KR20190129694A - Bridge bearing having system for checking mortal filling state - Google Patents

Abstract

The present invention relates to a smart bridge stand having a system for checking the filling of non-shrinkage mortar. The smart bridge stand comprises: an upper plate coupled to a lower portion of an upper structure; a lower plate coupled to a pier (or abutment) to face the upper plate, and having a guide groove which has an inverted U-shaped cross-sectional shape and has the predetermined length from the edge of the bottom surface thereof to a center portion of the bottom surface, and a reflective mirror which is provided on the other end of the guide groove positioned on the center portion of the bottom surface; an elastic support member interposed between the upper plate and lower plate; a non-shrinkage mortar fed and poured between the bottom surface of the lower plate and an object to be installed; and a sensor unit detachably provided on a side of the lower plate. According to the present invention, the bridge stand can allow the sensor unit to emit light at the non-shrinkage mortar and detect light reflected therefrom, thereby checking whether or not pores are present in the center portion of the lower plate.

Description

Smart bridge support with non-shrink mortar {Bridge bearing having system for checking mortal filling state}

The present invention relates to a smart bridge support having a filling confirmation system of the non-shrink mortar, specifically, the non-shrinkage that can confirm the filling state of the non-shrink mortar interposed between the lower plate of the bridge and the bridge of the lower structure of the bridge A smart bridge bearing with a mortar charging confirmation system.

In general, the bridge support is installed at the contact point of the bridge's upper structure and the bridge (or alternating load) supporting the load, and transmits the upper load acting on the upper structure to the lower structure's bridge, Displacement caused by vibrations such as earthquakes can be accommodated to prevent breakage and collapse of the bridge.

As is well known to those skilled in the art, a bridge bearing includes an upper plate fixed to a lower surface of an upper structure of a bridge corresponding to a support object, a lower plate fixed to a pier corresponding to an installation object, and between an upper plate and a lower plate. It is made of an elastic support member having an appropriate elasticity interposed in. The lower plate may be integrally connected to the length of the anchor socket lengthwise downward from the bottom of the lower plate by a stud bolt or anchor bolt. Optionally, the bridge bearing may bind the anchor socket of the lower plate to an anchor bolt provided in the pier to fix the lower plate on the pier. The anchor socket is buried by pouring non-shrink mortar on the bridge, it can be expected to improve the bridge safety through the coupling force between the bridge bearing and non-shrink mortar after construction.

As described above, the bridge bearing must completely fill the piercing and lower plate with non-contraction mortar when pouring non-shrink mortar to the side of the lower plate between the pier (or alternation) and the lower plate. When axial mortar is poured, an air gap occurs in the lower part of the bridge support, and this air gap specifically remains in the space where the non-condensed mortar is embedded (i.e., between the upper surface of the piers and the lower surface of the lower plate). This occurs because the air layer that is present cannot be discharged to the outside.

The voids cause problems such as deformation of the lower plate (sag phenomenon) and / or cracking of non-contraction mortar. These voids are not easily identified after non-shrink mortar casting, making repairs difficult.

The present invention has been made to solve the above-described problems, and it is possible to ensure the complete discharge of the non-condensation mortar by pouring air reliably during pouring the non-condensation mortar between the bottom plate and the piers as well as during Another object of the present invention is to provide a bridge support capable of confirming full filling of non-contraction mortar.

In order to achieve the above object, the present invention relates to a smart bridge bearing with a filling confirmation system of non-shrink mortar, the upper plate coupled to the lower portion of the support object; A guide groove coupled to the installation object to face the top plate, the guide groove having a predetermined length from the bottom edge to the center of the bottom surface and formed concave in the thickness direction from the bottom surface to the top surface, and the guide positioned at the center of the bottom surface. A lower plate on which the reflecting mirror is disposed at the other end of the groove; An elastic support member interposed between the upper plate and the lower plate; Non-shrink mortar which is supplied and poured between the lower surface of the lower plate and the installation object, and is poured at the same height as the lower surface of the lower plate; And a sensor unit detachably disposed at a side of a lower plate including an end of an induction groove positioned at an edge of a lower surface of the lower plate, wherein the smart bridge support is installed at a contact point of a support object and an installation object. By using an induction groove as a means, an optical path can be secured to detect light returned from the sensor unit toward the non-shrink mortar, thereby inspecting the presence or absence of voids between the lower plate and the non-shrink mortar.

The lower plate may be made of a metal material.

Selectively, the sensor unit and the light emitting unit for irradiating light to the non-condensation mortar; A light receiving unit for receiving light reflected from the non-shrink mortar; A control unit for calculating the distance from the sensor unit to the non-condensation mortar with light received by the light-receiving unit reflected by the non-contraction mortar; And a magnetic to help the light emitting unit and the light receiving unit to be positioned at one end of the guide groove.

The lower plate has an induction groove formed in an inverted U-shaped cross-sectional shape, and the induction groove may be disposed at the same height as the lower plate with a shield having a flat surface having a predetermined length to close the lower opening of the induction groove.

The length of the flat surface is formed shorter than the length of the guide groove, the present invention can form an opening between the flat surface and the other end of the guide groove.

The opening may be arranged on the same line in a direction perpendicular to the reflection mirror.

The shield may be formed in a U-shaped cross-section with a pair of sides vertically upright at both edges of the flat surface.

Alternatively, the shielding portion may be formed in a hollow rectangular cross-section having a pair of side surfaces vertically placed at both edges of the flat surface and an upper surface arranged between the pair of side surfaces parallel to the flat surface.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to this, the terms or words used in this specification and claims are not to be interpreted in a conventional and dictionary sense, and the inventors may appropriately define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention.

According to the description of the present invention, the present invention is to provide a bridge support configured to easily determine whether the complete shrinkage mortar to be poured between the lower plate and the bridge (or alternating) of the bridge bearing.

In particular, the present invention ensures the optical path of the light irradiated from the sensor unit through the guide groove formed in the lower surface of the lower plate, and at the same time to discharge the air existing between the lower plate and the pier when pouring the non-contraction mortar It has the advantage of being available.

The present invention can also be detachably arranged on the side of the lower plate of the sensor unit capable of confirming the state of charge of the non-shrink mortar enables real-time measurement during pouring and curing.

According to the present invention, a shielding part is disposed in the lower opening of the induction groove to prevent inflow of mortar from induction grooves and the like, thereby maintaining a sound state to more accurately calculate the distance between the sensor unit and the induction mortar to exist. And the size of the pores.

1 is a perspective view schematically showing a smart bridge bearing with a filling confirmation system of non-shrink mortar according to the present invention.
Figure 2 is a perspective view from below of the lower plate provided in the bridge support according to the first embodiment of the present invention.
3 is a cross-sectional view schematically illustrating the lower plate shown in FIG. 2.
4 is an exploded perspective view of the lower plate shown in FIG. 2.
Figure 5 is a state diagram that can confirm the construction state of the smart bridge support with a filling confirmation system of the non-shrink mortar according to the present invention, Figure 5 (a) is a bridge bearing there is no gap between the non-shrink mortar and the lower plate 5 (b) is a diagram illustrating a bridge support in which a gap exists between the non-shrink mortar and the lower plate.
6 is an exploded perspective view of the lower plate provided in the bridge support according to the second embodiment of the present invention.
FIG. 7 is a schematic cross-sectional view of the lower plate illustrated in FIG. 6.
8 is an exploded perspective view of the lower plate provided in the bridge support according to the third embodiment of the present invention.
FIG. 9 is a schematic cross-sectional view of the lower plate shown in FIG. 8.

The objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and embodiments associated with the accompanying drawings. In the present specification, in adding reference numerals to the components of each drawing, it should be noted that the same components as possible, even if displayed on different drawings have the same number as possible. In addition, in describing the present invention, if it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In this specification, terms such as first and second are used to distinguish one component from another component, and a component is not limited by the terms. In the accompanying drawings, some components are exaggerated, omitted, or schematically illustrated, and the size of each component does not fully reflect the actual size.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 5, a smart bridge support (hereinafter referred to as a bridge support) having a filling confirmation system of non-shrink mortar according to the first embodiment of the present invention and the upper plate 10 coupled to the lower portion of the support object; , The lower plate 20 coupled to the installation object to face the upper plate 10, and the elastic support member 30 interconnecting the upper plate 10 and the lower plate 20, preferably the lower plate. The sensor unit 50 may be provided on the side of the 20. In the present invention, the upper plate and the lower plate may be made of a plate-shaped metal material.

Bridge bearing according to the present invention is configured to determine the presence of the gap by measuring the distance to the object (that is, the non-shrink mortar) using the laser light emitted from the sensor unit 50.

The bridge support according to the present invention may be interposed at the contact point of the bridge's upper structure and the bridge (or alternating) supporting the load, the upper plate 10 is the lower portion of the upper structure 100 of the bridge corresponding to the support object The lower plate 20 is fixed to the surface of the pier (or alternating) 200 corresponding to the installation object.

The lower plate 20 may be formed in a plate shape that is fixed to the upper surface of the pier 200, the anchor socket lengthwise extended from the lower surface of the lower plate 20 by the stud bolt 21 vertically ( 22) can be connected integrally. Here, the bridge support of the present invention can be reinforced by supplying non-contraction mortar (C; concrete) to the side of the lower plate 20 between the lower plate 20 and the pier 200 to strengthen the adhesion between the lower plate and the pier. have. Through this placing process, the bridge support of the present invention can be fixed by embedding the anchor socket 22 of the lower plate in the piers 200.

The elastic support member 30 (or bearing) is disposed between the upper plate 10 and the lower plate 20 as shown in the figure, and is configured to transmit the load of the support object to the installation object and to absorb and absorb the horizontal external force. The member may be made of a rubber material and / or a metal material.

As described above, since the bridge bearing supplies the non-contraction mortar (C) to the side of the lower plate 20, air is not discharged to the outside at the center of the lower surface of the lower plate 20 to generate voids ( See FIG. 5 (b)).

Thus, the present invention forms the guide groove 23 on the lower surface of the lower plate (20). The guide groove 23 extends in an inverted U-shaped cross-section from the lower edge of the lower plate 20 to the center of the lower surface. In other words, one end of the guide groove 23 is disposed at the edge of the lower surface of the lower plate, while the other end of the guide groove 23 is disposed at the center of the lower surface of the lower plate.

As shown, the lower plate 20 is the sensor unit 50 by means of the guide groove 23 is formed concave in the inverted U-shaped cross-sectional shape so as to have a predetermined depth in the thickness direction from the lower surface toward the upper surface. In addition to providing a movement path of the light irradiated from the) it can also be utilized as a discharge path for discharging the air remaining between the lower plate 20 and the pier 200 to the outside.

The sensor unit 50 detects light reflected back after irradiating light toward a target to measure an accurate distance. As illustrated in FIG. 6, the sensor unit 50 includes a light emitting unit 51 for irradiating light (laser, infrared light, etc.) to the target, a light receiving unit 52 for receiving light reflected from the target, and a light receiving unit that is reflected through the target. Detachable portion of the sensor unit 50 adjacent to the control unit 53 for calculating the distance to the target from the sensor unit through the time coefficient using the light received by the 52, and the guide groove 23 of the lower plate 20. It is provided with a magnetic 54 to help. The term target may be non-contraction mortar (C) cast (and cured) between the lower plate 20 and the upper surface of the pier (or alternating). The control unit 53 displays a distance from the sensor unit to the non-shrink mortar to be positioned below the lower surface of the lower plate, a display for confirming the presence of voids, and remote and / or short-range wireless communication to transmit the result to an external device. Communication can be built-in, and the operating state of the sensor can be switched on or off or other settings can be set as needed.

In addition, the sensor unit 50 arranges the light emitting unit 51, the light receiving unit 52, and the magnet 54 on one surface facing the side of the lower plate. The light emitting unit 51 and the light receiving unit of the sensor unit 50 are disposed. A lip 56 protruding outwardly from one surface to assist positioning of the 52 into one end of the guide groove 23 of the lower plate 20. Lip portion 56 may have a size and shape that can be inserted into the inner surface of the guide groove 23, the light emitting portion 51 and the light receiving portion 52 can be disposed in the inner region of the lip portion 56 do.

The sensor unit 50 may be easily detachable on one side of the lower plate 20 of the metal material, specifically, one end of the guide groove 23 using the magnetic 54. As a result, in the present invention, the light emitting unit 51 and the light receiving unit 52 may be disposed in one end of the guide groove 23. Correspondingly, at the other end of the guide groove 23 is disposed a reflection mirror 25 for reflecting the light path to the target.

The light emitting unit 51 may emit light (incident light) into the guide groove 23. Incident light is guided along the guide groove 23 and reflected by the reflecting mirror 25 and refracted toward the target. Thereafter, the light reflected from the target (reflected light) may be guided back to the guide groove 23 through the reflecting mirror 25 and received by the light receiving unit 52. The controller 53 may specify the time of light emitted from the light emitting unit of the sensor unit and receive the light received from the light receiving unit to calculate and provide a distance / time from the sensor unit to the non-shrink mortar (C). For example, the worker may understand that if the time measured by the controller 53 is increased than the preset time, the operator delays the time due to the gap on the upper surface of the non-contraction mortar (C).

According to the present invention, the non-condensed mortar is formed near the center of the lower surface of the lower plate in real time through the sensor unit 50 even while placing the non-contraction mortar C between the lower plate 20 and the upper surface of the piers 200. You can check the casting height of C). Of course, the present invention can confirm the pouring height of the non-shrink mortar (C) after curing, it is preferable to maintain the pouring height of the non-shrink mortar at the same height (or level) of the lower surface of the lower plate.

The present invention is to guide the incident light and the reflected light along the guide groove 23 as described above, in order to prevent the non-shrink mortar inflow into the guide groove (23) when pouring the non-shrink mortar (C) in advance. In order to close the lower opening of the guide groove 23 may be provided with a shield (40). As shown in FIG. 4, the shield 40 may be disposed on the lower surface of the lower plate 20 so that the lower surface of the lower plate 20 may be generally flat. The shield 40 may be formed of the same metal material as the lower plate 20, so that the lower opening of the guide groove 23 may be easily finished by welding or the like.

Preferably, the flat surface 41 of the shield 40 has a length (L ₄ ) shorter than the length (L ₂ ) from one end to the other end of the guide groove (23). Since the length of the flat surface is shorter than the length of the guide groove 23, a gap is formed between the other end of the shielding portion and the other end of the guide groove 23, that is, the opening 44, and the opening 44 reflects. The incident light refracted by the mirror 25 or the reflected light reflected from the target may be allowed to enter or exit.

In addition, the smart bridge bearing with the non-shrink mortar filling confirmation system according to the present invention is a state in which the induction groove 23 under the state that the non-shrink mortar (C) is not filled under the lower surface of the lower plate after curing, forming a void The non-shrink mortar may be further fed into the voids to completely remove the voids between the lower plate and the upper surface of the piers.

Since the smart bridge bearing with the filling confirmation system of the non-shrink mortar according to the second embodiment of the present invention has a very similar structure except for the structural shape of the shield 40 shown in FIGS. Description of similar or identical components will be excluded here for the sake of clarity of understanding of the present invention.

The bridge support according to the second embodiment of the present invention includes a flat surface 41 which extends along the lower opening of the guide groove 23 and a pair of side surfaces vertically vertically positioned at both edges of the flat surface 41. 42, the shield 40 formed in the U-shaped cross-sectional shape is inserted into the guide groove 23.

As shown, the flat surface 41 of the shield 40 has a length shorter than the length from one end of the guide groove 23 to the other end, whereas the pair of side surfaces 42 have a length of the guide groove. Try to have substantially the same length. The reflection mirror 25 can be arranged between the pair of side surfaces 42. As such, the reflecting mirror 25 may be integrally disposed on the other end of the shield 40 to provide ease of assembly with structural simplification.

Of course, the reflecting mirror 25 can be arranged on the same line in the vertical direction with the opening 44 defined by the pair of side surfaces 42 and the flat surface 41.

As shown in FIGS. 8 to 9, the smart bridge bearing with the filling confirmation system of the non-shrink mortar according to the third embodiment of the present invention has a very similar structure except for the structural shape of the shield 40. As such, descriptions of similar or identical components will be omitted herein for the sake of clarity of understanding of the invention.

The bridge support according to the third embodiment of the present invention may include a shield 40 formed of a hollow rectangular cross section that can be accommodated in the guide groove 23. The shielding portion 40 of the hollow rectangular cross section is disposed between the flat surface 41, a pair of side surfaces 42 vertically raised from both edges of the flat surface 41, and a pair of side surfaces 42. And an upper surface 43 arranged in parallel with the flat surface 41, the length of the flat surface 41 being shorter than the pair of side surfaces 42. Accordingly, the shield 40 forms an opening 44 defined by the pair of side surfaces 42 and the flat surface 41, and the openings 44 can be arranged on the same line in the vertical direction with the reflective mirror 25. do.

The reflecting mirror 25 may be positioned and surrounded by the upper surface 43 and the pair of side surfaces 42.

Although the present invention has been described in detail by way of examples, this is for the purpose of describing the present invention in detail, and the bridge support having the filling confirmation system of the non-shrinkage mortar according to the present invention is not limited thereto. It will be apparent to those skilled in the art that modifications and improvements are possible.

All simple modifications and variations of the present invention fall within the scope of the present invention, and the specific scope of the present invention will be apparent from the appended claims.

10 ----- upper plate,
20 ----- lower plate,
23 ----- guideway,
25 ----- reflective mirror,
30 ----- elastic support member,
40 ----- shield,
50 ----- sensor unit,
C ----- non-shrink mortar.

Claims (8)

An upper plate 10 coupled to a lower portion of the supporting object;
The guide groove 23 is coupled to the installation object to face the upper plate 10, has a predetermined length (L ₂ ) from the lower edge to the center of the lower surface and is concave in the thickness direction toward the upper surface from the lower surface 23 A lower plate 20 having a reflecting mirror 25 disposed at the other end of the guide groove 23 located at the center of the lower surface;
An elastic support member 30 interposed between the upper plate 10 and the lower plate 20;
A non-shrink mortar (C) which is supplied and poured between the lower surface of the lower plate 20 and the installation object, and poured at the same height as the lower surface of the lower plate 20; And
And a sensor unit 50 detachably disposed at a side of the lower plate including one end of the guide groove 23 positioned at an edge of the lower surface of the lower plate 20.
The bridge support is installed at the contact point of the support object and the installation object, and detects the light returned from the sensor unit 50 toward the non-shrink mortar (C) by the guide groove 23 as a means. Smart bridge bearing with a filling confirmation system of non-shrink mortar that can secure the optical path to inspect the presence of voids between the bottom plate and the non-shrink mortar.
The method according to claim 1,
The lower plate 20 is a smart bridge bearing with a filling confirmation system of non-shrink mortar made of a metal material.
The method according to claim 1,
The sensor unit 50,
A light emitting unit 51 for irradiating light to the non-contraction mortar (C);
A light receiving unit 52 for receiving light reflected from the non-contraction mortar (C);
A control unit (53) for calculating the distance from the sensor unit (50) to the non-shrink mortar (C) by the light reflected by the non-shrink mortar (C); And
And a magnetic 54 to help the light emitting unit 51 and the light receiving unit 52 to be positioned at one end of the induction groove 23.
The method according to claim 1,
The lower plate 20 has the guide groove 23 formed in an inverted U-shaped cross-sectional shape,
The induction groove 23 is a non-shrink mortar for arranging the shield 40 made of a flat surface 41 having a predetermined length (L ₄ ) to the lower opening of the induction groove at the same height as the lower plate Bridge with smart charging confirmation system.
The method according to claim 4,
The length (L ₄ ) of the flat surface 41 is formed shorter than the length (L ₂ ) of the guide groove 23,
Smart bridge support having a filling confirmation system of the non-shrink mortar forming an opening 44 between the flat surface 41 and the other end of the guide groove (23).
The method according to claim 5,
The opening 44 is a smart bridge bearing having a filling confirmation system of non-shrink mortar disposed on the same line in the vertical direction with the reflection mirror (25).
The method according to claim 4,
The shield 40 is a smart bridge bearing having a filling confirmation system of non-shrink mortar formed in a U-shaped cross-section having a pair of side surfaces 42 vertically vertically positioned at both edges of the flat surface (41).
The method according to claim 4,
The shield 40 has an upper portion arranged between a pair of side surfaces 42 vertically upwardly positioned at both edges of the flat surface 41 and a pair of side surfaces 42 parallel to the flat surface 41. Smart bridge bearing with a filling confirmation system of non-shrink mortar, which is formed in a hollow rectangular cross section with a face 43.

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