of the bridge is induced by the drainage of the bridge slab embedded in the bridge slab from the side of the bridge slab, which is located toward or across the bridge slab. The phenomenon that flows into the beam can be prevented at the source, and it is possible to install a drain plate located at the flow path of the bridge slab from the upper part of the flow path or from the side of the flow path. Regarding buried rail type expansion joint device having prevention function .

In general, after the bridge is erected a number of pillars to form a skeleton on the upper side of the steel structure, concrete is placed on the skeleton of the steel structure to form the shape of the bridge top plate, the upper surface of the bridge top plate is usually coated with asphalt and normal roads Try to achieve the same conditions.

The bridge deck is increased and decreased in length by a change in temperature caused by seasons. In order to compensate for the expansion and contraction of the bridge deck, the bridge deck is divided into a number of units (in the following description, the term bridge slabra is used. It is connected elastically. Here, the expansion joint is installed at the connection portion between the bridge slab forming the bridge deck, the bridge deck and the plurality of bridge slabs forming it by the expansion joint is protected from damage due to the expansion phenomenon and at the same time smoothly Driving is guaranteed.

In addition, although expansion joints of various configurations are provided in expansion joints of bridges, conventional expansion joints for bridges are flexibly stretched according to the contraction and expansion of the bridge top plate, but structurally weak in preventing the penetration of water. Do.

Referring to FIG. 1 as an example, the expansion joint device 10 is normally installed in a block-out 22 space of a bridge (in the drawing, an example of an automobile bridge and a expansion joint device installed thereon). A crack occurs between the main concrete forming (20) and the concrete which is post-poured in the blocked-out space (hereinafter referred to as pour concrete), or a crack is formed between the concrete and the expansion joint device. And leakage occurs between these cracks. In addition, leakage occurs through the expansion joint device 10, and the rainwater or other waste water on the upper surface of the bridge slab 20 is caused by the leakage phenomenon occurring in the expansion joint device 10 and its peripheral portion. While leaking downward through the oil passage 21, the device 30 or the beam is corroded.

Republic of Korea Patent Publication No. 10-0707484 discloses a leak preventing device ("replacement expansion joint leakage prevention device") for the bridge expansion joint devised by the applicant of the present invention, this "expansion expansion joint leakage prevention device" Device ”ensures that the expansion joint and the water leaking from its periphery can be drained smoothly without entering the bridge or metal beam under the bridge slab.

Referring to FIG. 2, the replacement expansion joint leakage preventing device includes a space between bridge slabs forming a bridge top plate (in the drawing, taking an example of a railway bridge and a expansion joint installed therein) (between the bridge slabs in the following description). It is installed on the space between (using the term "gap"), and comprises a fixed support 30 and the fixed base 40 and the elastic member 50.

The fixing support 30 is formed in the form of a fixing groove, a pair of fixing support 30 is the symmetrical with each other on the basis of the opposite sides of the two bridge slab 20 bridges slab 20 Buried in the opposite side of each). Here, the pair of fixed pedestals 30 are embedded in a state in which the fixing grooves are respectively exposed to the oil passage 21. Then, a pair of fixing brackets 40 are fitted into and fixed to the pair of fixing pedestals 30, respectively, and the pair of fixing pedestals 40 are connected to the gap 21 through the fixing grooves of the fixing pedestal 30. Each is exposed. Then, both ends of the elastic member 50 is coupled to the pair of fixed base 40, the elastic member 50 is installed in the "U" shape between the bridge slabs 20, the drainage function. .

The replacement expansion joint leak prevention device devised by the applicant of the present invention is installed in a buried state irrespective of the area that is blocked out in the expansion joint between the bridge slab of the bridge. That is, when the formwork is installed to form the bridge slab, the fixed butt is fixed to the inner side of the formwork, and then concrete is placed inside the formwork to install the fixed butt on the side of the rail side of the bridge slab. Accordingly, the fixed pedestal is buried in a semi-permanent state in the bridge slab, coupled to the rail-type fixed pedestal in a sliding manner by combining the leakage member generated in the bridge expansion joint without entering the bridge or beam bridge It can be drained to the outside.

Referring to the expansion joint of Figure 1 described above in detail, the expansion joint leakage prevention device designed by the present applicant is blocked out 22, regardless of the area of the block out 22 of the bridge slab 20 It is embedded in the bridge slab 20 located below the area. That is, after fixing the fixed pedestal 30 of FIG. 2 inside the formwork (not shown), since the concrete is poured into the formwork to form the bridge slab 20, the fixed pedestal 30 is the bridge slab 20 ) Is buried and installed at the same time. In addition, after the bridge slab 20 is formed while the fixed support 30 is embedded, the block-out work for installing the expansion joint device 10 of FIG. 1 is performed.

However, the conventional expansion joint leakage preventing device for the above-described expansion member is installed in the form of the "U" shape of the bridge between the bridge, so that the phenomenon that the foreign substances accumulate on the inner surface of the expansion member, and thereby stretch There is a fear that the load acts on the member, which may lead to sagging.

That is, the rainwater or wastewater flows into the stretchable member from the road surface of the bridge deck through the expansion joint, and the rainwater or wastewater introduced into the stretchable member is introduced into the soil or other foreign matter. Accordingly, the soil and foreign matter contained in the rainwater or the wastewater may gradually accumulate on the inner surface of the stretchable member forming the drainage passage of the rainwater or the wastewater, and as the amount of the accumulated soil or the foreign matter gradually increases, the speed of accumulation may also be increased. Can be faster.

Accumulation of such soil and foreign matter acts as a load on the elastic member as described above, which can lead to sagging, deformation and shortening of the life of the elastic member. To prevent this, periodically clean the inside of the elastic member. This has to be cumbersome. In addition, in order for the elastic member to withstand the load of the soil or foreign matter accumulated therein well while maintaining the state firmly fixed to the fixing table inside the fixed support, riveting or bolting is required, which makes the installation of the elastic member relatively cumbersome.

In addition, the conventional expansion joint leakage preventing device for the expansion member is fixed to the metal holder, the holding member is coupled in a sliding manner along the fixed support while the expansion member is installed in the U-shaped shape of the bridge between the bridge of the bridge. Therefore, the expansion and contraction member is moved to the side of the bridge in the lateral direction with respect to the width direction of the bridge slab, and can not be installed, and therefore, the construction or other circumstances around the bridge is limited to the task of installing the elastic member or the process is It can be relatively difficult and difficult.

The present invention is to overcome the above-mentioned conventional problems, an object of the present invention is to the boundary between the post-pouring concrete and the main concrete or the expansion joint device of the bridge slab and the leakage occurring at the periphery of the bridge slab to the gap or flow It is to provide a drainage device using a buried rail of the bridge expansion joint to be guided and drained from the rail-shaped frame embedded in the bridge slab from one side of the bridge slab located.

Another object of the present invention is to include a leak in the drainage guide plate located in the flow of the bridge slab in the process of drainage of the boundary between the post-poured concrete and the main concrete of the bridge slab or the expansion joint and its periphery. It is to provide a drainage device using a buried rail of the bridge expansion joint formed to prevent the accumulation of foreign matters to prevent sagging or damage of the drainage guide plate and the deterioration of the drainage function.

It is still another object of the present invention to provide a drainage guide plate for guiding leakage at the boundary between the post-poured concrete and the main concrete or the expansion joint of the bridge slab and its periphery to the rail frame embedded in the bridge slab. It is to provide a drainage system using a buried rail of a bridge expansion joint, which can be installed from the side of the bridge or from the side of the stream.

In order to achieve the above object, the buried rail-type expansion joint device having a leakage preventing function of the bridge expansion joint according to the present invention is installed in a gap that refers to the space between the bridge slabs of the bridge deck between the bridge slab In the expansion joint device having a drainage function of the water leakage generated in the expansion joint portion, both sides of the longitudinal direction is open and the rail structure is formed on the one side of the width direction in the form of continuous opening in the longitudinal direction, forming the oil gap A pair of fixed frames, each of which is buried in a symmetrical state on one side of the two bridge slabs, and is formed in the form of an inclined surface in which both side portions are inclined downward with respect to the upper portion, the lower ends of the both side portions A drain guide plate is inserted into the pair of fixed frames, respectively, through the openings, and is supported by the lower periphery of the openings. And that is characterized.

In addition, the drain guide plate may be formed in a form in which the side portion is extended from both sides bent around the bent portion of the upper end and the fixing portion inserted into the opening of the fixing frame from the lower end of the side portion is bent.

In addition, the guide guide portion is formed in the insertion direction bent in the flow direction in the upper direction and is formed in a shape in which both sides and the lower portion of the longitudinal direction is open, the lower side of the open portion of the fixing frame through the lower opening the guide member Is inserted into, the insertion guide portion may guide the lower end of the side portion or the fixing portion of the drain guide plate to the inside of the opening and at the same time may support the inclined surface of the side portion.

In addition, the drainage guide plate is formed in a form in which the side portion is extended from both sides curved around the curved portion of the upper portion and the engaging portion of the forceps-type structure is provided in the lower portion of the side portion, the tong portion is an opening of the fixing frame The lower side may be inserted and supported.

In addition, the bridge slab is formed in such a shape that the height gradually decreases in the center direction from both ends in the width direction, the fixed frame includes a drain pipe extending downward from a point corresponding to the center of the bridge slab, Leakage of the expansion joint induced in accordance with it may be to be drained through the drain pipe.

In addition, the drain induction plate may be formed of a metal, polyvinyl chloride (PVC), polyethylene (PE), engineering plastics or rubber.

By the drainage system using the buried rails of the bridge expansion joint according to the present invention, the boundary between the post-pouring concrete and the main concrete or the expansion joint of the bridge slab and the leakage occurring at the periphery of the bridge slab From the one side of the bridge slab is induced by the rail frame embedded in the bridge slab and drained, the water leaked from the bridge deck generated from the expansion joint of the bridge is the original phenomenon that flow into the bridge device or beam of the bridge Can be prevented.

In addition, since the accumulation phenomenon of foreign matters contained in the water leakage is prevented with respect to the drainage induction plate located in the flow path of the bridge slab, the deflection phenomenon of the drainage induction plate and the damage caused by it are prevented, so that the structural stability of the drainage device and While durability is greatly improved, the phenomenon of deterioration of the drainage function due to the sag of the drainage guide plate or the damage thereof may be prevented.

In addition, since the drainage guide plate located in the flow path of the bridge slab can be installed from the top of the flow path or from the side of the flow path, the drainage guide plate may be considered in consideration of the situation at the time of installing the structure or other drainage around the bridge. Whether to install from the upper side of the stem or from the side of the stem, it is relatively flexible, there is an effect that can be installed more easily.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

Figure 3 is an exploded perspective view showing a rail buried expansion joint device according to an embodiment of the present invention. Figure 4 is a perspective view showing a state in which the rail buried expansion joint device is installed on the railway bridge according to an embodiment of the present invention. Figure 5 is a cross-sectional view showing the operation of drainage of the railway bridge expansion joint joint by the rail-type expansion joint according to an embodiment of the present invention.

As shown, the buried rail-type expansion joint device having a leakage preventing function of the bridge expansion joint according to an embodiment of the present invention comprises a pair of fixed frame 110 and the drainage guide plate 130 . In addition, the buried rail-type expansion joint device having a leakage preventing function of the bridge expansion joint portion may further comprise a guide member 120 and the upper cover 140.

The pair of fixed frames 110 are installed symmetrically to the bridge 161 of the bridge, that is, two different bridge slab 160 to form the bridge 161 of the bridge as shown in FIG. On one side of each is embedded in a state symmetrical with each other. The pair of fixed frames 110 have the same structure, and the structure thereof will be described based on one fixed frame 110. As shown in FIG. 3, the fixing frame 110 has both sides in the longitudinal direction open so that both sides of the longitudinal direction open to form the drainage port 111, and an opening part which is continuous in the longitudinal direction on one surface in the width direction. 112 is formed to form a rail as a whole. Then, the bent portion from the inner bottom surface of the fixing frame 110 to the lower side of the opening 112 serves as the locking jaw 113. The fixed frame 110 is embedded in the bridge slab 160 in a state in which the opening 112 is exposed to the side of the bridge 161 of the bridge.

In addition, reference numeral 162 denotes reinforcing bars embedded in the bridge slab 160, and 150 and 151 indicate fixing bolts and nut rails for fixing the fixing frame 110 to the reinforcing bars 162, and a nut rail ( 151, the nut is inserted in a sliding manner is coupled to the fixing bolt 150, the fixing bolt 150 is fixed by welding to the reinforcing bars 162. 3 and 4, the nut rail 151 and the nut inserted in the sliding manner are omitted. In addition, the fixing of the head of the fixing bolt to the fixed frame 110 by a welding method, a method of fixing one end of the fixed bolt welded to the fixed frame to the rebar 162 may be used.

In addition, the fixed frame 110 may be formed of a metal or a synthetic resin, the fixed frame of the present invention is not limited thereto.

The drainage guide plate 130 extends inclined downward in the downward direction with respect to an upper portion thereof to form a sloped surface. The drain guide plate 130 is supported by the lower portion of both side portions are inserted through the opening 112 of the fixing frame 110 at the same time the locking step 113 formed on the lower periphery of the opening 112. . Accordingly, the drainage guide plate 130 is floated and installed in the gap 161 in a state in which lower portions of both side portions are fixed to sides of two different bridge slabs 160 forming the gap 161.

Referring to the configuration of the drain induction plate 130 in more detail based on the present embodiment, the drain induction plate 130 is formed by inclining both sides of the bent on the bent portion of the upper end to form both sides of the inclined surface form The fixing part 131 is bent from the lower ends of both side parts, and the fixing part 131 is inserted through the opening part 112 of the fixing frame 110 and formed at the lower periphery of the opening part 112. Hanging jaw 113 is caught and supported.

The guide member 120 has an insertion guide portion 121 bent in the flow direction 161 in the upper portion, and is formed in a shape in which both sides and the lower portion in the longitudinal direction are open. Accordingly, the guide member 120 is inserted into and fixed to the portion of the locking step 113 positioned at the lower periphery of the opening 112 of the fixing frame 110 through the opened lower portion. The guide member 120 serves to guide the lower portion of the drain guide plate 130 inserted into the opening 112 of the fixing frame 110 is inserted from the top of the oil passage 161 toward the opening. Referring to the present embodiment, the insertion guide portion 121 of the guide member 120 guides the fixing portion 131 of the drain guide plate 130 toward the opening 112 of the fixing frame 110. do. In addition, the guide member 120 is fixed to the lower side of the opening 112 of the fixed frame 110, as shown in Figure 5, the drain guide plate 130 through the inclined surface of the insertion guide portion 121. Function to support the inclined side of the. Accordingly, the drain guide plate 130 may be fixed to the oil gap more firmly in the state that the side portions of both sides are supported by the guide member 120.

The upper cover 140 is fixed to the upper surface of the bridge slab 160 to block the upper portion of the oil gap 161 from the outside, such an upper cover 140 is usually anchor bolt 141 as in this embodiment It is fixed to the upper surface of the bridge slab 160 by the.

The drain guide plate 130 may be formed of a metal, polyvinyl chloride (PVC), polyethylene (PE), engineering plastics, or rubber.

The operation of the buried rail-type expansion joint device having a leakage preventing function of the bridge expansion joint according to the embodiment of the present invention described above.

4 and 5, the inclined side portion of the drain guide plate 130 while the leakage from the expansion joint of the bridge slab 160 flows into the bridge 161 of the bridge as illustrated by the arrow in FIG. Water leaked into the side portion of the drain guide plate 130 flows down along the inclined surface of the side portion and flows into the fixing frame 110 through the opening 112 of the fixing frame 110.

Accordingly, leaks flowing into the fixed frame 110 flow to the left and right sides of the bridge slab 160 along the fixed frame 110. Referring to FIG. 4, the fixed frame 110 is connected to the bridge slab 160. Since it is installed inclined downward from the center to the left and right both sides with respect to the width direction of the), as shown by the arrow of Figure 5 leaks flowing into the fixed frame 110 smoothly along the inclined bottom surface of the fixed frame 110 While flowing smoothly flows to the left and right sides of the bridge slab 160. In addition, since the fixed frame 110 is open at both sides in the longitudinal direction to form the opening 111, the leaks flowing to the left and right sides of the fixed frame 110 as described above are both sides of the fixed frame 110. It is discharged to the outside through the opening 111 formed in.

In other words, the leakage of water from the bridge deck generated at the expansion joint of the bridge flows into both sides of the bridge in the width direction of the bridge while preventing the water from flowing into the bridge device or the beam.

In addition, the phenomenon in which the foreign matter contained in the leaked water accumulates in the drainage guide plate 130 due to the shape of the drainage guide plate 130 is prevented. In other words, since the drain guide plate 130 has a structure in which the side portion extends downward in the form of an inclined surface from a relatively high upper portion positioned at the center, foreign matters included in the water leakage are swept away by the leakage flowing along the inclined side portion. The foreign matter does not accumulate in the side part. Accordingly, the deflection phenomenon of the drain induction plate 130 and the damage caused by it can be prevented, and the structural stability and durability of the expansion joint device can be greatly improved, while the deflection phenomenon of the drain induction plate 130 or Deterioration of the drainage function due to the damage phenomenon can be prevented.

In addition, the drain guide plate 130 positioned in the flow path 161 of the bridge slab 160 may be installed from the top of the flow path 161 or may be installed from the flow path side direction. Referring to FIG. 4, while the drain guide plate 130 is inserted from the top of the oil passage 161, the fixing parts 131 on both sides thereof are inserted into the fixing frame 110 through the opening 112 of the fixing frame 110. In this case, the both sides fixing portion 131 of the drain guide plate 130 is guided by the guide member 120 fixedly installed below the opening 112 of the fixing frame 110, the opening of the fixing frame 110 It can be easily inserted into the fixed frame 110 through the portion 112. In addition, alternatively, the drain guide plate 130 may be coupled in a sliding manner to the inside of the fixing frame 110 in any one side direction based on the width direction of the bridge slab 160.

Next, with reference to Figure 6 will be described another embodiment of the buried rail-type expansion joint device having a leakage preventing function of the bridge expansion joint according to the present invention. In the expansion joint device according to the present embodiment, the expansion joint device and drainage guide plate 230 according to FIGS. 3 to 5 are formed differently. Therefore, the expansion joint according to another embodiment of the present invention will be described with reference to the drainage guide plate 230, the same or similar parts as the expansion joint according to the embodiment of Figures 3 to 5 the same reference numerals. The detailed description is omitted here.

The drainage guide plate 230 extends in a form inclined downwardly from both sides curved around the curved portion of the upper portion, the coupling portion 231 of the forceps shape is provided at the lower end of the extended side portion, the coupling portion 231 is formed in a shape that is coupled while inserting a portion of the locking step 113 is located at the lower periphery of the opening of the fixing frame 110.

According to the above, compared with the expansion joint according to the embodiment of Figures 3 to 5 described above, the drainage guide plate 230 through the coupling portion 231 to the lower end of both side portions without the help of a separate guide member It may be coupled to the lower periphery of the opening 112 of the fixed frame (110). Accordingly, while the left and right ends of the drain guide plate 130 are fixed to the two fixing frames 110, the installation of the drainage guide plate 130 in the oil gap 161 may be more easily performed.

Next, with reference to Figure 7 will be described another embodiment of a buried rail-type expansion joint device having a leakage preventing function of the bridge expansion joint according to the present invention. In the expansion joint according to the present embodiment, the expansion joint according to FIGS. 3 to 5 and the fixed frame 310 have different structures. Accordingly, the expansion joint according to another embodiment of the present invention will be described with reference to the fixed frame 310, the same or similar parts as the expansion joint according to the embodiment of Figures 3 to 5 are the same reference numerals. The detailed description is omitted here.

The fixed frame 310 is installed on the side surface of the bridge slab 160 in the form of inclined gradually downward from both left and right sides with respect to the width direction of the bridge slab 160 in the center direction. That is, the bridge slab 160 is formed to be inclined downward from the left and right sides to the center with respect to the width direction, respectively, and the fixed frame 310 is installed in the side of the flow path 161 side of the bridge slab 160 ) Is also buried in a form inclined downward from both left and right sides to correspond to the shape of the bridge slab 160.

In addition, the drain pipe 314 extends downward from the center portion which is located at a relatively lower height than the left and right sides of the fixed frame 310, and leaks leaked from the periphery of the expansion joint of the bridge through the drain pipe. Drainage is prevented from entering the device or beam. Referring to FIG. 7, since the fixed frame 310 is buried in a lower position than the left and right sides of the fixed frame 310, the leaked water introduced into the fixed frame 310 through the drainage guide plate 130 is fixed to the frame ( Flowing downward along the 310 is concentrated in the central portion of the fixed frame 310, this leakage is concentrated in the central portion of the fixed frame 310 is guided to the outside of the bridge through the drain pipe 314 to drain, Only part of the drain pipe 314 is shown.

Reference numerals 311, 312, and 313 of the drawings show the openings, the openings, and the locking jaws, respectively, which are the same as the fixing frame of the expansion joint device according to the embodiment of FIGS. Detailed description is omitted.

Meanwhile, in the embodiments of FIGS. 3 to 7, the expansion joint device of the present invention is installed on a railway bridge, but the expansion joint device of the present invention may be applied to an automobile bridge, and of course, refer to FIG. 8. It will be described briefly.

FIG. 8 illustrates a state in which the expansion joint apparatus according to the embodiments of FIGS. 3 to 5 is installed in an automobile bridge, and the same reference numerals are used for the expansion joint apparatus according to the embodiments of FIGS. As shown in the drawing, the expansion joint is embedded in the bridge slab 460 located below the block-out 463 area irrespective of the block-out 463 area of the bridge slab 460. That is, since the fixing frame 110 is fixed to the inside of the formwork (not shown), since the concrete is poured into the formwork to form the bridge slab 460, the fixing frame 110 is formed of the bridge slab 460 At the same time the landfill is installed. Then, the drain guide plate 130 is inserted through the upper portion of the oil passage 461, and both ends thereof are inserted into and supported inside the opening of the fixing frame 110, respectively. After the fixed frame 110 and the drain guide plate 120 are installed in the bridge slab 460, the bridge slab 460 is blocked out 463, and another expansion joint 410 is disposed in the block out 463. ), And then concrete is placed in the block-out (463) space.

Accordingly, as illustrated by the arrow in FIG. 8, another expansion joint device installed in the interface between the concrete part placed in the block-out 463 area and the main concrete part poured in forming the bridge slab or in the space with the block-out 463 ( Water leakage is generated at the periphery of 410, and the water leak is introduced into the inclined side portion of the drainage guide plate 130 while flowing into the flow path 461 of the bridge. The water leakage introduced into the side portion of the drainage guide plate 130 flows along the inclined surface of the side portion and flows into the fixing frame 110 through the opening of the fixing frame 110 and is drained.

What has been described above is just one embodiment for implementing the drainage using the embedded rail of the bridge expansion joint according to the present invention, the present invention is not limited to the above embodiment, the utility model registration claims below As claimed in the present invention without departing from the gist of the present invention, any person having ordinary knowledge in the field to which the present invention belongs will have a technical spirit of the present invention to the extent that various modifications can be made.

1 is a view showing a state in which a conventional expansion joint device is installed on the automobile bridge

2 is a view showing a state in which another conventional expansion joint device is installed on the railway bridge

Figure 3 is an exploded perspective view showing a rail buried expansion joint device according to an embodiment of the present invention

Figure 4 is a perspective view showing a state in which the rail buried expansion joint device is installed on the railway bridge according to an embodiment of the present invention

Figure 5 is a cross-sectional view showing the operation of drainage leakage of the railway bridge expansion joint by the rail-type expansion joint according to an embodiment of the present invention

Figure 6 is a cross-sectional view showing a state in which the rail buried expansion joint is installed on the railway bridge in another embodiment of the present invention

Figure 7 is a perspective view showing a state in which the rail buried expansion joint device is installed on the railway bridge in another embodiment of the present invention

8 is a cross-sectional view illustrating a state in which a rail-filled expansion joint device according to the embodiment of FIGS. 3 to 5 is installed in an automobile bridge.

Explanation of symbols on the main parts of the drawings

100: expansion joint device 110: fixed frame

111,311 opening 112,312 opening

113,313: Hanging jaw 120: Guide member

121: insertion guide portion 130: drainage guide plate

131: fixing part 140: upper cover

141: anchor bolt 150: fixed bolt

151: nut rail 160: bridge slab

161: span 162: rebar

163: block out 230: drainage guide plate

231: coupling portion 310: fixed frame

314: drain pipe 410: expansion joint device

460: bridge slab 461: clearance

462: rebar

Claims (6)

In the expansion joint device having a drainage function of the water leakage is generated in the expansion joint between the bridge slab (slab) of the bridge deck slab, A pair of rail structures in which both sides of the longitudinal direction are opened and an opening portion having a continuous shape in a longitudinal direction is formed on one surface of the width direction, and each pair is buried in a state in which the two sides of the bridge slab forming the oil gap are symmetrical to each other. Fixed frame; It is formed in the form of an inclined surface in which both side portions are respectively inclined downward with respect to the upper portion, the lower end of the two side portions are respectively inserted into the pair of fixed frames through the opening portion drain guide plate is supported on the lower periphery of the opening portion A buried rail type expansion joint device having a leakage preventing function of the bridge expansion joint portion comprising a. The method of claim 1, The drainage guide plate, the bridge is characterized in that the extension is formed in a form in which the fixing portion is inserted into the opening of the fixing frame from the lower end of the side extending from both sides bent around the bent portion of the upper side A buried rail type expansion joint with water leakage prevention function. The method according to claim 1 or 2, Insertion guide portion bent in the flow direction in the upper portion is formed and further comprises a guide member formed in the shape of the open both sides and the lower portion in the longitudinal direction, the guide member is inserted into the lower side of the opening of the fixed frame through the open lower portion The buried rail-type expansion joint having a leakage preventing function of the bridge expansion joint is characterized in that the guide portion guides the lower end of the side portion or the fixing portion of the drain guide plate to the inside of the opening and supports the inclined surface of the side portion. Device. The method of claim 1, The drainage guide plate is formed in a form in which the side portion extends from both sides curved about the curved portion of the upper portion and a coupling portion having a tongs structure is provided below the side portion, and the forceps are inserted below the opening of the fixing frame. A buried rail type expansion joint device having a leakage preventing function of a bridge expansion joint portion, which is supported. The method of claim 1, The bridge slab is formed in such a way that the height gradually decreases in the center direction from both ends in the width direction, the fixed frame includes a drain pipe extending downward from a point corresponding to the center of the bridge slab, guided along the fixed frame A buried rail-type expansion joint device having a leakage preventing function of the bridge expansion joint portion, characterized in that the leakage of the expansion joint portion is discharged through the drain pipe. The method of claim 1, The drainage guide plate has a function of preventing leakage of a bridge expansion joint, which is formed of a metal, polyvinyl chloride (PVC), polyethylene (PE), engineering plastics, or rubber. Flush rail type expansion joint.

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