CN214951515U

CN214951515U - Overload and overturning monitoring and early warning system for single-pier overpass based on comprehensive perception

Info

Publication number: CN214951515U
Application number: CN202121340047.4U
Authority: CN
Inventors: 王立新; 林健富; 赵贤任; 黄剑涛; 胡荣攀; 刘军香; 汪羽凡; 何玉杰
Original assignee: Shenzhen Academy Of Disaster Prevention And Reduction
Current assignee: Shenzhen Academy Of Disaster Prevention And Reduction
Priority date: 2021-06-16
Filing date: 2021-06-16
Publication date: 2021-11-30
Anticipated expiration: 2031-06-16

Abstract

The utility model discloses a single mound overpass overload and toppling monitoring and early warning system based on comprehensive perception, including traffic load monitoring unit, bridge amount of deflection deformation monitoring unit, bridge relative displacement monitoring unit, bridge toppling risk monitoring unit, bridge beam supports counter-force monitoring unit and the terminal equipment that is used for showing and controlling, wherein, traffic load monitoring unit is used for monitoring the load of the traffic vehicle who traveles on the bridge to judge whether the bridge is overloaded according to the load monitored; the bridge deflection deformation monitoring unit is used for monitoring deflection deformation of the bridge; the bridge relative displacement monitoring unit is used for monitoring the change of the relative displacement between the bridge supports, the expansion joints of the bridge deck and the cracks of the bridge; the bridge overturning risk monitoring unit is used for monitoring whether the bridge has an overturning risk; the bridge support reaction monitoring unit is used for monitoring the change of the bridge support reaction. The utility model discloses be applied to bridge technical field.

Description

Overload and overturning monitoring and early warning system for single-pier overpass based on comprehensive perception

Technical Field

The utility model relates to a bridge technical field, concretely relates to monitoring and early warning system that singly mound overpass overloads and topples based on synthesize perception.

Background

For many years, the safety aspects of bridge construction have been a particular concern to the public. The modern large-scale overpass is an important node of an urban traffic main road, has a great influence on the development of urban traffic transportation, and is a symbol of national and regional economic development and technical progress. However, at present, many urban overpasses at home and abroad have hidden dangers of different degrees. The single-column pier overpass is an overpass with only one pier column as a pier under the cross section of the upper structure. The single-pier overpass has the advantages of simple structure, small occupied area, strong adaptability and good economical efficiency, and can be widely built and used in China for decades. However, until now, these single-column pier bridges have obvious potential safety hazards: because the single-column pier structure is supported by a single point, the structure has poor anti-overturning capability; the service time of a large number of single-column pier bridges exceeds 20 years, and as the traffic is increasingly busy during service, the traffic flow exceeds the design value of the current year, and the fatigue damage is rapidly accumulated; part of the bridge is built in unfavorable sections such as soft soil zones, or newly-built underground engineering structures such as subways and tunnels are arranged around the bridge after the bridge is built, so that the bridge has the risk of settlement or inclination under the action of long-term traffic load. In recent years, serious engineering accidents such as bridge collapse, overturn, fracture and collapse are frequently caused, and a great amount of casualties, economic property loss and adverse social effects are caused. For the single-column pier overpass, the overload and unbalance loading of vehicles and the overload and overturn of the bridge caused by disasters such as typhoons, earthquakes and the like are main accident reasons. At present, the following two methods are mainly used for the safety detection method of the running state of the urban overpass: (1) the manual inspection is the most widely used and most important overpass safety detection mode at present. Typically including routine inspection and periodic inspection. The daily inspection interval is day unit, and the inspection personnel only carry basic tools such as rulers, chalks and the like, and observe whether visible cracks, settlement and damage exist on the bridge floor and other exposed structures or whether auxiliary facilities such as railings, street lamps and the like are intact or not by naked eyes. The regular inspection time interval takes years as a unit, and inspectors carry professional instruments to carry out closed detection on the bridge, generally for tens of days, so that the health state of the bridge can be comprehensively inspected. There are several significant drawbacks to manual inspection including: the working efficiency is low, and a great amount of time is usually spent on daily inspection and regular inspection of the bridge; the accuracy is poor, and daily inspection personnel often judge by means of visual and experience, so that the randomness is strong; normal operation is affected, and traffic is often required to be closed for regular inspection; the timeliness is poor, the inspection interval time is long, the inspection is generally carried out according to a plan, and the real-time monitoring on the emergency cannot be carried out in time; and the dynamic monitoring is insufficient, and the operation data beyond the monitoring time cannot be obtained. (2) And an unmanned aerial vehicle and an inspection vehicle are used for replacing manual inspection. Unmanned aerial vehicle can remote control to can reach the region that patrols and examines personnel and be difficult to reach easily and shoot the inspection, the patrolling and examining car of special design then can improve the work efficiency who patrols and examines personnel and improve measurement accuracy through carrying on relevant equipment. But the detection mode is the same as that of manual inspection, the working efficiency is still not high enough, the accuracy is not enough, only external obvious damage can be found, and the defects of poor timeliness and insufficient dynamic monitoring are not changed essentially.

Due to the fact that most urban overpasses lack a structural safety monitoring system, abnormality of the structural state cannot be found in time, corresponding prevention measures cannot be taken in advance, serious accidents of the bridges frequently occur, and large economic loss and adverse social effects are caused. The reasons for bridge accidents are complex, and except for the design and construction reasons, some bridges are in overload operation states for a long time, so that fatigue damage of a plurality of components is aggravated, and the bridge is an important reason for collapse. If the running state of the bridge can be monitored in real time, the dynamic evaluation is given to the health condition of the bridge, and the prevention and reinforcement measures are taken in advance before the catastrophic accident comes, so that the catastrophic loss can be greatly reduced.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

A monitoring and early warning system for overload and overturning of an independent pier overpass based on comprehensive perception solves the technical problems of high potential safety hazard, low working efficiency, low accuracy, low dynamic monitoring and low timeliness of a bridge detection method in the prior art.

(II) technical scheme

In order to solve the technical problem, the utility model provides a single-pier overpass overload and overturning monitoring and early warning system based on comprehensive perception, which comprises a traffic load monitoring unit, a bridge deflection deformation monitoring unit, a bridge relative displacement monitoring unit, a bridge overturning risk monitoring unit, a bridge support counter-force monitoring unit and terminal equipment for displaying and controlling, wherein the traffic load monitoring unit, the bridge deflection deformation monitoring unit, the bridge relative displacement monitoring unit, the bridge overturning risk monitoring unit and the bridge support counter-force monitoring unit are respectively connected with the terminal equipment through the internet of things technology;

the traffic load monitoring unit is used for monitoring the load of traffic vehicles running on the bridge and judging whether the bridge is overloaded or not according to the monitored load; the bridge deflection deformation monitoring unit is used for monitoring deflection deformation of the bridge; the bridge relative displacement monitoring unit is used for monitoring the change of the relative displacement between the bridge supports, the expansion joints of the bridge deck and the cracks of the bridge; the bridge overturning risk monitoring unit is used for monitoring whether the bridge has an overturning risk; the bridge support reaction monitoring unit is used for monitoring the change of the bridge support reaction.

In a further improvement, the bridge deflection deformation monitoring unit comprises a deflectometer and an infrared target, the deflectometer comprises an industrial camera, a data acquisition card, a memory and a first edge calculation module which are assembled together, the industrial camera, the data acquisition card, the memory and the first edge calculation module are electrically connected with the infrared target, the industrial camera is positioned at the top of a bridge pier of the bridge, and the infrared target is positioned at 1/2 spans and 1/4 spans on the bottom surface of each bridge span panel of the bridge;

the first edge computing module is connected with the terminal equipment through the Internet of things technology.

In a further improvement, the first edge computing module is further connected with the snapshot camera, the information display screen and the license plate recognition system respectively through a wired technology or a wireless technology.

The traffic load monitoring unit comprises a weighing sensor and a position tire type sensor which are electrically connected, wherein a second edge calculation module is embedded in the weighing sensor and the position tire type sensor respectively, and the weighing sensor and the position tire type sensor are positioned on a straight section of the upper bridge and avoid a bridge crack and an expansion joint;

and the second edge computing module is connected with the terminal equipment through the Internet of things technology.

In a further improvement, the second edge computing module is further connected with the snapshot camera, the information display screen and the license plate recognition system through wired or wireless technologies respectively.

In a further improvement, the bridge relative displacement monitoring unit is a pull rope type displacement sensor, a third edge calculation module is embedded in the pull rope type displacement sensor, and the third edge calculation module is connected with the terminal equipment through the internet of things technology;

when the pull rope type displacement sensor monitors the change of relative displacement between bridge supports, one end of the pull rope type displacement sensor is installed at the top of a bridge pier, and the other end of the pull rope type displacement sensor is installed at the bottom of a bridge deck;

when the stay rope type displacement sensor monitors the bridge deck expansion joint, two ends of the stay rope type displacement sensor are respectively arranged at two sides of the expansion joint at the bottom of the bridge deck;

when the pull rope type displacement sensor monitors the crack of the bridge, two ends of the pull rope type displacement sensor are respectively installed on two side wall surfaces of the crack.

In a further improvement, the bridge overturning risk monitoring unit comprises at least one pair of thimble-type displacement sensors, a fourth edge calculation module is embedded in each thimble-type displacement sensor, and the fourth edge calculation module is connected with the terminal equipment through the internet of things technology;

each pair of thimble type displacement sensors comprises two thimble type displacement sensors, and the two thimble type displacement sensors in the same pair are respectively positioned at two sides of a bridge pier of the bridge.

Further improved, the counter-force monitoring unit is a force sensor, a fifth edge calculation module is embedded in the force sensor, the force sensor is installed at the joint of the bridge bearing and the bridge pier, and the fifth edge calculation module is connected with the terminal equipment through the internet of things technology.

(III) advantageous effects

When the traffic vehicles pass through the bridge, the traffic load monitoring unit measures the load of the traffic vehicles passing through the bridge and monitors whether the bridge is overloaded or not in real time. Due to the fact that the bridge bears the load of the vehicle, deflection deformation of the bridge can occur, relative displacement between bridge supports can become large, cracks can become large, and even the risk of overturning can occur. Therefore, the utility model discloses in, the amount of deflection of bridge warp deformation monitoring unit can monitor the amount of deflection of bridge warp and warp the monitoring unit and set up first early warning value in the bridge amount of deflection, if the amount of deflection of monitoring the bridge warp and exceed first early warning value, then terminal equipment sends first alarm signal, if the amount of deflection of not monitoring the bridge warp and exceed first early warning value, then terminal equipment does not send first alarm signal. The bridge relative displacement monitoring unit can monitor the change of the relative displacement between the bridge supports, the expansion joints of the bridge deck and the cracks of the bridge in real time; the bridge overturning risk monitoring unit can monitor the bridge overturning risk in time, and potential safety hazards are avoided. The bridge support reaction monitoring unit is used for monitoring the change of the bridge support reaction, mastering the actual change state of the bridge and guiding the maintenance in the operation stage. The monitoring information can be viewed in real time on the terminal device. The utility model discloses a monitoring and early warning system that singly mound overpass overloads based on comprehensive perception passes through traffic load monitoring unit, bridge amount of deflection deformation monitoring unit, bridge relative displacement monitoring unit, bridge topples risk monitoring unit, bridge beam supports counter-force monitoring unit's mutually supporting, can monitor the many-sided, multidimension of bridge, has improved the accuracy of bridge monitoring, all-weather automatic work, need not the special messenger and guard on duty, work efficiency is high, can realize dynamic monitoring; the bridge can continuously provide data in work, the data is monitored and recorded at intervals of seconds or minutes, the data can be inquired in a database at any time, the timeliness is high, and the bridge operation is not influenced; and the structure is simple, and the cost is lower.

Drawings

Fig. 1 is a schematic structural diagram of an overload and overturning monitoring and early warning system of a single-pier overpass based on comprehensive perception according to an embodiment of the present invention;

fig. 2 is an embodiment of the present invention, in which a first warning value is obtained from a schematic diagram.

Detailed Description

The following detailed description of the embodiments of the present invention is provided with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

Referring to fig. 1 to 2, the monitoring and early warning system for overload and overturning of the single-pier overpass based on comprehensive perception comprises a traffic load monitoring unit, a bridge deflection deformation monitoring unit, a bridge relative displacement monitoring unit, a bridge overturning risk monitoring unit, a bridge support reaction monitoring unit and terminal equipment for displaying and controlling, wherein the traffic load monitoring unit, the bridge deflection deformation monitoring unit, the bridge relative displacement monitoring unit, the bridge overturning risk monitoring unit and the bridge support reaction monitoring unit are respectively connected with the terminal equipment through the internet of things technology;

When the traffic vehicles pass through the bridge, the traffic load monitoring unit measures the load of the traffic vehicles passing through the bridge and monitors whether the bridge is overloaded or not in real time. As the bridge bears the load of traffic vehicles, the bridge can generate deflection deformation, the relative displacement between bridge supports can become large, cracks can become large, and even the risk of overturning can occur. Therefore, in this embodiment, the bridge deflection deformation monitoring unit may monitor deflection deformation of the bridge, set a first warning value in the terminal device, if the deflection deformation of the bridge is monitored to exceed the first warning value, the terminal device sends out a first warning signal, and if the deflection deformation of the bridge is not monitored to exceed the first warning value, the terminal device does not send out the first warning signal. The bridge relative displacement monitoring unit can monitor the change of the relative displacement between the bridge supports, the expansion joints of the bridge deck and the cracks of the bridge in real time; the bridge overturning risk monitoring unit can monitor the bridge overturning risk in time, and potential safety hazards are avoided. The bridge support reaction monitoring unit is used for monitoring the change of the bridge support reaction, mastering the actual change state of the bridge and guiding the maintenance in the operation stage. The monitoring information can be checked on the terminal device in real time, specifically, the terminal device is a mobile phone or a computer, and the like, and also can be other devices capable of realizing the functions in the embodiment. The terminal equipment is respectively communicated and controlled with the traffic load monitoring unit, the bridge deflection deformation monitoring unit, the bridge relative displacement monitoring unit, the bridge overturning risk monitoring unit and the bridge support reaction monitoring unit through a 5G/4G wireless communication technology. The monitoring and early warning system for overload and overturning of the single-pier overpass based on comprehensive perception can monitor multiple aspects and multiple dimensions of the bridge through the mutual matching of the traffic load monitoring unit, the bridge deflection deformation monitoring unit, the bridge relative displacement monitoring unit, the bridge overturning risk monitoring unit and the bridge support counterforce monitoring unit, and improves the accuracy of bridge monitoring. The all-weather automatic monitoring system can automatically work all weather, does not need special person to watch, has high working efficiency and can realize dynamic monitoring; the bridge can continuously provide data in work, the data is monitored and recorded at intervals of seconds or minutes, the data can be inquired in a database at any time, the timeliness is high, and the bridge operation is not influenced; and the structure is simple, and the cost is lower.

Overloading vehicles or accidents can cause the bridge girder to deform greatly in the vertical direction, and monitoring the deflection of the girder helps to evaluate the structural reliability of the bridge under the action of extreme loads. Further, in an embodiment, the bridge deflection deformation monitoring unit includes a deflectometer 1 and an infrared target 2, the deflectometer 1 includes an industrial camera, a data acquisition card, a memory and a first edge calculation module which are assembled together, the industrial camera, the data acquisition card, the memory and the first edge calculation module are electrically connected with the infrared target 2, the industrial camera is located at the top of a bridge pier of the bridge, the infrared target 2 is located in the middle of the bottom of each bridge span panel of the bridge, the infrared target 2 is respectively installed at target measuring points such as 1/2 and 1/4 bridge span the bottom of a longitudinal beam to monitor the dynamic deflection of the main beam, and the dynamic sampling frequency of the deflectometer 1 can be up to 1 Hz;

The industrial camera, the data acquisition card, the memory and the first edge calculation module in the dynamic deflectometer 1 are packaged and integrated together, the dynamic deflectometer 1 carries out deflectometry by adopting a mode of placing the industrial camera on the top of a pier and placing the infrared target 2 in a midspan manner, edge calculation is carried out through the first edge calculation module, data acquired by the industrial camera and the infrared target 2 are analyzed, and data transmission pressure is greatly reduced; and only the analysis result of the bridge safety state is finally transmitted to the user, so that the use threshold of the user is reduced. The dynamic deflectometer 1 can effectively express the dynamic response of the travelling crane on the overpass. Because the dynamic deflectometer 1 is internally provided with the data acquisition card and the memory, the dynamic deflectometer 1 also has a certain data storage function, and the time history of the bridge mid-span deflection can be obtained. By analyzing the deflection time-course data, the dynamic deflection of the bridge can be monitored, the function of counting the flow of the overloaded vehicle is achieved, and an alarm is given when the deflection exceeds a first early warning value. There are three ways to select the first warning value of overload: (1) obtaining a first early warning value based on the existing specification, namely calculating the span l/600 as an element of a first early warning value alternative set by JTG D62-2004/JTG D62-2018; (2) obtaining a first early warning value based on the worst loading working condition, namely calculating the peak value of the vertical deflection of the bridge span under the condition of full load/parallel of two vehicles according to truck overload management regulations, and bringing the peak value into a first early warning value alternative set; (3) and obtaining a first early warning value based on dynamic deflection data statistical analysis, namely counting the historical peak value of the dynamic deflection obtained by measurement, and selecting the deflection value of which the number of samples is 0.90 or 0.95 quantiles to be included in a first early warning value alternative set. The dynamic deflection sensor unit is connected with the snapshot camera, when a heavy vehicle passes by, the dynamic deflection of the bridge is increased to exceed a first early warning value, the snapshot camera is controlled to snapshot, and a basis is provided for managing and maintaining the overpass. The dynamic deflection deformation monitoring of the bridge is carried out by using the dynamic deflection meter 1, the sampling frequency is high, and the time history data of the bridge deflection can be obtained for carrying out traffic flow statistics.

Further, in an embodiment, the first edge computing module is further connected to the snapshot camera, the information display screen 4, and the license plate recognition system 5 through wired or wireless technologies, respectively. The license plate recognition system 5 is used for recognizing the license plate of the vehicle, the information display screen 4 is used for displaying the information of the vehicle, and the snapshot camera 3 is used for snapshot of the vehicle.

Further, in an embodiment, the traffic load monitoring unit includes a weighing sensor 6 and a position matrix sensor 7 that are electrically connected, a second edge calculation module is embedded in each of the weighing sensor 6 and the position matrix sensor 7, and the weighing sensor 6 and the position matrix sensor 7 are respectively located at a straight section of the upper bridge and avoid a bridge crack and an expansion joint;

and the second edge computing module is connected with the terminal equipment through the Internet of things technology. The weighing sensor 6 and the position tire type sensor 7 can obtain information such as single axle weight, axle number, total vehicle weight, axle distance, vehicle length, vehicle type, chassis frequency, vehicle speed, acceleration, tire number, license plate number, vehicle picture and the like of each vehicle, and the second edge calculation module can carry out edge calculation design and integrates the functions of the weighing sensor 6, the position tire type sensor 7, data acquisition, data transmission and certain data storage and analysis. The weighing sensor 6 and the position fetal type sensor 7 can directly demodulate locally after acquiring the original data, store the original data together with historical data for a period of time, process the data by a calculation analysis module of the processing platform, and send the processing result to the terminal equipment, and the final user only needs to analyze whether the bridge is safe or not, so that the pressure of data transmission is greatly reduced, and the use threshold of the user is reduced; when the user needs, the traffic load monitoring unit can be accessed to obtain the original data.

Further, in an embodiment, the second edge calculation module is further connected to the snapshot camera, the information display screen 4, and the license plate recognition system 5 through wired or wireless technologies, respectively.

Further, in an embodiment, the bridge relative displacement monitoring unit is a pull rope type displacement sensor 8, a third edge calculation module is embedded in the pull rope type displacement sensor 8, and the third edge calculation module is connected with the terminal device through the internet of things technology;

when the pull rope type displacement sensor 8 monitors the change of the relative displacement between the bridge supports, one end of the pull rope type displacement sensor 8 is installed at the top of a bridge pier of the bridge, and the other end of the pull rope type displacement sensor 8 is installed at the bottom of a bridge deck;

when the stay rope type displacement sensor 8 monitors the bridge deck expansion joint, two ends of the stay rope type displacement sensor 8 are respectively installed at two sides of the expansion joint at the bottom of the bridge deck;

when the pull rope type displacement sensor 8 monitors the crack of the bridge, two ends of the pull rope type displacement sensor 8 are respectively installed on two side wall surfaces of the crack.

The bridge relative displacement monitoring unit can monitor longitudinal and transverse relative displacement between beam piers, bridge deck expansion joints and cracks. The data are collected through the pull rope type displacement sensor 8, the data are primarily processed and analyzed through the third edge computing module, the processing result is sent to the terminal equipment, and the final user only needs to receive the analysis result of whether the bridge is safe or not, so that the pressure of data transmission is greatly reduced, and the use threshold of the user is reduced; when a user needs the method, the bridge relative displacement monitoring unit can be accessed to acquire original data.

Further, in an embodiment, the bridge overturning risk monitoring unit includes at least one pair of thimble-type displacement sensors 9, a fourth edge calculation module is embedded in each thimble-type displacement sensor 9, and the fourth edge calculation module is connected with the terminal device through the internet of things technology;

each pair of the thimble type displacement sensors 9 comprises two thimble type displacement sensors 9, and the two thimble type displacement sensors 9 in the same pair are respectively positioned at two sides of a bridge pier of the bridge.

The bridge overturning risk monitoring unit for monitoring bridge overturning comprises the following steps:

the two ejector pin type displacement sensors 9 in the same pair respectively measure the vertical heights h1 and h2 at two sides of the pier, and h1-h2 are dh, if dh exceeds a second early warning value, it is judged that a support is possible to be empty, the bridge has the risk of overturning and turning on one side, and the terminal equipment sends out a second warning signal. The second early warning value is obtained according to a plurality of tests and the like.

And if the deflection deformation of the bridge is not monitored to exceed the second early warning value, the terminal equipment does not send out a second warning signal.

Further, in an embodiment, the reaction force monitoring unit is a force sensor 10, a fifth edge calculation module is embedded in the force sensor 10, the force sensor 10 is installed at a joint between a bridge support and a pier, and the fifth edge calculation module is connected with a terminal device through the internet of things technology.

A force sensor 10 is installed at the joint of a bridge bearing and a bridge pier, so that the change of the reaction force of the bearing can be monitored in real time, and the health state of the bridge pier bearing can be judged. Bridge bearings are important structural components that connect the superstructure and substructure of a bridge. In the operation stage of the bridge, settlement of different degrees can occur in a lower structure or large relative displacement occurs between an upper beam structure and a lower supporting structure, so that difference occurs between the distribution condition of the counter force of the support and a theoretical value, and the theoretical jacking force is inconsistent with the actually required jacking force. Due to the influence of the uncertain factors, the stress state of the structure can be changed after the beam body generates additional stress, and the structure is damaged, cracked or even destroyed. Therefore, the support reaction force is monitored, the actual change state of the bridge is grasped, and the support reaction force can be used for guiding maintenance in the operation stage.

In this embodiment, specifically, the first edge calculation module, the second edge calculation module, the third edge calculation module, the fourth edge calculation module, and the fifth edge calculation module are respectively embedded in each sensor, and each sensor adopts an edge calculation design, and integrates the sensor, data acquisition, data transmission, and certain data storage and analysis functions. After the sensor acquires the original data, the sensor can directly perform primary data processing and analysis on a calculation and analysis module at the sensor end, and sends a processing result to the terminal equipment, and the final user only needs to receive an analysis result of whether the bridge is safe or not, so that the pressure of data transmission and a large amount of resources consumed by central calculation are greatly reduced. Obviously, the distributed data analysis can be conveniently performed by adopting the sensor with the edge computing capability, so that the data analysis efficiency is greatly improved.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims

1. A monitoring and early warning system for overload and overturning of a single-pier overpass based on comprehensive perception is characterized by comprising a traffic load monitoring unit, a bridge deflection deformation monitoring unit, a bridge relative displacement monitoring unit, a bridge overturning risk monitoring unit, a bridge support counterforce monitoring unit and terminal equipment for displaying and controlling, wherein the traffic load monitoring unit, the bridge deflection deformation monitoring unit, the bridge relative displacement monitoring unit, the bridge overturning risk monitoring unit and the bridge support counterforce monitoring unit are respectively connected with the terminal equipment through the Internet of things technology;

2. The overload and overturn monitoring and early warning system for the single-pier overpass based on the comprehensive perception according to claim 1, wherein the bridge deflection deformation monitoring unit comprises a deflectometer and an infrared target, the deflectometer comprises an industrial camera, a data acquisition card, a memory and a first edge calculation module which are assembled together, the industrial camera, the data acquisition card, the memory and the first edge calculation module are electrically connected with the infrared target, the industrial camera is positioned at the top of a bridge pier of the bridge, and the infrared target is positioned at 1/2 spans and 1/4 spans on the bottom surface of each bridge span panel of the bridge;

3. The system for monitoring and early warning overload and overturning of the single-pier overpass based on comprehensive perception according to claim 2, wherein the first edge computing module is further connected with the snapshot camera, the information display screen and the license plate recognition system through a wired technology or a wireless technology respectively.

4. The system for monitoring and early warning overload and overturning of the single-pier overpass based on the comprehensive perception according to claim 1, wherein the traffic load monitoring unit comprises a weighing sensor and a position matrix sensor which are electrically connected, the weighing sensor and the position matrix sensor are respectively embedded with a second edge calculation module, and the weighing sensor and the position matrix sensor are respectively positioned at a straight section of the upper bridge and avoid a bridge crack and an expansion joint;

5. The system for monitoring and early warning overload and overturning of the single-pier overpass based on comprehensive perception according to claim 4, wherein the second edge computing module is further connected with the snapshot camera, the information display screen and the license plate recognition system through wired or wireless technologies respectively.

6. The overload and overturn monitoring and early warning system for the single-pier overpass based on the comprehensive perception according to any one of claims 1 to 5, wherein the bridge relative displacement monitoring unit is a pull rope type displacement sensor, a third edge calculation module is embedded in the pull rope type displacement sensor, and the third edge calculation module is connected with a terminal device through the technology of Internet of things;

7. The overload and overturn monitoring and early warning system for the single-pier overpass based on the comprehensive perception according to any one of claims 1 to 5, wherein the bridge overturn risk monitoring unit comprises at least one pair of thimble-type displacement sensors, a fourth edge calculation module is embedded in each thimble-type displacement sensor, and the fourth edge calculation module is connected with a terminal device through the internet of things technology;

8. The overload and overturn monitoring and early warning system for the single-pier overpass based on the comprehensive perception according to any one of claims 1 to 5, wherein the counter force monitoring unit is a force sensor, a fifth edge calculation module is embedded in the force sensor, the force sensor is installed at the joint of a bridge support and a pier, and the fifth edge calculation module is connected with a terminal device through the technology of Internet of things.