CN219798326U - Bridge deformation inclination sensing device - Google Patents

Abstract

The utility model discloses a bridge deformation inclination sensing device, which comprises at least one bridge deformation inclination sensing mechanism, wherein the bridge deformation inclination sensing mechanism comprises a main body and a power supply assembly, an inclination monitoring assembly is arranged in the main body, and the power supply assembly supplies power to the inclination monitoring assembly through an electric energy transmission line; the inclination monitoring assembly comprises a data conversion circuit and a monitoring tank body fixedly connected with the main body, wherein a solution to be sensed is arranged in the monitoring tank body, a plurality of liquid level sensors are further arranged on the inner side wall of the monitoring tank body along the circumferential direction, each liquid level sensor is in contact with the solution to be sensed, the liquid level sensors are further in data connection with the data conversion circuit, and liquid level information of the solution to be sensed at corresponding positions is collected and sent to the data conversion circuit. The deformation condition of bridge can be sensed in real time by the scheme.

Description

Bridge deformation inclination sensing device

Technical Field

The utility model relates to the technical field of bridge monitoring, in particular to a bridge deformation inclination sensing device.

Background

Bridge engineering is an important and critical engineering for traffic construction. Along with the development of traffic construction and the progress of science and technology, the construction of bridge engineering is rapidly developed. More common are cable-stayed bridges, arch bridges, suspension bridges, beam bridges. At present, accidents caused by the problems of bridge overturning, larger bridge deformation and the like frequently occur endlessly.

At present, the deformation condition of a bridge is generally measured through a total station, namely a total station type electronic distance meter (Electronic Total Station), which is a high-technology measuring instrument integrating light, a machine and electricity, and is a surveying instrument system integrating the functions of measuring horizontal angle, vertical angle, distance (inclined distance and flat distance) and height difference. Compared with an optical theodolite, the electronic theodolite changes the optical dial into a photoelectric scanning dial, and replaces manual optical micrometer reading with automatic recording and displaying reading, so that the angle measurement operation is simplified, and reading errors can be avoided. The total station is called because it can complete all the measurement work on the station by setting the instrument at one time. The method is widely applied to the fields of precision engineering measurement or deformation monitoring such as ground large-scale building and underground tunnel construction. However, when the bridge deformation condition is measured by using the total station, the bridge deformation value cannot be measured in real time, and thus the bridge deformation condition cannot be mastered in real time.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model aims to solve the technical problems that: how to provide a bridge deformation inclination sensing device capable of sensing the deformation condition of a bridge in real time.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the bridge deformation inclination sensing device comprises at least one bridge deformation inclination sensing mechanism, wherein the bridge deformation inclination sensing mechanism comprises a main body and a power supply assembly, an inclination monitoring assembly is arranged in the main body, and the power supply assembly supplies power to the inclination monitoring assembly through an electric energy transmission line; the inclination monitoring assembly comprises a data conversion circuit and a monitoring tank body fixedly connected with the main body, wherein a solution to be sensed is arranged in the monitoring tank body, a plurality of liquid level sensors are further arranged on the inner side wall of the monitoring tank body along the circumferential direction, each liquid level sensor is in contact with the solution to be sensed, the liquid level sensors are further in data connection with the data conversion circuit, and liquid level information of the solution to be sensed at corresponding positions is collected and sent to the data conversion circuit.

In this scheme, initial state is the state when bridge deformation slope sensing device level was placed.

The working principle of the utility model is as follows: the bridge deformation inclination sensing device of this scheme is when using, install the main part on waiting to detect the bridge of deformation position, like this make bridge deformation inclination sensing device and bridge between have the same motion trend, when the bridge appears deforming and take place the slope, the main part will follow the bridge slope, wait to sense the position of solution in the monitoring jar body and will change, and a plurality of liquid level sensor that follow circumference distribution on the monitoring jar body will gather the liquid level information of corresponding position and wait to sense the solution, and send this liquid level information to data conversion circuit, the liquid level information that each liquid level sensor gathered is obtained to data conversion circuit. Because be equipped with a plurality of liquid level sensor on the inside wall of the monitoring jar body, when waiting to sense the position of solution in the monitoring jar body to change like this, the liquid level information of waiting to sense the solution that each liquid level sensor gathered compares when comparing with initial state all will change, from this scheme just can the real-time deformation slope condition of sensing bridge.

Preferably, a front liquid level sensor, a left liquid level sensor, a rear liquid level sensor and a right liquid level sensor are sequentially arranged on the inner side wall of the monitoring tank body along the circumferential direction, and the initial liquid level of the solution to be sensed is located at the middle position of each liquid level sensor.

In this way, through setting up front liquid level sensor, back liquid level sensor, left liquid level sensor and right liquid level sensor, and each liquid level sensor can discern the liquid level of waiting to sense solution and air juncture to judge the liquid level of waiting to sense solution, discern the initial liquid level of solution and lie in the centre of the liquid level sensor, when the pier appears inclining, the bridge warp the slope sensing device too along with inclining, therefore wait to sense solution and air juncture liquid level information change too, liquid level sensor, front liquid level sensor discerned wait to sense solution and air juncture liquid level information judge the inclination of the bridge fore-and-aft direction; and judging the inclination of the bridge in the left-right direction according to the liquid level information of the boundary position between the solution to be sensed and the air, which is recognized by the left liquid level sensor and the right liquid level sensor, wherein the larger the liquid level difference between the two sides of the recognition position is, the larger the inclination of the bridge is represented.

Preferably, the bridge deformation inclination sensing device further comprises a signal receiving mechanism, the bridge deformation inclination sensing mechanism further comprises a signal transmitting assembly arranged in the main body, the power supply assembly supplies power to the signal receiving mechanism and the signal transmitting assembly through power transmission lines respectively, the signal transmitting assembly comprises a signal transmitting part, a signal transmitting head and a signal transmitting circuit, the signal transmitting circuit is in data connection with a conversion data output end of the data conversion circuit, the signal transmitting head is connected with the signal transmitting part and stretches out of the main body, and the signal receiving mechanism is located on a signal transmitting path of the signal transmitting head so as to receive a position signal from the signal transmitting head.

In this way, when deformation monitoring is required to be carried out on a plurality of positions of the bridge, the bridge deformation inclination sensing mechanisms are installed at each corresponding position, then the signal receiving mechanisms are installed at the middle positions of the bridge, the liquid level information in each bridge deformation inclination sensing mechanism is converted by the data conversion circuit and then is sent to the signal transmitting circuit of the signal transmitting assembly, and the signal transmitting paths of the signal transmitting heads in each bridge deformation inclination sensing mechanism are all passed through the signal receiving mechanisms, so that the signal transmitting heads in the corresponding signal transmitting assemblies transmit signals to the signal receiving mechanisms when the bridge deformation inclination sensing mechanisms work, the signal receiving mechanisms receive the transmitting signals of the signal transmitting heads to provide a data basis for judging the positions of the signal transmitting heads, and the deformation data of each position of the bridge can be accurately obtained.

Preferably, the signal transmitting assembly further comprises a signal transmitting tank body, the signal transmitting tank body is fixed in the main body, and the signal transmitting component is fixed in the signal transmitting tank body.

Thus, the signal transmitting part is fixed by the signal transmitting tank body.

Preferably, the signal receiving mechanism comprises a signal receiving tank body and a signal identification data transmission assembly, the signal receiving tank body is internally provided with a signal identification assembly and a signal identification electric energy storage assembly, the signal identification electric energy storage assembly is electrically connected with the power supply assembly so as to supply power to the signal identification electric energy storage assembly through the power supply assembly, the signal identification electric energy storage assembly is also electrically connected with the signal identification assembly and the signal identification data transmission assembly through electric energy transmission lines respectively so as to supply power to the signal identification assembly and the signal identification data transmission assembly respectively, and the signal identification assembly is in data connection with the signal identification data transmission assembly.

Thus, when the signal receiving mechanism works, the signal identification electric energy storage component supplies power for the signal identification component and the signal identification data transmission component, the signal identification component is used for receiving signals of the signal transmitting head and then sending the received signals to the signal identification data transmission component, and the signal identification data transmission component can further transmit data to external data processing equipment for processing.

Preferably, the bridge deformation inclination sensing mechanism further comprises an inclination monitoring data transmission assembly, wherein the inclination monitoring data transmission assembly is in data connection with the data conversion circuit, and the power supply assembly supplies power to the inclination monitoring data transmission assembly through an electric energy transmission line.

In this way, the data conversion circuit converts the received liquid level data information of each liquid level sensor into a data format and then further transmits the data to the inclination monitoring data transmission assembly, and the inclination monitoring data transmission assembly can further transmit the data to external data processing equipment for further processing.

Preferably, the power supply assembly comprises an electric energy storage component and a plurality of solar panels, wherein one solar panel is electrically connected with the signal recognition electric energy storage component through an electric energy transmission line, the signal recognition electric energy storage component converts solar energy into electric energy and supplies power for the signal recognition component and the signal recognition data transmission component, the rest solar panels are supplied with power through the electric energy transmission line and the electric energy storage component, and the electric energy storage component converts the solar energy into electric energy and respectively supplies power for the inclination monitoring component and the signal transmission component through the electric energy transmission line.

In this way, solar energy is provided for the electric energy storage component and the signal recognition electric energy storage component through the solar panel, and then the electric energy storage component and the signal recognition electric energy storage component convert the solar energy into electric energy to supply power for all electric equipment.

Preferably, the solar panel for supplying power to the electric energy storage component comprises an upper solar panel, a middle solar panel and a lower solar panel, wherein the upper solar panel, the middle solar panel and the lower solar panel are arranged on the outer side of the bridge pier, and the solar panel for supplying power to the signal recognition electric energy storage component is arranged in the middle of the bridge.

Preferably, the bridge deformation inclination sensing device comprises two bridge deformation inclination sensing mechanisms, the two bridge deformation inclination sensing mechanisms are respectively arranged on bridge piers on two sides of a bridge, the signal receiving mechanism is arranged at the middle position of the bridge, and the signal receiving mechanism is arranged on a signal transmitting path of the signal transmitting head in the two bridge deformation inclination sensing mechanisms.

Drawings

FIG. 1 is an interior elevation view of a bridge deformation tilt sensing apparatus of the present utility model;

FIG. 2 is an interior side view of the bridge deformation tilt sensing device of the present utility model;

FIG. 3 is a top view of the bridge deformation tilt sensing device of the present utility model;

FIG. 4 is a detailed view of the bridge deformation inclination sensing device according to the present utility model when inclined;

FIG. 5 is a schematic diagram of a signal receiving mechanism in the bridge deformation and inclination sensing device according to the present utility model;

FIG. 6 is a schematic diagram showing the installation of the bridge deformation and inclination sensing device on a bridge.

Reference numerals illustrate: the device comprises a main body 1, an electric energy transmission line 2, a data conversion circuit 3, a front liquid level sensor 4, a rear liquid level sensor 5, a left liquid level sensor 6, a right liquid level sensor 7, a monitoring tank 8, a signal transmitting part 9, a signal transmitting head 10, a signal transmitting circuit 11, a signal transmitting tank 12, a signal receiving tank 13, a signal identifying component 14, a signal identifying electric energy storage component 15, a signal identifying data transmission component 16, an electric energy storage part 17, a signal identifying solar panel 18, an upper solar panel 19, a middle solar panel 20, a lower solar panel 21, a circular level 22, an inclination monitoring data transmission component 23, a solution to be sensed 24, a bridge 25 and a bridge pier 26.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which can be made by a person skilled in the art without creative efforts, based on the described embodiments of the present utility model fall within the protection scope of the present utility model. Unless defined otherwise, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this utility model belongs.

The terms "first," "second," and the like in the description and in the claims, are not used for any order, quantity, or importance, but are used for distinguishing between different elements. Also, unless the context clearly indicates otherwise, singular forms "a," "an," or "the" and similar terms do not denote a limitation of quantity, but rather denote the presence of at least one. The terms "comprises," "comprising," or the like are intended to cover a feature, integer, step, operation, element, and/or component recited as being present in the element or article that "comprises" or "comprising" does not exclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. "up", "down", "left", "right" and the like are used only to indicate a relative positional relationship, and when the absolute position of the object to be described is changed, the relative positional relationship may be changed accordingly.

As shown in fig. 1 to 6, a bridge deformation and inclination sensing device comprises at least one bridge deformation and inclination sensing mechanism, wherein the bridge deformation and inclination sensing mechanism comprises a main body 1 and a power supply assembly, an inclination monitoring assembly is arranged in the main body 1, and the power supply assembly supplies power to the inclination monitoring assembly through an electric energy transmission line 2; the inclination monitoring assembly comprises a data conversion circuit 3 and a monitoring tank body 8 fixedly connected with the main body 1, a solution 24 to be sensed is arranged in the monitoring tank body 8, a plurality of liquid level sensors are further arranged on the inner side wall of the monitoring tank body 8 along the circumferential direction, each liquid sensor is in contact with the solution 24 to be sensed, the liquid level sensors are further in data connection with the data conversion circuit 3, and liquid level information of the solution 24 to be sensed at corresponding positions is collected and sent to the data conversion circuit 3. Wherein the main body 1 and the monitoring tank body 8 are both made of waterproof and anti-corrosion steel materials, and a round level 22 is further arranged at the top of the main body 1 to ensure the level of an initial state.

In this scheme, initial state is the state when bridge deformation slope sensing device level was placed. The liquid level sensor is used for collecting the liquid level information of the solution and belongs to the prior art, and meanwhile, the data conversion circuit 3 adopts a circuit which can convert the liquid level signal of the liquid level sensor into a digital signal in the prior art, so that the scheme is not repeated for the specific structure of the data conversion circuit 3.

The working principle of the utility model is as follows: according to the bridge deformation inclination sensing device, when the bridge deformation inclination sensing device is used, the main body 1 is arranged on the bridge 25 at the deformation position to be detected, so that the bridge deformation inclination sensing device and the bridge 25 have the same movement trend, when the bridge 25 is inclined due to deformation, the main body 1 inclines along with the bridge 25, the position of a solution 24 to be sensed in the monitoring tank body 8 changes, a plurality of liquid level sensors distributed on the monitoring tank body 8 along the circumferential direction collect liquid level information of the solution 24 to be sensed at corresponding positions, the liquid level information is sent to the data conversion circuit 3, and the data conversion circuit 3 acquires the liquid level information collected by each liquid level sensor. Because be equipped with a plurality of liquid level sensor on the inside wall of the monitoring jar body 8, when the position of waiting to sense solution 24 in the monitoring jar body 8 changes like this, the liquid level information of waiting to sense solution 24 that each liquid level sensor gathered compares when comparing with initial condition all changes, from this scheme just can the real-time sensing bridge 25 warp the slope condition. When the bridge 25 deformation detection device is particularly used, after the liquid level information acquired by each liquid level sensor acquired by the data conversion circuit 3 can be subjected to data format conversion, the liquid level information can be further transmitted to external data processing equipment for terminal analysis, for example, the liquid level information can be transmitted to an external computer for data analysis to acquire the deformation condition of the bridge 25 in real time, and the liquid level information can also be transmitted to an external mobile phone end for convenient checking and the like.

In this embodiment, a front liquid level sensor 4, a left liquid level sensor 6, a rear liquid level sensor 5 and a right liquid level sensor 7 are sequentially provided on the inner side wall of the monitoring tank 8 along the circumferential direction, and the initial liquid level of the solution 24 to be sensed is located at the middle position of each liquid level sensor.

In this way, by arranging the front liquid level sensor 4, the rear liquid level sensor 5, the left liquid level sensor 6 and the right liquid level sensor 7, each liquid level sensor can identify the boundary position between the to-be-sensed solution 24 and the air to judge the liquid level of the to-be-sensed solution 24, the initial liquid level of the to-be-sensed solution is identified to be positioned in the middle of the liquid level sensor, when the bridge pier 26 tilts, the bridge 25 deforms and the tilt sensing device tilts along with the tilting, so that the liquid level information of the boundary position between the to-be-sensed solution 24 and the air also changes, and then the liquid level information of the boundary position between the to-be-sensed solution 24 and the air identified by the liquid level sensor 5 and the front liquid level sensor 4 judges the inclination of the bridge 25 in the front-rear direction; the inclination of the bridge 25 in the left-right direction is determined by the liquid level information of the boundary position between the solution 24 to be sensed and the air, which is recognized by the left liquid level sensor 6 and the right liquid level sensor 7 (as shown in fig. 4), and the larger the liquid level difference between the two sides of the recognition position is, the larger the inclination of the bridge 25 is represented.

In this embodiment, the bridge deformation inclination sensing device further includes a signal receiving mechanism, the bridge deformation inclination sensing mechanism further includes a signal transmitting component disposed in the main body 1, the power supply component supplies power to the signal receiving mechanism and the signal transmitting component through the power transmission line 2, the signal transmitting component includes a signal transmitting part 9, a signal transmitting head 10 and a signal transmitting circuit 11, the signal transmitting circuit 11 is in data connection with a conversion data output end of the data conversion circuit 3, the signal transmitting head 10 is connected with the signal transmitting part 9 and extends out of the main body 1, and the signal receiving mechanism is located on a signal transmitting path of the signal transmitting head 10 to receive a position signal from the signal transmitting head 10.

In this way, when deformation monitoring is required to be performed on a plurality of positions of the bridge 25 by arranging the signal receiving mechanism and the signal transmitting assembly, the bridge deformation inclination sensing mechanism is arranged at each corresponding position, then the signal receiving mechanism is arranged at the middle position of the bridge 25, the data conversion circuit 3 in each bridge deformation inclination sensing mechanism converts the liquid level information and then sends the liquid level information to the signal transmitting circuit 11 of the signal transmitting assembly, and the signal transmitting paths of the signal transmitting heads 10 in each bridge deformation inclination sensing mechanism pass through the signal receiving mechanism, so that when each bridge deformation inclination sensing mechanism works, the signal transmitting heads 10 in the corresponding signal transmitting assembly transmit signals to the signal receiving mechanism, and the signal receiving mechanism receives the transmitting signals of each signal transmitting head 10 to provide a data basis for judging the position of the signal transmitting head 10, and the deformation data of each position of the bridge 25 can be accurately obtained.

In this embodiment, the signal transmitting assembly further includes a signal transmitting can 12, the signal transmitting can 12 is fixed in the main body 1, and the signal transmitting part 9 is fixed in the signal transmitting can 12. The signal transmitting can 12 is made of waterproof and corrosion-resistant steel.

In this way, the signal transmitting member 9 is fixed by the signal transmitting can 12.

In this embodiment, the signal receiving mechanism includes a signal receiving tank 13 and a signal identifying data transmitting component 16, a signal identifying component 14 and a signal identifying electric energy storing component 15 are disposed in the signal receiving tank 13, the signal identifying electric energy storing component 15 is electrically connected with the power supplying component to supply power to the signal identifying electric energy storing component 15 through the power supplying component, and the signal identifying electric energy storing component 15 is also electrically connected with the signal identifying component 14 and the signal identifying data transmitting component 16 through the electric energy transmitting line 2 respectively to supply power to the signal identifying component 14 and the signal identifying data transmitting component 16 respectively, and the signal identifying component 14 is in data connection with the signal identifying data transmitting component 16. The signal receiving tank 13 is made of waterproof and corrosion-resistant steel.

Thus, in operation of the signal receiving mechanism, the signal recognition electric energy storage component 15 supplies power to the signal recognition component 14 and the signal recognition data transmission component 16, the signal recognition component 14 is used for receiving the signal of the signal transmitting head 10, and then sending the received signal to the signal recognition data transmission component 16, and the signal recognition data transmission component 16 can further transmit the data to an external data processing device for processing.

In this embodiment, the bridge deformation inclination sensing mechanism further includes an inclination monitoring data transmission component 23, the inclination monitoring data transmission component 23 is in data connection with the data conversion circuit 3, and the power supply component supplies power to the inclination monitoring data transmission component 23 through the power transmission line 2.

In this way, the data conversion circuit 3 converts the received liquid level data information of each liquid level sensor into a data format, and then further transmits the data to the inclination monitoring data transmission assembly 23, and the inclination monitoring data transmission assembly 23 can further transmit the data to an external data processing device for further processing.

In this embodiment, the power supply assembly includes an electric energy storage part 17 and a plurality of solar panels, wherein one solar panel is a signal recognition solar panel 18, the signal recognition solar panel 18 is electrically connected with the signal recognition electric energy storage assembly 15 through the electric energy transmission line 2, and the signal recognition electric energy storage assembly 15 converts solar energy into electric energy and supplies power for the signal recognition assembly 14 and the signal recognition data transmission assembly 16, the remaining solar panels supply power to the electric energy storage part 17 through the electric energy transmission line 2, and the electric energy storage part 17 converts solar energy into electric energy and supplies power to the tilt monitoring assembly and the signal emission assembly through the electric energy transmission line 2, respectively.

In this way, the solar panel provides solar energy for the electric energy storage component 17 and the signal recognition electric energy storage component 15, and then the electric energy storage component 17 and the signal recognition electric energy storage component 15 convert the solar energy into electric energy to supply power for each electric equipment.

In the present embodiment, the solar panels for supplying power to the electric energy storage unit 17 include an upper solar panel 19, a middle solar panel 20 and a lower solar panel 21, and the upper solar panel 19, the middle solar panel 20 and the lower solar panel 21 are disposed outside the bridge pier 26, and the solar panel for supplying power to the signal recognition electric energy storage unit 15 is disposed at the middle position of the bridge 25.

In this embodiment, the bridge deformation and inclination sensing device includes two bridge deformation and inclination sensing mechanisms, the two bridge deformation and inclination sensing mechanisms are respectively disposed on the bridge piers 26 at two sides of the bridge 25, the signal receiving mechanism is disposed at the middle position of the bridge 25 (as shown in fig. 6), and the signal receiving mechanism is disposed on the signal transmitting path of the signal transmitting head 10 in the two bridge deformation and inclination sensing mechanisms. When the bridge 25 deformation and deflection monitoring system is used, the signal transmitting head 10 horizontally transmits signals, the signal identifying component 14 transmits identifying signals, the positions of the signals transmitted by the signal transmitting head 10 are identified, the identified position signals are further transmitted to the signal identifying data transmitting component 16 and then further transmitted to an external data processing and monitoring terminal, and therefore real-time monitoring of the bridge 25 deformation and deflection is achieved.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the technical solution, and those skilled in the art should understand that modifications and equivalents may be made to the technical solution of the present utility model without departing from the spirit and scope of the present utility model, and all such modifications and equivalents are included in the scope of the claims.

Claims (9)

1. The bridge deformation inclination sensing device is characterized by comprising at least one bridge deformation inclination sensing mechanism, wherein the bridge deformation inclination sensing mechanism comprises a main body and a power supply assembly, an inclination monitoring assembly is arranged in the main body, and the power supply assembly supplies power to the inclination monitoring assembly through an electric energy transmission line; the inclination monitoring assembly comprises a data conversion circuit and a monitoring tank body fixedly connected with the main body, wherein a solution to be sensed is arranged in the monitoring tank body, a plurality of liquid level sensors are further arranged on the inner side wall of the monitoring tank body along the circumferential direction, each liquid level sensor is in contact with the solution to be sensed, the liquid level sensors are further in data connection with the data conversion circuit, and liquid level information of the solution to be sensed at corresponding positions is collected and sent to the data conversion circuit.

2. The bridge deformation inclination sensing device according to claim 1, wherein a front liquid level sensor, a left liquid level sensor, a rear liquid level sensor and a right liquid level sensor are sequentially arranged on the inner side wall of the monitoring tank body along the circumferential direction, and the initial liquid level of the solution to be sensed is located at the middle position of each liquid level sensor.

3. The bridge deformation and inclination sensing device according to claim 1, further comprising a signal receiving mechanism, wherein the bridge deformation and inclination sensing mechanism further comprises a signal transmitting assembly arranged in the main body, the power supply assembly supplies power to the signal receiving mechanism and the signal transmitting assembly through power transmission lines respectively, the signal transmitting assembly comprises a signal transmitting part, a signal transmitting head and a signal transmitting circuit, the signal transmitting circuit is in data connection with a conversion data output end of the data conversion circuit, the signal transmitting head is connected with the signal transmitting part and extends out of the main body, and the signal receiving mechanism is located on a signal transmitting path of the signal transmitting head so as to receive a position signal from the signal transmitting head.

4. The bridge deformation inclination sensing device of claim 3 wherein the signal transmitting assembly further comprises a signal transmitting canister, the signal transmitting canister being secured within the main body and the signal transmitting member being secured within the signal transmitting canister.

5. A bridge deformation inclination sensing device according to claim 3, wherein the signal receiving means comprises a signal receiving tank body and a signal identification data transmission assembly, the signal receiving tank body is internally provided with a signal identification assembly and a signal identification electric energy storage assembly, the signal identification electric energy storage assembly is electrically connected with the power supply assembly to supply power to the signal identification electric energy storage assembly through the power supply assembly, and the signal identification electric energy storage assembly is also electrically connected with the signal identification assembly and the signal identification data transmission assembly through electric energy transmission lines respectively to supply power to the signal identification assembly and the signal identification data transmission assembly respectively, and the signal identification assembly is in data connection with the signal identification data transmission assembly.

6. The bridge deformation tilt sensing device of claim 1, wherein the bridge deformation tilt sensing mechanism further comprises a tilt monitoring data transmission assembly in data connection with the data conversion circuit, and the power supply assembly supplies power to the tilt monitoring data transmission assembly via an electrical power transmission line.

7. The bridge deformation and inclination sensing device according to claim 5, wherein the power supply assembly comprises an electrical energy storage component and a plurality of solar panels, wherein one solar panel is electrically connected with the signal recognition electrical energy storage assembly through an electrical energy transmission line, and the signal recognition electrical energy storage assembly converts solar energy into electrical energy and supplies power to the signal recognition assembly and the signal recognition data transmission assembly, the remaining solar panels are supplied with power to the electrical energy storage component through an electrical energy transmission line, and the electrical energy storage component converts solar energy into electrical energy and supplies power to the inclination monitoring assembly and the signal emission assembly through an electrical energy transmission line, respectively.

8. The bridge deformation and inclination sensing device according to claim 7, wherein the solar panel for supplying power to the electric energy storage means comprises an upper solar panel, a middle solar panel and a lower solar panel, and the upper solar panel, the middle solar panel and the lower solar panel are disposed at the outer side of the bridge pier, and the solar panel for supplying power to the signal recognition electric energy storage means is disposed at the middle position of the bridge.

9. The bridge deformation inclination sensing device according to claim 3, wherein the bridge deformation inclination sensing device comprises two bridge deformation inclination sensing mechanisms, the two bridge deformation inclination sensing mechanisms are respectively arranged on bridge piers on two sides of a bridge, the signal receiving mechanism is arranged in the middle of the bridge, and the signal receiving mechanism is arranged on a signal transmission path of the signal transmission head in the two bridge deformation inclination sensing mechanisms.