CN212539114U

CN212539114U - Bridge crack dynamic monitoring device

Info

Publication number: CN212539114U
Application number: CN202021301167.9U
Authority: CN
Inventors: 聂华伟; 邓捷
Original assignee: Guizhou Jiaotong College
Current assignee: Guizhou Jiaotong College
Priority date: 2020-07-06
Filing date: 2020-07-06
Publication date: 2021-02-12
Anticipated expiration: 2030-07-06

Abstract

The utility model discloses a dynamic bridge crack monitoring device, which belongs to the technical field of bridge maintenance and comprises a shell B and a shell A, wherein the shell B is connected with the shell A to form a box body structure with one open side, a swing rod is arranged outside the shell B and can swing around a rotating shaft; the swing rod is divided into a short side and a long side by taking the rotating shaft as a boundary, and an arc-shaped groove is further formed in the shell B at the long side end of the swing rod; and a displacement sensor, a storage battery, a communication module, a positioning module, a central processing unit and the like are arranged in the shell B. According to the technical scheme, the split type shell structure is arranged, so that the function of monitoring the crack development condition of the concrete building is realized; through set up the pendulum rod structure in the casing outside, just monitor through displacement sensor after carrying out several times with the direct change value of crack and enlargiing, realized the enlargiing of crack change condition for the change data of crack is monitored more easily to the sensor, has reduced the precision and the sensitivity requirement of disease monitoring to the sensor.

Description

Bridge crack dynamic monitoring device

Technical Field

The utility model belongs to the technical field of the bridge maintenance, a an auxiliary assembly that is used for bridge maintenance and disease prevention and cure is related to, especially, relate to a bridge crack dynamic monitoring device.

Background

The bridge is used as the throat of traffic, the safety condition of the bridge not only directly influences the normal operation of the whole traffic network, but also causes great negative social influence once the bridge destroys an incident of death because of the particularity of the bridge. Due to historical limitations or human factor influences, the bridge may have the situations of incomplete design, poor construction, improper management and the like, and with the increase of the operation years, many bridges have diseases of different degrees. In order to avoid catastrophic accidents and ensure the safety of people's lives and properties, it is necessary to ensure that these defects or hidden dangers can be discovered in time and remedied and eliminated.

At present, most of small and medium span concrete bridges are mainly realized by regular manual detection or by means of load tests in terms of structural states. When a bridge structure is damaged and needs to be reinforced, maintained or rebuilt, a long period is usually needed from declaration, item establishment and batch return to formal implementation, and the period is months in short and years in long. The bridge has a high probability of presenting a significant safety problem during this "vacuum period". In order to ensure safety, the bridge management department can continuously improve the manual detection frequency in the period, so that the latest development condition of the bridge structure diseases is obtained. As a result, the daily maintenance cost of the bridge is greatly improved, and as time goes on, if more and more bridges have diseases of different degrees, the workload of daily maintenance of the bridge is hard to bear by bridge management departments and detection units. Moreover, data before and after manual detection is affected by human factors, and the deviation of the accuracy and comparability of the data is large, so that problems cannot be found in time.

With the development of big data and artificial intelligence technology becoming mature, the big data and artificial intelligence technology are gradually applied to bridge disease monitoring. Wherein, monitoring to the bridge crack, chinese utility model patent that application number is 201820522926.0 discloses a bulky concrete crack monitoring device, utilize humidity transducer, a weighing sensor and a temperature sensor, a central processing unit, image acquisition device, image processing device etc. carry out real time monitoring to bulky concrete, data that a sensor among humidity transducer and the temperature sensor surveyed surpass after presetting the threshold value, central processing unit sends image acquisition trigger signal with the control signal trigger, image acquisition device gathers the image information of the bulky concrete that awaits measuring, and transmit to central processing unit behind image processing device, central processing unit judges whether there is the crack in the bulky concrete that awaits measuring through the image information of received image processing device output, if, then trigger alarm device sends alarm information. The device is mainly used for discovering crack diseases.

Chinese utility model patent with application number CN201821707974.3 discloses a long-term monitoring of portable crack width, early warning system, including the sensor, data acquisition equipment and remote monitoring device etc, independently analyze data through data processing unit, calculate, reduce the human factor error, and compare the upper limit threshold value with the setting, if the measured value is big then automatic triggering alarm, realize automatic monitoring, liberation on-the-spot monitoring personnel, improve productivity, realize remote monitoring, can provide the most direct judgement foundation to the administrator in real time. Although the technical scheme provides a monitoring and early warning system, the specific structure of the monitoring device is not provided.

The application number is CN 201821112927.4's chinese utility model patent, a concrete structure crack width monitoring ruler is disclosed, through main scale both ends fixed connection in the fissured both sides of concrete structure, the slide rail has openly been seted up to the vice chi, in main scale sliding connection's the slide rail, the equal fixedly connected with gusset plate in main scale back both ends, the through-hole has been seted up to the junction of gusset plate and main scale, the through-hole runs through in gusset plate and main scale, be equipped with the cement nail in the through-hole, the cement nail runs through in the through-hole and extends to inside the concrete, the scale mark is openly established to main scale and vice chi, through the change value of regularly reading the scale mark, can reach fissured situation of change. The technology is a traditional crack monitoring technology, needs manual regular inspection and has large workload.

In the prior art, a large number of tools are used for monitoring large-volume concrete engineering cracks, and the problems that firstly, the intelligent degree is not high, and the large-volume concrete engineering cracks are dependent on manual regular data acquisition to a great extent are generally solved; secondly, the volume is large, and the volume of the used monitoring instrument is large due to small change of cracks and the fact that accurate data are required to be acquired, so that the installation is difficult to realize, and the normal work of the instrument is more difficult to ensure; third, when the fracture changes very slightly over a period of time, valid data may not be obtained.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides a bridge crack dynamic monitoring device to realize on-the-spot simple to operate, accurate monitoring crack data change, thereby realize bridge crack real-time supervision, in time judge the effect of potential safety hazard.

The utility model discloses a realize through following technical scheme.

A dynamic bridge crack monitoring device comprises a shell B and a shell A, wherein the shell B and the shell A are connected together to form a box structure with one open side, and the joint of the shell B and the shell A is movably connected together through a telescopic structure; the shell B is also externally provided with a swing rod, the swing rod is movably arranged on the shell B through a rotating shaft, and the swing rod can swing around the rotating shaft; the swing rod is divided into a short edge and a long edge by taking the rotating shaft as a boundary, and the end point of the short edge is movably connected with the shell A through a connecting rod; the shell B at the long side end of the swing rod is also provided with an arc-shaped groove, the arc-shaped groove penetrates through the shell B, and the radian of the arc-shaped groove is the maximum swing stroke of the swing rod; a moving module is arranged in the arc-shaped groove, penetrates through the arc-shaped groove, is fixedly arranged at the long edge end of the swing rod, and slides in the arc-shaped groove under the driving of the swing rod; casing B internally mounted displacement sensor, casing A internally mounted battery, communication module, orientation module and central processing unit, displacement sensor, communication module, orientation module and central processing unit are respectively through the battery power supply, and displacement sensor, communication module and orientation module are connected with central processing unit again respectively.

Furthermore, the shell B and the shell A are respectively internally provided with corresponding unthreaded holes along the plane direction of the shell, connecting springs are arranged in the unthreaded holes, and two ends of each connecting spring are respectively fixed at the bottoms of the unthreaded holes.

Furthermore, the swing rod is divided by the rotating shaft, and the length of the long side is 5-10 times of that of the short side.

Furthermore, the end point of the long edge of the oscillating bar is movably connected with the shell A through a reset connecting belt, and the reset connecting belt is an elastic rubber belt.

Furthermore, a supporting seat is arranged on one side of the shell B and one side of the shell A, and the supporting seat is only in contact with the shell B and the shell A and is not connected with the shell B.

Furthermore, the positioning module adopts a GPS satellite positioning system or a Beidou satellite positioning system.

Furthermore, the arc-shaped groove edge is provided with scales, and the maximum radian of the arc-shaped groove is 60 degrees.

Furthermore, the edges of the shell B and the shell A are respectively provided with a mounting flange, and the mounting flanges are respectively provided with a plurality of mounting holes.

Furthermore, a power switch is arranged on the shell A.

The utility model has the advantages that:

bridge crack dynamic monitoring device:

the split type shell structure is arranged, and the key components inside are respectively installed in the two parts of shells, so that the shells are separated, and the function of monitoring the crack development condition of the concrete building is realized.

The swing rod structure is arranged outside the shell, the direct change value of the crack is amplified for multiple times and then monitored by the displacement sensor, so that the change condition of the crack is amplified, the change data of the crack can be monitored by the sensor more easily, the requirements of disease monitoring on the accuracy and sensitivity of the sensor are lowered, the sensor with a smaller volume can be selected, the size of the whole device is reduced, and the device is more convenient to carry and install.

The intelligent module is introduced, the installation position of the accurate positioning device is quickly identified by setting the positioning module, data are uploaded in real time through the communication module, the workload of manual regular field monitoring is reduced, errors of data obtained through manual detection and instability of manual operation are reduced, and the acquired data more accord with actual change conditions of bridge cracks.

The technical scheme has the advantages of simple structure, easy realization, low requirements on the precision and the sensitivity of the sensor, reduction of the manufacturing cost of the whole device and suitability for popularization and application in the bridge disease control technology.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the inner unthreaded hole of the middle housing of the present invention.

Fig. 3 is a schematic structural diagram of internal components of the middle housing B according to the present invention.

Fig. 4 is a schematic structural diagram of the internal components of the middle shell a of the present invention.

Fig. 5 is a schematic diagram of the system structure of the present invention.

Fig. 6 is a schematic diagram of the calculation principle of the middle crack variation value of the present invention.

In the figure: 1-crack, 2-bridge, 3-arc groove, 4-installation flange, 5-shell B, 6-rotating shaft, 7-oscillating bar, 8-connecting rod, 9-shell A, 10-reset connecting belt, 11-unthreaded hole, 12-connecting spring, 13-displacement sensor, 14-moving module, 15-supporting seat, 16-storage battery, 17-communication module, 18-positioning module, 19-central processor and 20-power switch.

Detailed Description

The technical solution of the present invention is further described below with reference to the accompanying drawings, but the scope of protection claimed is not limited to the description.

As shown in fig. 1-5, the dynamic bridge crack monitoring device of the present invention includes a housing B5 and a housing a9, wherein the housing B5 and the housing a9 are connected together to form a box structure with an opening on one side, and the connection between the housing B5 and the housing a9 is movably connected together through a telescopic structure; a swing rod 7 is further arranged outside the shell B5, the swing rod 7 is movably mounted on the shell B5 through a rotating shaft 6, and the swing rod 7 can swing around the rotating shaft 6; the swing rod 7 is divided into a short side and a long side by taking the rotating shaft 6 as a boundary, and the end point of the short side is movably connected with the shell A9 through a connecting rod 8; the shell B5 at the long side end of the swing rod 7 is also provided with an arc-shaped groove 3, the arc-shaped groove 3 penetrates through the shell B5, and the radian of the arc is the maximum swing stroke of the swing rod 7; a moving module 14 is arranged in the arc-shaped groove 3, the moving module 14 passes through the arc-shaped groove 3 and is fixedly arranged at the long edge end of the swing rod 7, and the moving module 14 slides in the arc-shaped groove 3 under the driving of the swing rod 7; the displacement sensor 13 is mounted inside the housing B5, and the storage battery 16, the communication module 17, the positioning module 18 and the central processor 19 are mounted inside the housing a 9.

The displacement sensor 13, the communication module 17, the positioning module 18 and the central processing unit 19 are respectively powered by the storage battery 16, the displacement sensor 13, the communication module 17 and the positioning module 18 are respectively connected with the central processing unit 19, and the communication module 17 is wirelessly connected with the data center.

The inside corresponding unthreaded hole 11 along the casing plane direction that is equipped with respectively of casing B5 and casing A9, be equipped with connecting spring 12 in the unthreaded hole 11, connecting spring 12 both ends are fixed respectively in unthreaded hole 11 bottom. The function of the device is to ensure that the shell B5 and the shell A9 can be tightly attached at the initial position, can be separated by overcoming the elasticity of the spring 12 when the crack is expanded, can be restored to the initial position after the monitoring is finished, and ensures that the device can be repeatedly used.

The swing rod 7 is divided by the rotating shaft 6, and the length of the long side is 5-10 times of that of the short side. The effect is that the displacement directly obtained from the end point of the short side is amplified at the end point of the long side, so that the displacement sensor 13 can more easily monitor the small change of the crack 1.

The end point of the long edge of the oscillating bar 7 is movably connected with the shell A9 through a reset connecting belt 10, the reset connecting belt 10 is an elastic rubber belt, and the reset connecting belt is mainly used for resetting the oscillating bar 7, so that the oscillating bar 7 is ensured to be at an initial position when equipment is installed.

And a support seat 15 is further arranged on one side of the shell B5 and one side of the shell A9, the support seat 15 is only in contact with the shell B5 and the shell A9, the connection relationship is not formed, and the support seat 15 can also be connected with a bridge body through a cement nail. The support seat 15 is mainly used for mounting on a vertical surface to increase the degree of stability of the case B5 and the case a 9.

The positioning module 18 adopts a GPS satellite positioning system or a beidou satellite positioning system.

The edge of the arc-shaped groove 3 is provided with scales, and the maximum radian of the arc-shaped groove 3 is 60 degrees, namely the maximum swing angle of the swing rod 7. In the actual operation process, the swing angle of the swing rod 7 is generally below 15 degrees, before the swing angle is reduced, the potential safety hazard is eliminated, and the crack cannot be further enlarged.

The edges of the shell B5 and the shell A9 are respectively provided with a mounting flange 4, the mounting flanges 4 are respectively provided with a plurality of mounting holes, and the mounting holes can be connected and fixed with a bridge body through cement nails or screws and the like.

The shell A9 is provided with a power switch 20, the power switch 20 is mainly used for starting and stopping the device, and when the device is installed on the bridge body 2, the power switch 20 can be started to enter a working state.

Examples

As shown in fig. 1-5, before use, the storage battery 16 is ensured to be sufficiently charged, and the normal operation of each component is determined through debugging. When the device is installed, the installation position of the device is arranged according to the position of the crack, the installation direction of the shell is perpendicular to the crack covered by the shell, and the shell B5 and the shell A9 are ensured to be in the initial position, the end faces are in close contact, and the two side faces are respectively positioned on the same plane.

The present apparatus is placed on the bridge body 2 at the gap 1 so that the case B5 and the case a9 are positioned on both sides of the gap 1, and cement nails are driven into the mounting holes of the mounting flange 4 to fix the positions of the case B5 and the case a9, respectively. After the installation is finished, the power switch 20 is pressed, the device is started, the device enters a working state, waterproof measures are made, and the installer can leave the site. Each device has a unique serial number, and the serial numbers correspond to the positioning modules 18 in the device one by one, so that the position of each device can be accurately positioned; after the system normally works, the position information and the initial value of the crack are uploaded to the central processing unit 19, the central processing unit 19 obtains the data and then transmits the data to the data center through the communication module 17 for storage, and technicians in the data center download, monitor and analyze the data.

In the working process, when the crack is not changed, the uploaded data is not changed, which indicates that the crack is not deteriorated, and measures can be temporarily not taken. When the width of the crack is gradually enlarged, the relative positions of the shell A9 and the shell B5 are changed, the interval between the shells is opened, and the short side of the swing rod 7 connected with one end of the swing rod rotates around the rotating shaft 6 under the pulling of the connecting rod 8 because the length of the connecting rod 8 is fixed. Because the swing rod 7 takes the rotating shaft 6 as a dividing point, and the length of the long side is 5-10 times of the length of the short side, when the end point of the short side of the swing rod 7 slightly rotates for a certain arc length, the arc length rotating at the end point of the long side of the swing rod 7 is amplified by 5-10 times; at this time, the moving module 14 connected to the end point of the long side of the swing link 7 is driven by the swing link 7 to slide in the arc-shaped groove 3. The displacement sensor 13 monitors the displacement of the mobile module 14 in the casing B5, and uploads the data to the central processing unit 19 during periodic uploading, and the central processing unit 19 uploads the data to the data center through the communication module 17 for storage, so that technicians in the data center can download, monitor and analyze the data. When the change speed of the crack or the width of the crack reaches a set threshold value, the bridge management department immediately takes remedial measures to repair the crack to avoid disasters.

The crack detection device is characterized in that the radian of the end point of the short side of the swing rod 7 driven by the connecting rod 8 to rotate can approximately represent the change value of the crack 1, but the variable is possibly very small, 5-10 times of amplification is shown at the end point of the long side of the swing rod 7 through the amplification effect of the swing rod 7, so that the displacement sensor 13 can more easily monitor the change of the crack 1, the change value of the crack 1 can be more easily acquired, at the moment, the movement of the moving module 14 monitored by the displacement sensor 13 is linear displacement data, and the linear displacement length is assumed as a for convenient calculation₁Let a be a straight-line distance by which the end point of the short side moves₂Then a is₂＝na₁Wherein n is r₁Relative r₂Multiples of (a). As shown in fig. 6.

Suppose the length r of the long side of the pendulum 7₁Is the length r of the short side₂X is a when the width variation value of the bridge crack is denoted by x₂A and a₂＝5a₁。a₁The value of (d) can be monitored directly by a displacement sensor.

The above-mentioned embodiments are merely exemplary, so as to enable those skilled in the art to better understand the technical solution, and should not be construed as limiting the scope of the present invention, and all modifications and simple substitutions made according to the technical solution of the present invention fall within the scope of the present invention.

Claims

1. The utility model provides a bridge crack dynamic monitoring device, includes casing B (5) and casing A (9), casing B (5) and casing A (9) link together, form one of them open-ended box body structure, its characterized in that: the connection part of the shell B (5) and the shell A (9) is movably connected together through a telescopic structure; a swing rod (7) is further arranged outside the shell B (5), the swing rod (7) is movably mounted on the shell B (5) through a rotating shaft (6), and the swing rod (7) can swing around the rotating shaft (6); the swing rod (7) is divided into a short side and a long side by taking the rotating shaft (6) as a boundary, and the end point of the short side is movably connected with the shell A (9) through a connecting rod (8); an arc-shaped groove (3) is further formed in the shell B (5) at the long side end of the swing rod (7), the arc-shaped groove (3) penetrates through the shell B (5), and the radian of the arc-shaped groove is the maximum swing stroke of the swing rod (7); a moving module (14) is arranged in the arc-shaped groove (3), the moving module (14) penetrates through the arc-shaped groove (3) and is fixedly arranged at the long edge end of the swing rod (7), and the moving module slides in the arc-shaped groove (3) under the driving of the swing rod (7); casing B (5) internally mounted displacement sensor (13), casing A (9) internally mounted battery (16), communication module (17), orientation module (18) and central processing unit (19), displacement sensor (13), communication module (17), orientation module (18) and central processing unit (19) are respectively through battery (16) power supply, and displacement sensor (13), communication module (17) and orientation module (18) are connected with central processing unit (19) again respectively.

2. The dynamic bridge crack monitoring device of claim 1, wherein: casing B (5) and casing A (9) are inside to be equipped with respectively along casing plane direction's corresponding unthreaded hole (11), be equipped with connecting spring (12) in unthreaded hole (11), connecting spring (12) both ends are fixed respectively in unthreaded hole (11) bottom.

3. The dynamic bridge crack monitoring device of claim 1, wherein: the swing rod (7) is divided by the rotating shaft (6), and the length of the long side is 5-10 times of that of the short side.

4. The dynamic bridge crack monitoring device of claim 1, wherein: the long edge end point of the swing rod (7) is movably connected with the shell A (9) through a reset connecting belt (10), and the reset connecting belt (10) is an elastic rubber belt.

5. The dynamic bridge crack monitoring device of claim 1, wherein: the shell B (5) and the shell A (9) are further provided with a supporting seat (15), and the supporting seat (15) is only in contact with the shell B (5) and the shell A (9) and is not connected with the shell A (9).

6. The dynamic bridge crack monitoring device of claim 1, wherein: the positioning module (18) adopts a GPS satellite positioning system or a Beidou satellite positioning system.

7. The dynamic bridge crack monitoring device of claim 1, wherein: the scale is arranged on the edge of the arc-shaped groove (3), and the maximum radian of the arc-shaped groove (3) is 60 degrees.

8. The dynamic bridge crack monitoring device of claim 1, wherein: the edge of the shell B (5) and the edge of the shell A (9) are respectively provided with a mounting flange (4), and the mounting flanges (4) are respectively provided with a plurality of mounting holes.

9. The dynamic bridge crack monitoring device of claim 1, wherein: and a power switch (20) is arranged on the shell A (9).