KR101084330B1 - Inspection system for bridge foundation structure by using water pressure sensor - Google Patents

Abstract

PURPOSE: A safety inspection system for a bridge foundation structure using a water pressure sensor is provided to by inspecting water pressure applied to the bottom end or edge of a bridge foundation structure. CONSTITUTION: A safety inspection system(1) for a bridge foundation structure using a water pressure sensor comprises a guide unit(110), a first reaction unit(120), an edge diagnosis unit(100), a second fastening unit(210), and a bottom end diagnosis unit(200). The guide unit covers the edge of a bridge foundation structure. The first reaction unit reacts when water pressure is applied to the bridge foundation structure. The edge diagnosis unit has a first fastening unit(130) which fixes the guide unit to the edge of the bridge foundation structure. The second fastening unit covers the bottom end of the bridge foundation structure. The bottom end diagnosis unit has a second reaction unit(220) coupled to the second fastening unit.

Description

Safety Diagnosis Device for Bridge Foundation Structures Using Water Pressure Sensors {Inspection System for Bridge Foundation Structure by Using Water Pressure Sensor}

The present invention relates to a safety diagnosis device for a bridge foundation structure, and more particularly, a circumference diagnostic device for measuring the water pressure transmitted to the circumference of the bridge foundation structure by a plurality of arc-shaped reaction plates around the bridge foundation structure underwater, bridge foundation At the bottom of the structure, by installing the bottom diagnosers that measure the water pressure transmitted to the bottom of the bridge foundation structure by a number of slanted reaction plates forming a solid shape, the manager automatically detects when high water pressure is transmitted around the bridge foundation structure. It is possible to prevent the large-scale accidents such as the damage of the bridge foundation structure and the collapse of the bridge by effectively protecting the lower part of the bridge foundation structure where the scour phenomenon due to the high water pressure is frequent. Of safety diagnosis device of bridge foundation structure using water pressure sensor The.

In general, a bridge is a structure in which the substructure and the superstructure are placed, and is mainly composed of a foundation pile, a pier foundation, a pier ping, a bridge arrangement, a box structure, and a bridge deck.

Here, the bridge foundation corresponds to the substructure, which is installed on the foundation pile installed in the ground, and transfers all the loads acting on the superstructure after the installation and installation of the superstructure through the piers into the ground of the riverbed (河床). Due to these structural characteristics, excessive load is transferred during actual use, and when the installation condition of the foundation pile is changed due to the ground change due to such imputation and natural phenomena, it is linked to provide bad effects to the entire bridge. Many.

In particular, the foundation of bridges in rivers, rivers, etc. is neutralized by external impact friction caused by moving objects such as rocks and stones flowing down during flooding and flooding, and by water pollution caused by pollutants and neutralization of the material itself. Due to corrosion of concrete and defects in the foundation due to poor construction, the wall part of the foundation is damaged or the reinforcing structure is exposed, or scour phenomenon occurs frequently in which the soil of the interview portion of the bottom of the bridge foundation structure and the underwater surface is lost. .

As a result, it was necessary to periodically monitor and monitor such scour phenomenon. Until now, such surveillance has been performed by a manager using a separate non-destructive device or visual inspection and photographing using divers. Not only could not be diagnosed, but also there were administrative problems.

On the other hand, in order to solve the problems as described above, there has been applied for a safety diagnosis method of the bridge foundation structure using a hydraulic pressure sensor, such as patent registration No. 0877349.

However, the device used in the safety diagnostic method as described above, the pressure plate sliding by the hydraulic pressure is configured in the shape of an arc plate, the outer circumference of the conventional bridge foundation structure is made of a circular shape to minimize the effect on the water pressure, bridge Contrary to the outer circumferential surface of the foundation structure, that is, the outer circumferential surface is formed in a concave plate shape substantially has a shape corresponding to the flow velocity in the water in the front, which is impossible to accurately detect the pressure due to the excessive pressure on the pressure plate. There was this.

In addition, the measurement method is also configured to be limited to the outer periphery of the bridge foundation structure, and is not suitable for the measurement of the hydraulic pressure acting on the lower end of the bridge foundation structure where the scour occurs easily and the interview portion of the underwater surface. There was a problem with a poor structure.

The present invention has been made to solve the above problems, the arc-shaped reaction plate is formed to form the same circular shape as the circumferential surface of the bridge foundation structure and the hydraulic pressure stably by the operation bar that is elastically developed to both sides of the hydraulic pressure transmitted to the arc reaction plate It operates with a sensing sensor to enable accurate diagnosis of the river water pressure delivered to the bridge foundation structure, and to detect the water pressure transmitted to the bottom of the bridge foundation structure by a number of slanted reaction plates. It is an object of the present invention to provide a safety diagnosis device for a bridge foundation structure using a sensor.

In addition, the circumference of the bridge foundation structure, as well as the interface between the bottom of the bridge foundation and the underwater surface, which are vulnerable to scour when high water pressure is applied, thereby preventing the scour phenomenon at the bottom, resulting in damage to the bridge foundation structure and resulting bridge collapse. Another object of the present invention is to provide a safety diagnosis device for a bridge-based structure using a hydraulic pressure sensor capable of preventing a large accident in advance.

As a specific means for achieving the above object, a guide portion surrounding the underwater circumference of the bridge foundation structure, a first reaction portion that reacts when the river water pressure acts by using the guide portion, and the circumference of the bridge foundation structure A circumferential diagnostic device that forms a first fastening part for fixing to the second fastening part that surrounds the underwater lower end of the bridge foundation structure, and a lower diagnosing part that is coupled to the second fastening part so as to slide up and down to form a second reaction part that responds to water pressure. In the bridge foundation structure safety diagnostic device configured to detect the strength and weakness of the river water pressure by the pressure sensor and control the risk,
The guide part of the circumferential diagnostic device is composed of two divided rings, each of which has a guide rail formed with a guide groove having a “c” shape and upper and lower surfaces of each guide rail. At least one first supporting rod having a protrusion formed therein and a plurality of pressure sensing sensors are formed in the guide groove at equal intervals, and the first reaction portion is a four-divided arc-shaped reaction plate and its respective arc shape having an outer circumferential surface. The inner surface of the reaction plate is formed with two sets of operating bars, one end of which is axially coupled and elastically connected by a spring, and each of the other ends of the operating bar is formed with rollers, and the first fastening part has two flanges at both ends. It is composed of upper and lower fastening rings of divided phase rings, each of which forms a plurality of fastening portions into which the first supporting rods are inserted,
The first reaction part is embedded between the guide groove and the hydraulic pressure sensor by the roller, and is inserted and nut-fastened to the fastening part of the upper and lower fastening rings by the first supporting rod of the guide part, and the flange of the upper and lower fastening rings. It is formed by fastening the bolts and nuts around the bridge foundation structure,
The second fastening part of the lower diagnosing part is composed of two fastening plates of two divided plates having flanges at both ends, each of which has a plurality of pressure sensing sensors formed at equal intervals and adjacent to each of the pressure sensing sensors. Each of the slide holes is formed in the second reaction part, and a plurality of inclined reaction plates having a quadrant formed in a downwardly inclined surface facing outward are formed, and each of the inclined reaction plates includes a second supporting rod having a locking part at the top and a screw at the upper end. Is formed to protrude and the spring and the touch bar is coupled to the top of each of the second support rod,
The inclined reaction plate is inserted into the slide hole from the bottom to the top by the second support rod and the spring is inserted, and the touch bar is coupled to the upper part of the spring so as to be spaced apart from the upper part of the hydraulic pressure sensor, by fastening plates on both sides. It can be achieved by configuring the bolt and nut fastened by the flange at the bottom of the bridge foundation structure.

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As described above, the safety diagnosis device for the bridge foundation structure using the hydraulic pressure sensor of the present invention includes a circumference diagnosis unit for detecting a danger by the operation of the hydraulic pressure sensor and the response to the water pressure by the arc-shaped reaction plate around the bridge foundation structure, and the bridge foundation In the lower part of the structure, the inclined reaction plate responds to the hydraulic pressure and the lower diagnosis device detects the danger by the operation of the pressure sensor. It is possible to prevent large accidents such as breakage or bridge collapse in advance.

In addition, it is possible to protect the bottom of the bridge foundation structure vulnerable to scour phenomenon, as well as preventing the scour phenomenon around the bridge foundation structure, in particular to protect the bottom of the bridge foundation structure and the surface of the underwater surface when the hydraulic pressure is applied by the slope reaction plate. You can get the effect.

1 is an overall perspective view of a safety diagnosis device for a bridge foundation structure using the present invention hydraulic pressure sensor.
Figure 2 is an exploded perspective view showing the circumference diagnostic device of the safety diagnosis device of the bridge foundation structure using the present invention hydraulic pressure sensor.
Figure 3 is an exploded perspective view showing a lower diagnosis of the safety diagnosis device of the bridge foundation structure using the present invention hydraulic pressure sensor.
Figure 4 is a combined perspective view of the state installed in the bridge foundation structure of the safety diagnosis device of the bridge foundation structure using the present invention water pressure sensor.
5 is an operational state diagram of the circumference diagnostic device of the safety diagnosis device of the bridge foundation structure using the present invention hydraulic pressure sensor.
Figure 6 is an operating state diagram of the lower diagnosis of the safety diagnosis device of the bridge foundation structure using the present invention water pressure sensor.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, 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.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention, and do not represent all of the technical idea of the present invention, which can be replaced at the time of the present application It should be understood that there may be various equivalents and variations.

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

1 is an overall perspective view of a safety diagnosis device for a bridge foundation structure using the present invention hydraulic pressure sensor.

As shown in FIG. 1, the safety diagnosis device 1 of a bridge foundation structure using the present invention hydraulic pressure sensor is installed to surround the underwater circumference of the bridge foundation structure 10 to provide safety according to the strength and weakness of the hydraulic pressure transmitted to the circumference. The circumference diagnosis device 100 for diagnosing, and is installed to surround the lower end of the water in the bridge foundation structure 10 is composed of a lower end diagnosis device 200 for diagnosing safety according to the strength of the hydraulic pressure transmitted to the lower end.

At this time, the circumference diagnostic apparatus 100, the guide portion 110 surrounding the underwater circumference of the bridge foundation structure 10, as shown in Figure 2, and reacts when the river water pressure acts by using the guide portion 110 as a guide The first reaction unit 120 and the guide unit 110 is composed of a first fastening unit 130 for fixing around the bridge foundation structure (10).

At this time, the guide portion 110, when combined to form a semi-circular ring shape divided into two divided to form a circular ring and each of the circumference is composed of a guide rail 111 formed with a guide groove (111a) of the "c" shape When the guide rails 111 are coupled to each other, guide grooves 111a in the circumferential direction are formed, and the engaging pieces 112a and the engaging pieces 112a are disposed on the upper and lower surfaces of the respective guide rails 111. And one or more first supporting rods 112 having a threaded portion M at the ends extending upwardly and downwardly protrudingly formed, and the plurality of pressure sensing sensors S are formed in the guide groove 111a at equal intervals. .

In addition, the first reaction unit 120 is to react when the river water pressure acts on the bridge-based structure 10, the quadrant arc-shaped reaction plate 121 is formed, the outer peripheral surface of the convex shape is formed, respectively The inner side of the arc-shaped reaction plate 121 is formed with two sets of operating bars 123, one end of which is coupled to the shaft (H), and the two sets of operating bars 123 are tension springs on the opposite sides ( 122 is elastically coupled to the operating bar 123 is configured to have a restoring force when deployed, and the other end of each operation bar 123 is formed with a roller 124.

Here, the first reaction unit 120 is inserted into the guide grooves of the guide rail 111 radially by the roller 124 formed on the other end of the operation bar 123, but each of the pressure sensing when the inside It is built between the sensors (S) is configured to touch-responsive to the water pressure detection sensor (S) located on both sides when the operation bar 123 is deployed.

In addition, the first fastening part 130 is for fastening the guide part 110 provided with the first reaction part 120 to the periphery of the bridge foundation structure 10, and has a semi-circular ring shape divided into two parts. Flange P is formed at each end thereof, and a plurality of fastening parts 132 into which the first supporting rods 112 are inserted are formed at each end thereof, and fastening support is provided at upper and lower portions of the guide part 110. The upper and lower fastening rings 131 and 131 'are configured to be possible.

Here, the first fastening portion 130, the upper and lower fastening ring 131, 131 'by the flange (P) fastened to the bolt (B) and the nut (N) is around the bridge foundation structure (10) The first support rods 112 protruding from the upper and lower surfaces of the upper and lower fastening rings 131 and 131 ′ are formed on the fastening portions 132 of the guide rails 111. What is necessary is to fasten and fasten the nut N to this insertion and the threaded part M. FIG.

In this case, the upper and lower fastening rings 131 and 131 'are supported by the locking pieces 112a formed on the upper portions of the respective first supporting rods 112, and are supported by the screw portions through the fastening portions 132. By only (M) protruding and fastening the nut (N), each arc-shaped reaction plate 121 can be installed in parallel.

In addition, the lower end diagnosis device 200 is coupled to the second fastening part 210 surrounding the lower end of the underwater portion of the bridge foundation structure 10 and the fastening part 132 so as to slide up and down as shown in FIG. It is composed of a second reaction unit 220.

At this time, the second fastening portion 210 is composed of two fastening plates 211 made of semi-circular plates formed in two parts having flanges P at both ends, and flanges P are formed at each end thereof. A plurality of pressure sensing sensors S are formed at equal intervals on the peripheral portion of the fastening plate 211, and slide holes 212 are formed through the adjacent portions of the pressure sensing sensors S, respectively.

In addition, the second reaction unit 220 is composed of a plurality of inclined reaction plate 221 divided into four divided by a downward inclined surface (221a) gradually widening from the upper to the lower, each of the inclined reaction plate 221 On the inclined surface 221a of the upper surface), a second supporting rod 222 having a threaded portion M is formed to protrude from an upper end extending with the locking piece 222a and the locking piece 222a, and the second supporting rod The upper end of the 222 is a compression type spring 223 and the touch bar 224 is formed.

Here, the second reaction unit 220, the inclined reaction plate 221 is inserted into the slide hole 212 of the fastening plate 211 by the second support rod 222 from the bottom to the top and to the engaging piece 222a. The lower locking and the screw portion (M) is exposed to the upper portion of the slide hole 212, the spring 223 is inserted into the exposed screw portion (M) and the touch bar 224 at the end of the hydraulic pressure sensor (S) The nut (N) is fastened to a predetermined distance to the upper portion, and the bolt (B) and the nut (N) is fastened by the flange (P) to the lower end of the bridge foundation structure 10 by the fastening plate 211 of both sides.

At this time, the inclined reaction plate 221, the lower end of the bridge foundation structure 10, that is, it is preferable to install a predetermined distance from the underwater ground buried portion.

In addition, the springs 122 and 223 installed in the circumference diagnosis device 100 and the lower diagnosis device 200 may be pre-tensioned and compressed when a hydraulic pressure greater than or equal to a safety pressure is applied according to the installation conditions of the bridge foundation structure 10. It is preferable to use springs that have been tested for elasticity.

In addition, each of the pressure detection sensors (S) installed in the circumference diagnosis device 100 and the lower diagnosis device 200 to detect the strength and weakness of the water pressure is provided in a separate control unit (not shown in the drawing) for control and diagnosis of the manager. It is preferable to configure as possible.

Hereinafter, with reference to the accompanying drawings, the operation of the safety diagnosis device for the bridge-based structure using the present invention hydraulic pressure sensor having the configuration as described above will be described in detail.

As shown in FIG. 4, the safety diagnosis apparatus for a bridge foundation structure using the hydraulic pressure sensor according to the present invention has a circumference diagnosis device 100 installed around the bridge foundation structure 10 in the water, and a lower diagnosis device 200 at the bottom thereof. When the river water pressure is installed in the water, the strength and weakness of the pressure sensor is detected and the controller through the manager to diagnose the safety status of the bridge foundation structure.

In detail, first, when a strong hydraulic pressure is applied to the periphery of the bridge foundation structure 10 as shown in Figure 5, to minimize the action of the hydraulic pressure transmitted to the structure around the conventional bridge foundation structure 10 In order to be constructed in a circular form for the general bar, when the water pressure below a predetermined pressure acts on the arc reaction plate 121 of the present invention formed in the same shape as the circumference according to the flow rate of the operation is not made.

At this time, when a predetermined or more water pressure acts according to the flow velocity of the river, the arc-shaped reaction plate 121 is compressed to the bridge foundation structure 10 by water pressure, and at this time, the arc-shaped reaction plate 121 by the compression force. The operating bar 123 on both sides formed on the inner surface of the spring 122, 223 to overcome the force of the force is deployed, the guide groove of the guide rail 111 by the roller 124 formed at its end 111a is deployed to both sides, and when the hydraulic pressure of the safety state is applied to the roller 124 of the operation bar 123 to be developed to touch the pressure sensor (S) so that the pressure sensor (S) reacts. Will be.

Thereafter, the water pressure sensor S transmits the signal to the controller (not shown in the figure) and transmits a dangerous state around the bridge base structure 10 due to high water pressure to the manager according to the signal of the controller. Recognizing this will take the safety measures of the bridge foundation structure (10).

In addition, when a strong hydraulic pressure is applied to the lower end of the bridge foundation structure 10 as shown in Figure 6, the hydraulic pressure acts on the inclined surface (221a) of the inclined reaction plate 221, the inclined reaction plate 221 If the water pressure below a certain amount depending on the flow rate of the river is not working.

At this time, when a predetermined or more water pressure acts according to the flow rate of the river, the inclined reaction plate 221 is compressed to the lower part by the water pressure. At this time, the inclined reaction plate 221 protrudes on the inclined reaction plate 221 by the compression force. The second support rod 222 is also slid downward through the slide hole 212 of the fastening plate 211, and at the same time the touch bar 224 coupled to the end is moved downward and touch the pressure detection sensor (S) The pressure sensor (S) is to react.

Thereafter, the water pressure sensor S transmits the signal to the controller (not shown in the figure) and transmits the dangerous state of the lower end of the bridge foundation structure 10 due to high water pressure to the manager according to the signal of the controller. Recognizing this will take the safety measures of the bridge foundation structure (10).

In addition, in general, the scour phenomenon of the ground sediment is frequently generated when high water pressure is applied to the boundary portion embedded in the underwater ground of the bridge foundation structure 10. At this time, the inclined reaction plate 221 is lowered by the water pressure. It is possible to prevent scour at the boundary between the bridge foundation structure 10 and the underwater ground by moving and covering the ground.

As described above, the present invention effectively diagnoses the risk of hydraulic pressure transmitted to the bridge base structure underwater by the circumference diagnosis device and the bottom diagnosis device at the circumference and the bottom thereof, and effectively prevents the scour phenomenon. Large accidents such as bridge collapse can be prevented beforehand.

100: circumference diagnostic device 110: guide part
111: guide rail 111a: guide groove
112: first support rod 120: first reaction part
121: arc-shaped reaction plate 122: spring
123: operation bar 124: roller
130: first fastening part 131,131 ': upper and lower fastening ring
132: fastening portion 200: the lower diagnostic machine
210: second fastening portion 211: fastening plate
212: slide hole 220: second reaction part
221: inclined reaction plate 222: second support rod
223 spring 224 touch bar
H: Shaft M: Thread
P: Flange S: Hydraulic Pressure Sensor

Claims (3)

The guide part 110 surrounding the underwater circumference of the bridge foundation structure 10, the first reaction part 120 reacting when the water pressure acts using the guide part 110 as a guide, and the guide part 110. And a circumferential diagnostic device 100 constituting the first fastening portion 130 for fixing the circumference of the bridge foundation structure 10, a second fastening portion 210 surrounding the lower end of the underwater portion of the bridge foundation structure 10, and It is composed of the lower diagnostic device 200 is coupled to the second fastening portion 210 to slide up and down to form a second reaction unit 220 responding to the water pressure dangerous to detect the strength and weakness of the river water pressure by the water pressure sensor and the controller In the bridge foundation structure safety diagnostic device for diagnosing
The guide portion 110 of the circumference diagnostic apparatus 100 is composed of two divided rings, each of which has a guide rail 111 and a guide rail 111 having a guide groove 111a having a “c” shape. 111) At least one first supporting rod 112 having a locking piece 112a at the upper circumference and a threaded portion M at the end is formed on the upper and lower surfaces thereof, and the plurality of hydraulic pressure sensing units are provided at equal intervals in the guide groove 111a. The sensor S is formed inwardly, and the first reaction part 120 has a quadrant arc-shaped reaction plate 121 having an outer circumferential surface formed in a convex shape, and one end thereof is formed on an inner surface of each arc-shaped reaction plate 121. (H) two pairs of operating bars 123 coupled and elastically connected by a spring 122 are formed, and rollers 124 are formed at the other ends of the respective operating bars 123, respectively, and the first fastening part 130 is composed of upper and lower fastening rings 131 and 131 'formed of two-divided rings having flanges P at both ends thereof. 1 form a plurality of fastening portion 132 is inserted into the support rod 112,
The first reaction part 120 is embedded between the guide groove 111a by the roller 124 and between the hydraulic pressure sensor S, and the first supporting rod 112 of the guide part 110 is used for the upper part. Insertion and nut (N) is fastened to the fastening portion 132 of the lower fastening ring (131) (131 ') and bridge foundation structure (10) by the flange (P) of the upper and lower fastening ring (131) (131') It is formed to fasten the bolt (B) and the nut (N) around the
The second fastening part 210 of the lower end diagnosis device 200 is composed of two side fastening plates 211 made of a plate of two splits having flanges P at both ends thereof, and each of the upper peripheries has a plurality of hydraulic pressure sensors ( S) is formed at equal intervals, and slide holes 212 are formed in the proximal portions of the respective pressure sensing sensors S, and the second reaction part 220 forms a downward inclined surface 221a facing outward. A plurality of inclined reaction plates 221 of four divisions are formed, and each of the inclined reaction plates 221 has a second supporting rod 222 having a locking piece 222a at the top and a threaded portion M at the top thereof. On each upper end of the second support rod 222 is configured to be coupled to the spring 223 and the touch bar 224,
The inclined reaction plate 221 is inserted into the slide hole 212 and the spring 223 is inserted by the second support rod 222 from the bottom to the top, the touch bar 224 on the top of the spring 223 N is coupled to the nut (N) so as to be spaced apart from the upper portion of the hydraulic pressure sensor (S), the bolt (B) and the nut by the flange (P) at the lower end of the bridge foundation structure 10 by the fastening plate 211 of both sides (N) Safety diagnosis device of the bridge foundation structure using a hydraulic pressure sensor, characterized in that configured to be fastened. delete delete

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