KR102048803B1 - Extension joint using compression fixed type high elastic material - Google Patents

Abstract

The present invention relates to an expansion joint using a compression-fixed high-elastic material. More specifically, a high-elasticity rubber sealant (hereinafter referred to as ′sealant′) is installed between a pair of connection reinforcement plates installed between opposite slabs of a bridge, which are joints of the bridge, but a gap between the connection reinforcement plates is filled with the sealant in a state in which a distance between the connection reinforcement plates is maximized, in other words, a state in which the opposite slabs are maximally contracted, and then, the sealant is compressed, thus increasing waterproof performance against the permeation of rainwater or the like. Through first and second support frames and control bolts installed inside the connection reinforcement plates, the sealant is controlled to be attached tightly to the inner surface of the connection reinforcement plates to prevent the sealant from being separated from the connection reinforcement plates with the expansion and contraction of the slabs, especially, contraction. Therefore, the expansion joint using a compression-fixed high-elastic material is capable of preventing shearing or sagging caused by the contraction and expansion of the slabs.

Description

Expansion joint using compression fixed type high elastic material

The present invention relates to an expansion joint device using a high elastic material, in more detail, it is installed between the joints of the bridge, that is, a pair of connecting reinforcing plate installed between the slab of the opposite bridge, High elastic rubber sealant which is compressed after being installed between the pair of connecting reinforcing plates in a state where the distance between the pair of connecting reinforcing plates is maximized, that is, the opposed slab is in the maximum contraction state (hereinafter referred to as By installing a sealant) to increase the waterproof performance against the penetration of rainwater, and the like by the first support frame, the second support frame and the adjustment bolt installed inside the pair of reinforcing plates. Is firmly in close contact with the inner side of the connecting reinforcement plate to prevent the phenomenon of the sealant from falling off the connecting reinforcement plate by contraction and expansion of the slab, in particular by contraction As a result, it is a technical field of a expansion joint device using a compression-fixed high-elastic material that can prevent the deflection or shear caused by shrinkage and expansion of the opposite slab.

In general, the slab included in the upper structure of the bridge contracts or expands along its longitudinal direction due to temperature change during winter and summer, and also changes in ambient temperature, load of live load, earthquake, contraction, stress relaxation, settlement Many internal and external elements of the bridge, etc., cause the superstructure to trigger relative movement with the substructure, which can be varied by rotation in the direction of the axial direction, the perpendicular direction of the axial direction, or the direction of the axial direction.

Accordingly, since the slab may be deformed and the bridge may be broken due to the expansion or contraction of the slab, an expansion joint device for accommodating the expansion and contraction of the slab is required between the slab and the slab.

Therefore, the upper structure of the bridge is used to absorb the deformation of the structure such as temperature change, drying shrinkage, creep, and to smoothly operate the vehicle while minimizing the impact force caused by the vehicle load, and to prevent the drainage from being discharged to the alternating and pier sides. Expansion joints with waterproof function are installed.

The expansion joint is largely an open joint, a filled joint, a sliding plate joint, a finger plate joint, a sawtooth plate joint. ), Compression Seal Joint, Strip Seal Joint, Sheet Seal Joint, Plane Seal Joint, Modular Joint ) And the like.

These expansion joints belong to a small member of the bridge structure, but when they do not properly exhibit a number of problems can occur, the following describes the problems of the conventional expansion joints.

First, the expansion joint is a device for smoothly accommodating the movement and rotation of the upper elevation due to the expansion and contraction, creep, and live load due to the expansion and contraction due to temperature change, but the increase of traffic volume, neglected construction, unsatisfactory repair The most frequent breakage occurs among the components of the bridge due to the lack of timely maintenance.

Second, when water leaks through the expansion joints, the structures underneath it deteriorate. Also, when the expansion joints become inoperative, many members of the bridge are subjected to excess stress and are easily damaged.

Third, when the expansion joint is damaged, the rubber material or sealing material in the inner part may be loosened, torn or broken, and the drainage gutters of the catchment may be filled with debris and foreign matters in the drainage gutter at the lower part thereof, so that the drainage and stretching action may not be performed smoothly. do.

Fourth, when the expansion joints are damaged, loosening and rusting of other steel parts such as steel sheets, section steel, anchor bolts, cracking and dropping of concrete, rusting of structural steels and exposure of reinforcing bars, noise of passage of vehicles, Damage due to vibration, signs of bridge settlement, and the like can occur.

Looking at the structure of the conventional expansion joint device installed in the clearance space, that is, the clearance space between the end and the end of the slab having the above problems, the connecting reinforcing plate arranged to face each other at regular intervals, and the back of the connecting reinforcing plate And a rod-shaped stud anchor that is integrally welded to and coupled with reinforcing bars embedded in each slab.

At this time, the space between the connecting reinforcing plate of one side and the other to be bound to the slab becomes the clearance, the upper elastic material is mounted so that the clearance between the connecting reinforcement plate is not visible, the lower portion of the connection between the reinforcing plate The expansion material for the drainage that serves as a drainage is mounted, and the upper expansion material and the expansion material for drainage are made of a rubber material.

In more detail, the upper elastic material is provided in the form of stretchable corrugation is fixed to the wall of one connecting reinforcement plate and the other connecting reinforcing plate by means of a bolt or the like, the expansion material for the drainage drainage It is provided in the form of a "U" to form a groove is fixedly mounted on the wall of one side of the connection reinforcement plate and the other side of the connection reinforcement plate through the bolts.

At this time, the stud anchor of the connecting reinforcing plate is filled by the non-contraction concrete together with the reinforcing bar of the bridge, the surface of the saik non-contraction concrete becomes a road surface that is parallel to the surface of the bridge.

Therefore, when the slab 100 expands or contracts along its longitudinal direction due to external environmental conditions, that is, temperature change, drying shrinkage, creep, etc., the connecting reinforcing plate, which is connected to the reinforcing bar of the slab, moves forward or backward, and at the same time, As the upper and lower elastic materials different from the reinforcement plate are stretched or contracted, the expansion or contraction of the slab is absorbed. In addition, the rainwater flowing through the gap between the upper expansion material and the slab during rainy weather is drained to the side of the bridge via the expansion material for the drainage.

However, the conventional expansion joint device as described above has a problem of damage due to easy tearing due to the repeated expansion and contraction load of the slab and the repeated expansion load of the vehicle or railway, while the upper expansion material is damaged, and the upper expansion material is damaged. According to the present invention, there is a problem in that the waterproofing property inherent in the lower stretchable material for the drainage channel is degraded, such as rainwater is excessively filled and overflows at the bottom of the stretchable material disposed below the rainwater. There is a problem that secondary breakage and destruction of the bridge may occur by generating a phenomena of deterioration of concrete such as bridges and bridges by the rainwater penetrated, and at the same time rust.

In addition, in the conventional expansion joint device as described above, the stud anchor is integrally connected to the back of the connecting reinforcing plate in the state that the wire is simply bound with the slab of the slab, the stud anchor is repeatedly repeated in the non-shrink concrete during the contraction and expansion of the slab. By moving forward and backward linearly, stress is concentrated on a wire or the like, and there is a problem in that the stud anchor is separated from the rebar of the slab while the wire and the like are broken.

In particular, in the conventional expansion joint device as described above, in addition to the problem that the upper expansion material and the lower expansion material is damaged by repeated contraction and expansion of the slab, it is fixed and mounted through the connecting reinforcement plate and bolts, so the repeated contraction of the slab and Not only does it easily fall off when it is inflated, but there is a gap between the connecting reinforcing plates even if it is not dropped, so that rainwater, etc., penetrates into the piers or shifts, so that the waterproof performance is low.

In addition, the conventional expansion joint as described above is when the slab shrinks in winter due to the melted upper elastic material and the lower elastic material is easily broken or melted and flows down to the bottom when the temperature is increased to about 100 ℃ in the summer There is a problem that is easily broken.

In addition, the conventional expansion joint as described above, when a plurality of expansion joints are installed on the bridge due to the characteristics of the expansion joint manufactured to a certain length, the airtightness between the expansion joint and the adjacent expansion joints of the slab There is a problem in that it is degraded by repeated contraction and expansion does not completely perform the waterproof function.

In addition, the conventional expansion joint device as described above is formed in the upper portion, that is, foreign matter penetrates into the opening formed between the connecting reinforcement plate, the foreign matter is not easily removed even if the slab expands in the summer, the upper elastic member of the There is a problem that causes breakage.

Republic of Korea Patent No. 1596689 Republic of Korea Registered Patent No.

The present invention has been made to solve the problems according to the prior art described above, the pair of connections in a state in which the distance between the pair of connecting reinforcing plate in the state that the opposite slab of the bridge is in the maximum contraction state to the maximum By filling and installing the sealant between the reinforcing plates and compressing them, the sealant not only increases the waterproofing performance against penetration, such as rainwater, but also fluidly responds to the contraction and expansion of the opposing slabs. It is a main object of the present invention to provide a expansion joint device using a compression-fixed high-elastic material that can easily prevent sag or shear due to shrinkage and expansion.

In addition, the present invention by installing a pair of first and second support frames and a plurality of adjusting bolts in the inner side before filling the sealant between the pair of connecting reinforcing plate, by filling the sealant, By adjusting the sealant to be in close contact with the inner side of the connecting reinforcing plate by rotating, it is possible to prevent the sealant from falling off from the connecting reinforcing plate during shrinkage and shrinkage of the facing slab, in particular, shrinkage, and as a result excellent The purpose of the present invention is not only to maximize the waterproof performance against the penetration force of the sealant but also to allow the sealant to be more flexibly responded to the contraction and expansion of the opposing slabs.

In addition, the present invention is installed in each of the pair of connecting reinforcing plate to protrude in the horizontal direction, each end is installed so as to overlap, the first and second support plate or the seal of the sealant is installed to be located below the sealant It is formed to be impregnated in the lower portion, by using the first, second non-woven fabric formed so that the ends overlap to prevent sagging of the sealant even at a high temperature in the summer, it is intended to minimize the deformation and breakage of the sealant.

In addition, the present invention forms the first and second bending grooves in a plurality of studs protruding on the outer surface of each of the pair of connecting reinforcing plate by combining with the first reinforcing bar of the bridge joint is installed expansion expansion device In order to improve the construction quality by increasing the coupling force of the expansion joint to be constructed, by allowing the reinforcing bars to be installed in the bending grooves.

The present invention provides a pair of connecting reinforcement plate and a plurality of studs protruding from the outer surface of each of the pair of connecting reinforcing plate is installed in the joint of the bridge to achieve the desired object as described above Compression fixed type high-elastic material, characterized in that it is installed between the connecting reinforcement plate, including a sealant which is compressed after being installed in the state of maximizing the separation distance of the pair of connecting reinforcement plate The expansion joint used is presented.

In addition, the connecting reinforcing plate of the present invention is installed by the plurality of bolt holes are formed in the side and the plurality of adjustment bolts coupled to the bolt holes and the inner side so that the head is located inside the first adjustment bolt to be located inside It characterized in that it comprises a support frame and a plurality of adjustment nuts coupled to the adjustment bolt to be located on the outside.

In addition, the connecting reinforcing plate of the present invention is positioned inside the first limit spring is installed on the adjusting bolt to be located between the inner surface and the first support frame, spaced apart from the inside of the first support frame It characterized in that it comprises a second support frame is installed by the adjusting bolt and the second limit spring is installed on the adjusting bolt to be located between the first support frame and the second support frame.

In addition, the present invention is one side of the pair of the reinforcing plate of any one of the pair of reinforcing plate is installed on the inner side of the protruding in the horizontal direction, protruding to be located below the sealant and the pair of The other side of the connecting reinforcing plate is installed on the inner side of the other one of the connecting reinforcing plate is protruded in the horizontal direction, characterized in that it comprises a second support plate protruding so that one side is located on the other side lower portion of the first support plate do or,

The sealant is formed below the nonwoven fabric layer and the nonwoven fabric layer formed below the upper layer and the upper layer, and comprises a lower layer of the same material as the upper layer, wherein the nonwoven fabric layer is formed below the upper layer of the singer, A first nonwoven fabric formed from one side of the upper layer in the other direction and a second nonwoven fabric formed in the lower portion of the upper layer, the second nonwoven fabric formed in one side from the other side of the upper layer so that one side is positioned under the other side of the first nonwoven fabric It is characterized by.

In addition, the sealant of the present invention is 55 to 70% by weight of straight asphalt; and 15 to 20% by weight of SBS rubber; and 5 to 10% by weight of polymer synthetic resin; And 10 to 15% by weight of oil; characterized in that comprises a.

The expansion joint using the compression-fixed high-elastic material according to the present invention as described above is installed between the high elastic rubber sealant between a pair of reinforcing plate, in the state of maximizing the separation distance of the pair of reinforcing plate By filling after installation, it can not only increase the waterproofing performance against the penetration of rainwater, etc., but also flexibly respond to shrinkage and expansion of the slabs facing each other and can easily prevent sag or shear of the slabs. You can get the effect.

In addition, the present invention after installing the first and second support frames in the inner side of the connecting reinforcement plate by a plurality of adjusting bolts, the sealant is installed between a pair of connecting reinforcing plate, and the adjustment bolt is rotated to By adjusting the sealant to be in close contact with the inner side of the connecting reinforcing plate, the contraction and expansion of the facing slab of the bridge, in particular, prevents the sealant from falling off from the connecting reinforcing plate during contraction, thereby providing a waterproofing performance against the penetration of rain, etc. In addition to the maximum maximization as well as more smoothly corresponding to the shrinkage and expansion of the opposite slab can be obtained an effect that can more easily prevent the sag or shear of the slab.

In addition, the present invention using the first, the support plate provided between the pair of reinforcing reinforcing plate, or using the non-woven fabric layer impregnated with the first and second non-woven fabric in the lower portion of the sealant deflection of the sealant when the outside temperature is high in the summer By preventing, it is possible to obtain the effect that can minimize the deformation and breakage of the sealant.

In addition, the present invention forms the first and second bent grooves in a plurality of studs protruding from the outer surface of each of the pair of connecting reinforcing plate, between the first and second bent grooves and the main reinforcing bar provided in the joint portion of the bridge By installing additional reinforcing bars in the construction, it is possible to increase the bonding strength of the expansion joint to be constructed, thereby obtaining the effect of improving the construction quality.

1 is a front sectional view showing a state in which the expansion joint according to a preferred embodiment of the present invention is installed in the joint portion of the bridge.
Figure 2 is a perspective view of the expansion joint according to a preferred embodiment of the present invention.
Figure 3 is an exploded perspective view showing a connecting reinforcing plate according to a preferred embodiment of the present invention.
Figure 4 is an exploded perspective view showing a connecting reinforcing plate according to another embodiment of the present invention.
Figure 5 is a front sectional view showing the inside of the expansion joint according to a preferred embodiment (a) and another embodiment (b) of the present invention.
Figure 6 is a front sectional view showing a state in which the first and second support plates are installed in the expansion joint according to a preferred embodiment of the present invention.
7 is a front sectional view showing a state in which a nonwoven fabric layer is formed on a sealant according to a preferred embodiment of the present invention.
8 is a bottom view showing a state in which a nonwoven fabric layer is formed on a sealant according to a preferred embodiment of the present invention.
Figure 9 is a front sectional view showing the manufacture of the expansion joint according to a preferred embodiment of the present invention.
10 is a front sectional view showing the manufacturing of the expansion joint according to another embodiment of the present invention.

The present invention relates to an expansion joint device using a high elastic material, in more detail, a pair of connecting stiffener plate 100 is provided between the joint of the bridge, that is, the slab (1) of the opposite bridge After installing the first and second support frames 130 and 160 on the inner side of the connecting reinforcement plate 100 using the adjusting bolt 120 and the adjusting nut 140, a highly elastic rubber sealant (hereinafter 'sealant 300') And then compress it, install it, and compress it. By tightening the adjusting nut 140, the first and second support frames 130 and 160 are moved outwardly by the adjusting boat 120. Is moved in the direction so that the sealant 300 is firmly in close contact with the inner surface of the connecting reinforcing plate 100 can be stably flow and correspond to the contraction and expansion of the opposing slab 1 as well as excellent It is possible to increase the waterproof performance against the penetration force, and consequently, the opposite slab The present invention relates to an expansion joint apparatus using a compression-fixed high-elastic material that can prevent the slab 1 from sagging or shearing due to shrinkage and expansion of the slab 1.

A configuration for achieving the present invention as described above is a pair of connecting reinforcement plate 100 is installed on the joint portion of the bridge; and a plurality of studs protruding on the outer surface of each of the pair of connection reinforcing plate 100 200; And a sealant 300 installed between the pair of connecting reinforcing plates 100 and being compressed after being installed in a state in which the separation distance of the pair of connecting reinforcing plates 100 is maximized. It characterized by comprising;

In addition, the connecting reinforcing plate 100 of the present invention is a plurality of bolt holes 110 formed through the side; and a plurality of adjustment bolts coupled to the bolt hole 110 so that the head 122 is located inside ( 120); and the first support frame 130 is installed by the adjustment bolt 120 to be located inside; And a plurality of adjustment nuts 140 coupled to the adjustment bolts 120 so as to be positioned outside.

In addition, the connecting reinforcing plate 100 of the present invention; the first limit spring 150 is installed on the adjusting bolt 120 to be located between the inner surface and the first support frame 130; A second support frame 160 installed by the adjusting bolt 120 to be spaced apart from the inside of the first support frame 130; And a second limit spring 170 installed on the adjustment bolt 120 to be positioned between the first support frame 130 and the second support frame 160.

In addition, the present invention is one side is installed on the inner surface of any one of the connection reinforcing plate 100 of the pair of connection reinforcing plate 100 is protruded in the horizontal direction, protruding to be located below the sealant (300) The other side is installed on the inner side of the other one of the connecting reinforcing plate 100 and the pair of connecting reinforcing plate 100 is protruded in the horizontal direction, the first support plate 400 It characterized in that it comprises a; or the second support plate 500 protruding so that one side is located in the lower side of the other side)

The sealant 300 includes an upper layer 310 and a nonwoven layer 320 formed below the upper layer 310; And a lower layer 330 formed of the same material as that of the upper layer 310, wherein the nonwoven layer 320 is formed below the upper layer 310 of the singer. A first nonwoven fabric 322 formed from one side of the upper layer 310 in the other direction; and a first nonwoven fabric 322 formed in the lower portion of the upper layer 310 and formed in one direction from the other side of the upper layer 310. And a second nonwoven fabric 324 having one side positioned at the lower side of the other side of 322.

In addition, the sealant 300 of the present invention is 55 to 70% by weight of straight asphalt; and 15 to 20% by weight of SBS rubber; and 5 to 10% by weight of polymer synthetic resin; And 10 to 15% by weight of oil; characterized in that comprises a.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 10 illustrating embodiments of the present invention.

First, the expansion joint device of the present invention may be installed after the bridge is initially installed, or may be installed after removing the conventional expansion joint device installed in the joint portion of the existing bridge.

In addition, the expansion joint device of the present invention is installed in the joint portion of the bridge and the slab 1 adjacent to the slab 1 which is actually spaced apart from the joint portion of the bridge (hereinafter referred to as "slapping slab 1"). When the sealant 300 is flowed together according to the contraction and expansion of), and the sealant 300, which will be described in detail later, is installed between the pair of connecting reinforcing plates 100, the opposing slabs 1 are contracted to the maximum in winter. That is, the pair of reinforcing reinforcing plate 100 is installed in a state in which the pair of connecting reinforcement plates 100 are spaced apart by the maximum distance that the opposed slabs 1 are spaced apart by the maximum distance. It features.

That is, when the expansion joint device of the present invention is installed in the joint portion of the bridge, the sealant 300 is installed to maintain the compressed state in consideration of the external temperature, whereby the opposed slab 1 is maximized. Even when contracted with, it stably flows to prevent sagging and shearing of the slab 1.

Connection reinforcing plate 100 is the main component to achieve the present invention is

It is installed at the joint of the bridge, it is composed of a pair, and is installed between the joint of the bridge, that is, the step (not shown) of the opposing slab 1, and the sealant 300 to be described later is installed between In addition, the slab 1 is moved in the direction in which the slab 1 contracts and expands together with the slab 1 so that the sealant 300 can stably flow as the opposed slab 1 contracts and expands.

Specifically, the connecting reinforcing plate 100 of the present invention is moved in accordance with the contraction and expansion of the opposite slab (1) the upper part having a shape (for example, sawtooth) corresponding to each other so as to overlap because they are adjacent or spaced apart It characterized in that it comprises a plate (not shown), and the side plate formed in the lower direction of the upper plate. At this time, the top plate may be formed in any shape conventionally used, so a detailed description thereof will be omitted.

That is, the connection reinforcing plate 100 of the present invention is formed in the plurality of studs 200 to be described later in the outer direction of the side plate protruding, the sealant 300 to be described in detail later on the inside of the side plate is filled Is installed.

In addition, the connecting reinforcing plate 100 of the present invention is to be removed from the inner surface of the connecting reinforcing plate 100 when the sealant 300, which will be described in detail later, the contraction and expansion of the opposed slab 1, in particular, when contracted It is configured to include a plurality of bolt holes 110, a plurality of adjustment bolts 120, the first support frame 130, a plurality of adjustment nuts 140 to prevent that.

In more detail, the connection reinforcing plate 100 of the present invention is a plurality of bolt holes 110 formed through the side and a plurality of coupled to the bolt hole 110 so that the head 122 is located inside Adjusting bolt 120, the first support frame 130 is installed by the control bolt 120 to be located inside and a plurality of adjustment nuts 140 coupled to the control bolt 120 to be located outside Characterized in that it comprises a.

The bolt hole 110 is formed to penetrate the side of the connection reinforcing plate 100, that is, the side plate, a plurality of penetrating formed in the longitudinal direction, the distance and size of each formed adjustment bolt according to the judgment of those skilled in the art Considering the load of the 120 and the first support frame 130, etc. will be apparent, it will be apparent that the stud 200, which will be described later, is formed at a position where the protrusion is not formed.

The adjustment bolt 120 is the bolt hole 122 in the inner side of the side plate of the connecting reinforcing plate 100 so that the bolt head 122, that is, the head 122 is located in the inner side of the connecting reinforcing plate 100 As it is coupled to the 110, it is coupled to the plurality of bolt holes 110 is provided with a plurality, the adjustment nut 140 described above is coupled to the outside of the connection reinforcing plate 100, the operator is the adjustment nut By rotating the 140, the head 122 is rotated and moved outwardly of the connecting reinforcing plate 100.

The first support frame 130 is installed by the adjusting bolt 120 to be located inside the connection reinforcing plate 100, the length is formed in the longitudinal direction of the connection reinforcing plate 100, A plurality of coupling holes (not shown) through which the adjustment bolt 120 can pass through are formed to correspond to the bolt holes 110, and the head 122 of the adjustment bolt 120 is connected to the reinforcing plate 100. While moving together as it is moved to the outside of the sealant, which will be described in detail later, is located inside the sealant 300 to compress one side or the other side of the sealant 300 to the outside of the connecting reinforcing plate 100 to the sealant ( One side or the other side of the 300 is to be in close contact with the inner surface of the connection reinforcing plate 100, that is, the inner surface of the side plate to prevent the sealant 300 from falling off from the connection reinforcing plate 100. Make it happen.

In addition, the coupling hole is preferably formed in the form of a long hole, as shown in Figure 3 or 4, which is coupled by the control bolt 120 if not formed exactly in the position corresponding to the bolt hole 110 When twisting or shearing may occur during the formation of a long hole, the first support frame 130 may be smoothly installed by the adjusting bolt 120.

In addition, the coupling hole is formed in the form of a long hole to realize the effect of smoothing the movement of the adjustment bolt 120, which is difficult for the operator to move the plurality of adjustment bolts 120 at the same time one or a constant Since the number of adjustment bolts 120 are moved, when one or a certain number of adjustment bolts 120 are moved, the first support frame 130 is kept inclined with respect to the longitudinal direction to maintain a plurality of adjustments. The bolt 120 allows the first support frame 130 to be stably moved.

In other words, as the coupling hole is formed in the form of a long hole, when the operator moves one or a predetermined number of adjustment bolts 120, the first support frame 130 is moved forward or rearward in the longitudinal direction first. Since the adjusting bolt 120 is inclined to form a long hole, the adjusting bolt 120 is moved inward of the coupling hole, and thus the first support frame 130 is inclined. Since the plurality of adjustment bolts 120 are moved in any order or in any order, it is possible to obtain an effect of stably moving by the plurality of adjustment bolts 120 without being twisted or sheared, and consequently, the first support frame. By 130, it is possible to stably compress one side or the other side of the sealant 300 to the inner surface of the connection reinforcing plate 100, that is, the inner surface of the side plate.

The adjustment nut 140 is positioned outside the connection reinforcement plate 100, that is, coupled to the adjustment bolt 120 coupled to the bolt hole 110 in the side plate outer direction of the connection reinforcement plate 100. As, by being rotated by the operator by rotating the adjusting bolt 120, the head 122 of the adjusting bolt 120 is moved in the outward direction of the connecting reinforcing plate 100, and consequently the first support frame The effect of allowing 130 to be moved outward is realized.

In connection with the above, the connection reinforcing plate 100 of the present invention includes a first limit spring 150 is installed on the adjusting bolt 120 to be located between the inner surface and the first support frame 130. Characterized in that it is configured, the first limit spring 150 is such that the first support frame 130 is in close contact with the head 122 of the adjustment bolt 120 stably the first support frame 130 The control bolts 120 are not only moved in the outward direction of the connecting reinforcement plate 100 but also compressed as the control bolts 120 are moved outwards so that the control bolts 120 are outward. By limiting the distance to be moved, as a result it is characterized in that the first support frame 130 to limit the distance moved in the outward direction.

That is, the first limit spring 150 is a distance that the first adjustment bolt 120 and the first support frame 130 is moved to the outside of the connecting reinforcing plate 100 by the adjustment nut 140 By limiting the limiting distance of one side or the other side of the sealant 300 to be described later in accordance with the movement of the first support frame 130, the sealant 300 is the first support frame 130 In addition to preventing the damage by the) and the first support frame 130 to achieve the effect that the sealant 300 is in close contact with the inner surface of the connecting reinforcing plate 100.

In addition, the connection reinforcing plate 100 of the present invention is located on the inside, the second support frame 160 is installed by the adjustment bolt 120 to be spaced apart inside the first support frame 130 and And a second limit spring 170 installed on the adjustment bolt 120 to be positioned between the first support frame 130 and the second support frame 160.

The second support frame 160 is formed in the longitudinal direction of the connecting reinforcing plate 100, as in the first support frame 130 described above, so that the adjustment bolt 120 can be flexibly coupled A plurality of coupling holes (not shown) formed in a long hole shape are formed, and one side or the other side of the sealant 300 to be described later together with the first support frame 130 is stable on the inner surface of the connection reinforcing plate 100. By making it firmly and tightly contacted, it is possible to realize the effect of maximizing the waterproof performance by rain.

Like the first limit spring 150 described above, the second limit spring 170 elastically supports the second support frame 160 in the direction of the head 122 of the adjustment bolt 120 to the second limit spring. The support frame 160 can be stably installed in one side or the other side of the sealant 300 to be described later, while the second support frame 160 is connected to the reinforcing plate 120 by the adjustment bolt 120 ( By limiting the distance moved in the outward direction of 100, it is possible to realize the effect that one side or the inside of the sealant 300 can be prevented from being damaged by the second support frame 160.

That is, the first support frame 130 and the second support frame 160 is moved in the outward direction of the connecting reinforcement plate 100 by using the adjusting bolt 120 and the adjusting nut 140, which will be described later. When one side or the other side of the sealant 300 is firmly in close contact with the inner surface of the connecting reinforcing plate 100 to realize the effect of maximizing the waterproof performance as well as during contraction and expansion of the opposite slab (1) In particular, by preventing the phenomenon that one side or the other side of the sealant 300 is dropped from the inner surface of the connecting reinforcing plate 100 during the contraction, and the sealant 300 to flow smoothly, This makes it possible to easily prevent sag or shear.

On the other hand, the connecting reinforcing plate 100 of the present invention further comprises a connecting flange 102 protruding laterally at the end of the longitudinal direction, that is, the front and rear end, and the base fabrication according to the width direction length of the bridge And it is characterized in that it can be connected to the expansion joint device of the present invention to be installed smoothly.

At this time, the expansion joint device of the present invention is connected to the connection flange 102 through a fastening configuration such as a bolt to extend the length, the connection portion, that is, in the same material as the sealant 300 to be described in detail later It may be configured to further comprise a self-adhesive molding tape (not shown, referred to as "connection tape"), the connection tape is more stable over time due to the material properties of the sealant 300 By integrating with the sealant 300, the effect of having an excellent waterproof performance is realized.

Stud 200 is the main component for achieving the present invention is

Protrudingly formed on the outer surface of each of the pair of reinforcing plate 100, is provided with a plurality, and filled with non-concrete concrete (not shown) together with the reinforcing rods (3), particularly the reinforcing bars (3) installed on the slab (1) of the bridge When the slab 1 shrinks and expands along its longitudinal direction due to external environmental conditions, that is, temperature change, dry shrinkage, creep, etc., the connecting reinforcement plate 100 is connected to the cast iron 3 of the slab 1. ) To bind together and to move together.

Specifically, the stud 200 of the present invention is the first inclined portion 210 inclined in the lower direction on the upper surface and the second inclined portion 220 inclined in the upper direction from the end of the first inclined portion 210. The first bent groove 230 formed by the upper and third inclined portion 240 inclined downward from the end of the second inclined portion 220 and the upper direction from the end of the third inclined portion 240 It characterized in that it comprises a second bending groove 260 formed by the fourth inclined portion 250 inclined to.

In addition, the stud 200 of the present invention further comprises a reinforcing bar 270 that is seated in at least one of the first bent groove 230 or the second bent groove 260, the reinforcement ( 270 to realize the effect that can be more firmly combined with the cast iron (3) of the slab (1), the connection reinforcing plate 100 smoothly together in accordance with the contraction and expansion of the facing slab (1) To realize the effect of being moved.

In this case, the reinforcing bar 270 is formed in the longitudinal direction of the connecting reinforcing plate 100 is seated in any one or more of the first bending groove 230 or the second bending groove 260 of the plurality of studs 200. This realizes the above effects.

Sealant 300 is the main component to achieve the present invention

It is installed between the pair of connecting reinforcing plate 100, and is compressed after being installed in a state in which the separation distance of the pair of connecting reinforcing plate 100 to the maximum (high elastic rubber) It is made of a material and flows flexibly according to the contraction and expansion of the opposing slab 1, thereby realizing the effect of preventing the slab 1 from sagging or shearing when contracting and expanding the opposing slab 1. do.

That is, in the sealant 300 of the present invention, the distance between the pair of connecting reinforcement plates 100 is maximized, that is, in a state in which the slab 1 facing the winter is contracted and the distance spaced apart is the maximum. After being installed between the pair of connecting reinforcing plate 100 and actually installed in the joint of the bridge, by adjusting the separation distance of the pair of connecting reinforcing plate 100 to be compressed and installed, the opposite By allowing the fluid to flow flexibly according to the contraction and expansion of the slab 1, the slab 1 is prevented from sagging and shearing.

At this time, the sealant 300 of the present invention, as described above, one side and the other side is firmly in close contact with the inner surface of the connecting reinforcement plate 100 by the first and second support frames 130, 160, Not only to increase the waterproof performance of the expansion joint device of the invention, but also to prevent falling from the connecting reinforcing plate 100 during contraction and expansion of the facing slab (1), especially during contraction to prevent breakage due to dropout To realize the effect of improving the construction quality.

In addition, the sealant 300 of the present invention is the same as the sealant conventionally used, but when the temperature rises in the summer, the physical properties become flexible and sagging occurs, the expansion joint device of the present invention to prevent such a first, second The support plates 400 and 500 may be formed on the connection reinforcing plate 100 or may be prevented by forming the nonwoven fabric layer 320 inside the sealant 300.

In more detail, the expansion joint device of the present invention is installed on one side of the inner side of any one of the pair of connecting reinforcing plate 100 of the connecting reinforcing plate 100 is protruded in the horizontal direction, the sealant ( The other side is installed on the inner side of the first support plate 400 protruding to be positioned below the 300 and the other one of the connection reinforcing plate 100 of the pair of reinforcing plate 100 protrudes in a horizontal direction The second support plate 500 is protruded so that one side is positioned below the other side of the first support plate 400.

The first support plate 400 and the second support plate 500 are coupled to one side or the other side to the inner surface of the pair of reinforcing reinforcement plate 100 to protrude in the horizontal direction, so that the other side and one side overlap, Preventing the deflection of the sealant 300, thereby minimizing the deformation of the sealant 300 in the summer to realize the effect to be able to exhibit a stable performance even in the winter. At this time, the material of the first and second support plates 400 and 500 is made of a metal material, such as the connection reinforcing plate 100 and the stud 200.

In addition, the first and second support plates 400 and 500 may prevent sagging of the sealant 300 as described above, and at the same time, the rain may be leaked between the sealant 300 and the connecting reinforcement plate 100. As described above, the sealant 300 is minimized from falling off from the connecting reinforcing plate 100, but the gap generated by the impact of the rainy season or earthquake, etc., which is constantly raining. In case of leakage, the above effect can be realized.

In addition, the first and second support plates 400 and 500 may be formed so that their ends are inclined upward in order to maximize the effect of drainage, which prevents the sagging of the sealant 300 even more efficiently. At the same time, the rainwater is prevented from leaking between the first and second support plates 400 and 500.

Meanwhile, the first and second support plates 400 and 500 are not formed on the connection reinforcing plate 100 to replace the sagging of the sealant 300 by the first and second support plates 400 and 500. In addition, the nonwoven fabric layer 320 may be formed in the sealant 300.

In more detail, the sealant 300 of the present invention is formed on the upper layer 310 of the high elastic rubber material and the lower layer of the nonwoven fabric layer 320 and the lower layer of the nonwoven fabric layer 320. The lower layer 330 may be formed of the same material as the upper layer 310.

The nonwoven fabric layer 320 is made of a synthetic fiber material, and is formed in a manner impregnated inside the lower portion of the sealant 300, thereby realizing the effect of preventing sagging of the sealant 300, and made of synthetic fiber material In order to be included in the highly elastic rubber sealant 300, that is, the upper layer 310 and the lower layer 330 to form a smooth layer, the adhesive layer (between the upper layer 310 and the lower layer 330) It is preferable to further form).

In addition, in the sealant 300 of the present invention, the adhesion is further formed between the upper layer 310 and the nonwoven fabric layer 320 and between the nonwoven fabric layer 320 and the lower layer 320. It is possible to obtain an effect that the layer 320 is smoothly formed inside.

In this case, the nonwoven fabric layer 320 is formed under the upper layer 310, the first nonwoven fabric 322 formed in one direction from the other side of the upper layer 310 and the lower layer 310 is formed below The second nonwoven fabric 324 is formed in the one direction from the other side of the upper layer 310, and the second nonwoven fabric 324 is located at the lower side of the other side of the first nonwoven fabric 322.

That is, the nonwoven fabric layer 320 is formed of a nonwoven fabric made of one synthetic fiber and is formed to overlap a portion of the first nonwoven fabric 322 and the second nonwoven fabric 324 instead of preventing sagging of the sealant 300. It is possible to realize the effect of effectively preventing the deflection of the sealant 300.

In addition, when the nonwoven fabric layer 320 is formed of one nonwoven fabric, when one of the sealants 300 deflects, one of the nonwoven fabrics is broken so that the deflection of the sealant 300 may not be prevented efficiently. Although, the first and second nonwoven fabrics 322 and 324 are formed to overlap, the sag of the sealant 300 can be effectively prevented without being broken. At this time, it is preferable that the adhesive layer is formed between the first and second nonwoven fabrics 322 and 324 so that the rigid nonwoven fabric layer 320 is formed.

In addition, the first and second nonwoven fabrics 322 and 324 are not formed from both ends of the upper layer 310, but are formed from a predetermined distance from both ends, which is described above. This is because both sides of the sealant 300 are firmly supported by 130 and 160.

In addition, as shown in FIG. 8, the nonwoven fabric layer 320 may be formed in plural instead of being formed in the entire inner lower portion of the sealant 300, which may include the sealant 300 in the nonwoven fabric layer 320. This is to prevent the upper layer 310 and the lower layer 320 of the slide from being sheared and separated or broken.

In connection with the above, the sealant 300 of the present invention is made of a high elastic rubber material, in more detail, 55 to 70% by weight of straight asphalt and 15 to 20% by weight of styrene-butadiene-styrene copolymer (SBS) rubber And, it is characterized by comprising 5 to 10% by weight of polymer synthetic resin and 10 to 15% by weight of oil.

The straight asphalt (Straight Asphalt) contains a lot of bitumen that does not decompose to the last remaining material when the crude oil is removed through the atmospheric pressure, reduced pressure distillation apparatus, etc., Penetration is less than about 40㎜ Is mainly used for industrial purposes, and the penetration of about 40mm or more is used for road paving or repair structures. Its disadvantage is that it has high elongation, excellent adhesion and waterproofness, low elasticity, low softening point (軟化 點), which is sensitive to temperature change and poor weather resistance.

In the present invention, the straight asphalt is the main component of the sealant 300, and its kind is AP-3 or AP-5. At this time, the content of the straight asphalt is preferably 55 to 70% by weight, if the content is less than 55% by weight, the melting point is increased, the fluidity is reduced, there is a problem that the plasticity is poor, if the content exceeds 70% by weight the adhesive strength is reduced And there is a problem that the hardness is excessively raised, it is preferable to be included in the content as described above. In addition, the straight asphalt is preferably about 80 to 100mm penetration.

The SBS rubber is a modifier added to modify the straight asphalt. In addition, when synthetic resins such as coumarone indene resin, PP, and PE, which are conventionally used, are used, the melting point of the sealant 300 may be increased, and when the melting point is high, the sealant of the present invention ( Deflection phenomenon of the 300 may be prevented, but it may be difficult to form due to the filling of the sealant 300, so it is preferable not to use the synthetic resin as described above.

At this time, the content of the SBS rubber is preferably 15 to 20% by weight, if the content is less than 15% by weight, there is a problem that the modification of the straight asphalt is not sufficient, and when the content exceeds 20% by weight, the melting point of the sealant 300 There is a problem that it may be difficult to form the sealant 300 to rise too much, it is preferably included in the content as described above.

In addition, the SBS rubber is largely divided into a linear type and a radial type. In this case, the radial type styrene-butadiene-styrene polymer (SBS) has a high molecular weight and thus a sealant ( It is preferable to use a linear type of styrene-butadiene-styrene polymer (SBS) having a relatively low molecular weight because the viscosity of 300) is excessively increased so that it is not suitable for the charge formation due to low temperature melting.

The polymer synthetic resin is to improve the adhesive strength, chemical resistance, ozone resistance, UV resistance or elasticity of the sealant 300, any conventional polymer synthetic resin having a purpose in this field may be used, for example Polyethylene oxydo, polyvinylpyrrolidone, cellulose resin, polyvinyl alcohol, polyvinylacetate, epoxy resin, silicone resin, urethane resin, acrylic resin or a mixture thereof may be used.

In addition, the polymer synthetic resin of the present invention may also use synthetic rubber, for example, may be chloroprene rubber, specifically water-based chloroprene rubber, butyl rubber, styrenebutadiene rubber, butadiene rubber or a mixture thereof, but has a high resilience, It is preferable to use chloroprene rubber which is excellent in chemical resistance, ozone resistance and ultraviolet resistance.

At this time, the content of the polymer synthetic resin is preferably 5 to 10% by weight, if the content is less than 5% by weight of the sealant 300, the improvement of the adhesion, chemical resistance, ozone resistance, UV resistance or elasticity is insignificant, 10 If the content is more than the weight%, the content of the straight asphalt and SBS rubber is insignificant, and thus the content effect of the straight asphalt and SBS rubber is lowered.

The oil is intended to reduce the separation between each other by inducing the chemical bonding of the straight asphalt and polymer synthetic resin to improve the transmission deformation and crack resistance, and to extend the life of the sealant by improving the rheological properties such as viscoelastic properties, elastic recovery In addition, the effect of improving the stability is realized.

The oil may be a process oil, and the process oil may be classified into paraffin, naphthalene and aromatic, and may be used in any of them, and the content of the oil is preferably 10 to 15% by weight, the content of which is 10% by weight. If it is less than%, it is difficult to express such characteristics, and if it exceeds 15% by weight, the durability of the sealant 300 is lowered due to excessive use, so that the plastic deformation characteristics deteriorate.

On the other hand, the expansion joint device of the present invention is installed between the opposite slab (1), it may be configured to further include a sound absorbing material 600 is installed to be located below the sealant 300, the sound absorbing material 600 ) Prevents the rain, which may be leaked again, between the sealant 300 and the connecting reinforcing plate 100 to further increase the waterproof performance and at the same time to alleviate the impact applied to the opposing slabs 1. As a result, it is possible to reliably prevent problems such as water that flows to the alternating parts and cause a fatal effect on the bridge, thereby realizing the effect of maintaining the life of the bridge for a long time.

In connection with the above, FIGS. 9 and 10 illustrate the case where the nonwoven fabric layer 320 is formed on the sealant 300 and the first and second support plates 400 and 500 are formed when the expansion joint device of the present invention is manufactured. And a case where the sealant 300 is formed, respectively. In particular, the sealant 300 is compressed.

As a result, the expansion joint device of the present invention is installed by compressing the high elastic rubber sealant 300, but also to increase the waterproofing ability to penetrate such as excellent by increasing the bonding strength with the connection reinforcing plate 100, summer Deflection is prevented even at high temperatures, so that there is little deformation, thereby minimizing breakage. Accordingly, sag or shear due to shrinkage and expansion of the opposing slabs 1 can be easily prevented, thereby improving construction quality. .

The following test report is a test of the high elastic rubber sealant used in the present invention, that is, the elastic recovery rate, flow chart, softening point, and adhesiveness of the sealant 300 and the connection tape, and the expansion joint device after the high elastic rubber sealant of the present invention is bonded. It can be seen that the waterproof performance (non-water immersion) of the connection portion of the may be increased.

The above has been described with reference to a preferred embodiment of the present invention, but is not limited to the above embodiment, the person having ordinary skill in the art to which the present invention pertains through the above embodiments without departing from the gist of the present invention Can be implemented in a variety of changes.

1: slab 2: ascon 3: cast iron
100: connection reinforcement plate 110: bolt hole 120: adjustment bolt
122: head 130: first support frame 140: adjustment nut
150: first limit spring 160: second support frame 170: second limit spring
200: stud 210: first inclined portion 220: second inclined portion
230: first bent groove 240: third inclined portion 250: fourth inclined portion
260: second bending groove 270: reinforcing steel 300: sealant
310: upper layer 320: nonwoven fabric layer 322: first nonwoven fabric
324: second nonwoven fabric 330: lower layer 400: first support plate
500: second support plate 600: sound absorbing material

Claims (10)

A pair of connecting reinforcing plates 100 installed between the steps of the opposite slabs 1, which are joints of the bridge; and
A plurality of studs 200 protruding from the outer surface of each of the pair of connection reinforcing plates 100; and
A sealant 300 installed between the pair of reinforcing reinforcing plates 100, the sealant 300 being compressed after being installed in a state in which the separation distance of the pair of reinforcing reinforcing plates 100 is maximized; And
And a sound absorbing material 600 installed between the opposite slabs 1 and positioned to be positioned below the sealant 300.
The connecting reinforcement plate 100
A plurality of bolt holes 110 formed through the side; And
A plurality of adjusting bolts 120 coupled to the bolt holes 110 such that the head 122 is located inside; and
A first support frame 130 installed by the adjusting bolt 120 so as to be positioned inward, and having a plurality of coupling holes formed in a long hole shape through which the adjusting bolt 120 can pass;
A plurality of adjustment nuts 140 coupled to the adjustment bolts 120 to be positioned outside; and
A first limit spring 150 installed on the adjustment bolt 120 to be positioned between an inner surface and the first support frame 130; and
Is located in the inner side, is installed by the adjusting bolt 120 so as to be spaced apart in the inner side of the first support frame 130, a plurality of coupling holes made in the form of a long hole so that the control bolt 120 can be coupled The second support frame 160 is formed; And
And a second limit spring 170 installed on the adjustment bolt 120 to be positioned between the first support frame 130 and the second support frame 160.
The sealant 300 is
An upper layer 310; and
A plurality of nonwoven layers 320 formed under the upper layer 310; And
It is formed below the nonwoven fabric layer 320, the lower layer 330 of the same material as the upper layer 310;
The nonwoven layer 320 is
A first nonwoven fabric 322 formed at a lower portion of the upper layer 310 and formed in one direction from one side of the upper layer 310; and
A second non-woven fabric 324 formed under the upper layer 310 and formed in one direction from the other side of the upper layer 310 so that one side is positioned under the other side of the first nonwoven fabric 322. ,
An adhesive layer is formed between the upper layer 310 and the nonwoven fabric layer 320, between the nonwoven fabric layer 320 and the lower layer 330, and between the first and second nonwoven fabrics 322 and 324.
The sealant 300 is
With straight asphalt;
SBS rubber; and
Polymer synthetic resins; And
Expansion and expansion device using a compression-elastic high-elastic material, characterized in that comprising; oil.
delete delete delete delete The method of claim 1,
The expansion joint device
One side of the pair of connecting reinforcing plate 100 is installed on one inner side of the connecting reinforcing plate 100 is protruded in the horizontal direction, the first supporting plate protruding to be located below the sealant (300) 400); and
The other side of the pair of connection reinforcing plate 100 is installed on the inner side of the other one of the connection reinforcing plate 100 is protruded in the horizontal direction, so that one side is located on the other side lower portion of the first support plate 400 It is configured to include; protruding second support plate 500,
The first and second support plates 400 and 500 are
An expansion joint using a compression-fixed high-elastic material, characterized in that each end is inclined upward.
delete delete delete The method of claim 1,
The sealant 300 is
Straight asphalt 55-70% by weight; and
SBS rubber 15-20% by weight; and
5 to 10% by weight of a polymer synthetic resin made of chloroprene rubber; And
10 to 15% by weight of oil; expansion joint device using a compression-elastic high-elastic material, characterized in that comprising a.

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