CN112286089B - Intelligent monitoring system for high-pier long-span bridge construction process - Google Patents

Abstract

The embodiment of the disclosure provides a bridge work progress intelligent monitoring system is striden greatly to high mound, bridge work progress intelligent monitoring system is striden greatly to high mound includes the linear monitoring device of bridge girder, high pier stud straightness measuring device that hangs down, bridge construction management device, construction safety monitoring device and central controller, the linear monitoring device of bridge girder, high pier stud straightness measuring device, bridge construction management device and construction safety monitoring device are even central controller connects. The intelligent detection control system is applied to the construction project of the Yuqian high-iron stone beam river bridge, the dynamic, efficient, accurate, objective and early warning of monitoring data are well verified, and the intelligent detection control system has high adaptability and reliability to the complex construction environment of a construction site.

Description

Intelligent monitoring system for high-pier long-span bridge construction process

Technical Field

The utility model relates to a bridge construction engineering equipment technical field especially relates to a high mound long-span bridge work progress intelligent monitoring system.

Background

The Yuqian high-iron stone beam river bridge has large span, ultrahigh piers, larger live load, large design speed per hour and high requirement on construction control indexes of the bridge correspondingly. In the construction control of the mountain high-pier large-span T-shaped structural bridge, the monitoring control of high-pier construction becomes the central importance. The super-large scale pier span construction often has the problems of unbalanced structure size control precision, large artificial control safety risk and large monitoring labor cost.

Disclosure of Invention

In view of this, the embodiment of the present disclosure provides an intelligent monitoring system for a high-pier large-span bridge construction process, which at least partially solves the problems in the prior art.

In a first aspect, the disclosed embodiment provides an intelligent monitoring system for a high-pier long-span bridge construction process, which comprises a bridge girder linear monitoring device, a high pier stud verticality measuring device, a bridge construction management device, a construction safety monitoring device and a central controller, wherein the bridge girder linear monitoring device, the high pier stud verticality measuring device, the bridge construction management device and the construction safety monitoring device are all connected with the central controller;

the bridge girder linear monitoring device comprises girder linear detection equipment, a first inductive mobile device for installing the girder linear monitoring equipment and a plurality of linear detection points, wherein the linear detection points are arranged on the vertical central axis of a girder and two end parts of the girder in the horizontal direction, the plurality of linear detection points are connected with the girder linear detection equipment, and the output end of the girder linear detection equipment is connected with a central controller; the first inductive mobile device is arranged on the main beam, the bottom of the first inductive mobile device comprises a position signal receiver which is used for automatically adjusting the position when the inductive position does not reach a linear detection point, and a position signal emitter matched with the first inductive mobile device is arranged at the linear detection point;

high pier stud straightness measuring device that hangs down includes laser plummet appearance and the second can respond to mobile device, the laser plummet appearance is installed on the second can respond to mobile device, high pier stud straightness measuring device that hangs down still includes a plurality of straightness check points of hanging down and sets up the position signal transmitter in a plurality of perpendicular check points department, the second can respond to mobile device bottom and be provided with the position signal receiver who matches with the position signal transmitter of perpendicular check point department for when sensing the position and not reach perpendicular check point automatic adjustment position.

According to a specific implementation manner of the embodiment of the disclosure, the bridge construction management device comprises a BIM platform, a BIM software platform, a transmission device and intelligent monitoring equipment, wherein the BIM software platform is connected with the bridge BIM platform, and the intelligent monitoring equipment is connected with the bridge BIM platform through the transmission device; the bridge BIM platform comprises a three-dimensional design cooperation module, a construction information management module and an operation maintenance service module, wherein the three-dimensional design cooperation module is used for carrying out BIM parameterized modeling on a bridge and is connected with an external GIS system, a BIM system and an FEA system to realize lossless transmission of a BIM information model; the construction information management module is used for carrying out information management on the construction, progress, safety and quality of the bridge; and the operation maintenance service module is used for carrying out information management on the disease information, the structural state, the maintenance measures and the maintenance equipment of the bridge.

According to a concrete implementation mode of the embodiment of the disclosure, the construction safety monitoring device comprises a constructor installation monitoring device, the constructor safety monitoring device comprises a protective device with a wireless camera for personnel safety, an interactive intelligent assistant, a sensor and a cloud server, the interactive intelligent assistant comprises the wireless camera, an ARM cluster, an alarm, a display, a hard disk and an interface device, and the wireless camera, the intelligent monitoring equipment and the cloud server are all in wireless connection with the intelligent assistant.

According to a specific implementation manner of the embodiment of the disclosure, the intelligent monitoring system for the construction process of the high-pier large-span bridge further comprises a construction operation environment monitoring device, wherein the construction operation environment monitoring device comprises a data acquisition module, a data preprocessing module, a dust fall coefficient analysis module, a data input module, a noise analysis module, a management database, a regulation and control module and an early warning module; the data preprocessing module is connected with the data acquisition module, the dust fall coefficient analysis module is respectively connected with the data preprocessing module, the management database and the central controller, the noise analysis module is respectively connected with the data preprocessing module, the management database, the data input module and the central controller, and the central controller is respectively connected with the management database, the dust fall coefficient analysis module, the noise analysis module, the regulation and control module, the early warning module and the display terminal.

According to a concrete implementation mode of the embodiment of the disclosure, the data acquisition module comprises a dust concentration sensor, a humidity sensor, a wind speed sensor and a noise sensor, and is used for acquiring the dust concentration, the air humidity, the wind speed and the noise volume in the building construction operation environment in real time and sending the acquired data to the data preprocessing module and the intelligent monitoring equipment.

According to a specific implementation manner of the embodiment of the disclosure, the intelligent monitoring system for the construction process of the high-pier large-span bridge further comprises a stress sensor, wherein the stress sensor is installed on the frame body and used for monitoring the stress of each part of the frame body.

According to a specific implementation manner of the embodiment of the disclosure, the intelligent monitoring device comprises a mobile phone and a computer.

According to a specific implementation manner of the embodiment of the disclosure, the terminal device comprises a mobile phone, a computer and an alarm.

According to a specific implementation manner of the embodiment of the disclosure, the intelligent monitoring system for the high-pier large-span bridge construction process further comprises a video detection device, wherein the video detection device is used for monitoring image information of a construction site and transmitting the acquired image information to intelligent monitoring equipment.

According to a specific implementation manner of the embodiment of the disclosure, the intelligent monitoring system for the construction process of the high-pier large-span bridge further comprises an alarm device, and the alarm device is connected with the control system

The intelligent monitoring system for the construction process of the high-pier long-span bridge in the embodiment of the disclosure comprises a bridge girder linear monitoring device, a high pier stud verticality measuring device, a bridge construction management device, a construction safety monitoring device and a central controller, wherein the bridge girder linear monitoring device, the high pier stud verticality measuring device, the bridge construction management device and the construction safety monitoring device are uniformly connected with the central controller;

the bridge girder linear monitoring device comprises girder linear detection equipment, a first inductive mobile device for installing the girder linear monitoring equipment and a plurality of linear detection points, wherein the linear detection points are arranged on the vertical central axis of a girder and two end parts of the girder in the horizontal direction, the plurality of linear detection points are connected with the girder linear detection equipment, and the output end of the girder linear detection equipment is connected with a central controller; the first inductive mobile device is arranged on the main beam, the bottom of the first inductive mobile device comprises a position signal receiver which is used for automatically adjusting the position when the inductive position does not reach a linear detection point, and a position signal emitter matched with the first inductive mobile device is arranged at the linear detection point;

high pier stud straightness measuring device that hangs down includes laser plummet appearance and the second can respond to mobile device, the laser plummet appearance is installed on the second can respond to mobile device, high pier stud straightness measuring device that hangs down still includes a plurality of straightness check points of hanging down and sets up the position signal transmitter in a plurality of perpendicular check points department, the second can respond to mobile device bottom and be provided with the position signal receiver who matches with the position signal transmitter of perpendicular check point department for when sensing the position and not reach perpendicular check point automatic adjustment position.

The intelligent detection control system is applied to the construction project of the Yuqian high-iron stone beam river bridge, the dynamic, efficient, accurate, objective and early warning of monitoring data are well verified, and the intelligent detection control system has high adaptability and reliability to the complex construction environment of a construction site.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present disclosure, the drawings needed to be used in the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present disclosure, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic diagram of a module of an intelligent monitoring system for a high-pier large-span bridge construction process provided by an embodiment of the present disclosure.

Detailed Description

The embodiments of the present disclosure are described in detail below with reference to the accompanying drawings.

The embodiments of the present disclosure are described below with specific examples, and other advantages and effects of the present disclosure will be readily apparent to those skilled in the art from the disclosure in the specification. It is to be understood that the described embodiments are merely illustrative of some, and not restrictive, of the embodiments of the disclosure. The disclosure may be embodied or carried out in various other specific embodiments, and various modifications and changes may be made in the details within the description without departing from the spirit of the disclosure. It is to be noted that the features in the following embodiments and examples may be combined with each other without conflict. All other embodiments, which can be derived by a person skilled in the art from the embodiments disclosed herein without making any creative effort, shall fall within the protection scope of the present disclosure.

It is noted that various aspects of the embodiments are described below within the scope of the appended claims. It should be apparent that the aspects described herein may be embodied in a wide variety of forms and that any specific structure and/or function described herein is merely illustrative. Based on the disclosure, one skilled in the art should appreciate that one aspect described herein may be implemented independently of any other aspects and that two or more of these aspects may be combined in various ways. For example, an apparatus may be implemented and/or a method practiced using any number of the aspects set forth herein. Additionally, such an apparatus may be implemented and/or such a method may be practiced using other structure and/or functionality in addition to one or more of the aspects set forth herein.

It should be noted that the drawings provided in the following embodiments are only for illustrating the basic idea of the present disclosure, and the drawings only show the components related to the present disclosure rather than the number, shape and size of the components in actual implementation, and the type, amount and ratio of the components in actual implementation may be changed arbitrarily, and the layout of the components may be more complicated.

In addition, in the following description, specific details are provided to facilitate a thorough understanding of the examples. However, it will be understood by those skilled in the art that the aspects may be practiced without these specific details.

The embodiment of the disclosure provides an intelligent monitoring system for a high-pier large-span bridge construction process.

Referring to fig. 1, the intelligent monitoring system for the high-pier long-span bridge construction process provided by the embodiment of the present disclosure includes a bridge girder linear monitoring device, a high pier stud verticality measuring device, a bridge construction management device, a construction safety monitoring device and a central controller, wherein the bridge girder linear monitoring device, the high pier stud verticality measuring device, the bridge construction management device and the construction safety monitoring device are all connected with the central controller;

the bridge girder linear monitoring device comprises girder linear detection equipment, a first inductive mobile device for installing the girder linear monitoring equipment and a plurality of linear detection points, wherein the linear detection points are arranged on the vertical central axis of a girder and two end parts of the girder in the horizontal direction, the plurality of linear detection points are connected with the girder linear detection equipment, and the output end of the girder linear detection equipment is connected with a central controller; the first inductive mobile device is arranged on the main beam, the bottom of the first inductive mobile device comprises a position signal receiver which is used for automatically adjusting the position when the inductive position does not reach a linear detection point, and a position signal emitter matched with the first inductive mobile device is arranged at the linear detection point;

high pier stud straightness measuring device that hangs down includes laser plummet appearance and the second can respond to mobile device, the laser plummet appearance is installed on the second can respond to mobile device, high pier stud straightness measuring device that hangs down still includes a plurality of straightness check points of hanging down and sets up the position signal transmitter in a plurality of perpendicular check points department, the second can respond to mobile device bottom and be provided with the position signal receiver who matches with the position signal transmitter of perpendicular check point department for when sensing the position and not reach perpendicular check point automatic adjustment position.

The intelligent detection control system is applied to the construction project of the Yuqian high-iron stone beam river bridge, the dynamic, efficient, accurate, objective and early warning of monitoring data are well verified, and the intelligent detection control system has high adaptability and reliability to the complex construction environment of a construction site.

Furthermore, the bridge construction management device comprises a BIM platform, a BIM software platform, a transmission device and intelligent monitoring equipment, wherein the BIM software platform is connected with the bridge BIM platform, and the intelligent monitoring equipment is connected with the bridge BIM platform through the transmission device; the bridge BIM platform comprises a three-dimensional design cooperation module, a construction information management module and an operation maintenance service module, wherein the three-dimensional design cooperation module is used for carrying out BIM parameterized modeling on a bridge and is connected with an external GIS system, a BIM system and an FEA system to realize lossless transmission of a BIM information model; the construction information management module is used for carrying out information management on the construction, progress, safety and quality of the bridge; and the operation maintenance service module is used for carrying out information management on the disease information, the structural state, the maintenance measures and the maintenance equipment of the bridge.

Further, the construction safety monitoring device comprises a constructor installation monitoring device, the constructor safety monitoring device comprises a protective device with a wireless camera for personnel safety, an interactive intelligent assistant, a sensor and a cloud server, the interactive intelligent assistant comprises the wireless camera, an ARM cluster, an alarm, a display, a hard disk and an interface device, and the wireless camera, the intelligent monitoring equipment and the cloud server are all in wireless connection with the intelligent assistant.

Furthermore, the intelligent monitoring system for the construction process of the high-pier large-span bridge also comprises a construction operation environment monitoring device, wherein the construction operation environment monitoring device comprises a data acquisition module, a data preprocessing module, a dust fall coefficient analysis module, a data input module, a noise analysis module, a management database, a regulation and control module and an early warning module; the data preprocessing module is connected with the data acquisition module, the dust fall coefficient analysis module is respectively connected with the data preprocessing module, the management database and the central controller, the noise analysis module is respectively connected with the data preprocessing module, the management database, the data input module and the central controller, and the central controller is respectively connected with the management database, the dust fall coefficient analysis module, the noise analysis module, the regulation and control module, the early warning module and the display terminal.

Furthermore, the data acquisition module comprises a dust concentration sensor, a humidity sensor, a wind speed sensor and a noise sensor, and is used for acquiring the dust concentration, the air humidity, the wind speed and the noise volume in the building construction operation environment in real time and sending the acquired data to the data preprocessing module and the intelligent monitoring equipment.

Furthermore, the intelligent monitoring system for the construction process of the high-pier large-span bridge further comprises a stress sensor, wherein the stress sensor is installed on the frame body and used for monitoring the stress of each position of the frame body.

Further, the intelligent monitoring device comprises a mobile phone and a computer.

Furthermore, the intelligent monitoring system for the high-pier large-span bridge construction process further comprises a video detection device, wherein the video detection device is used for monitoring image information of a construction site and transmitting the acquired image information to intelligent monitoring equipment.

Furthermore, the intelligent monitoring system for the high-pier large-span bridge construction process further comprises an alarm device, and the alarm device is connected with the control system.

The above description is only for the specific embodiments of the present disclosure, but the scope of the present disclosure is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present disclosure should be covered within the scope of the present disclosure. Therefore, the protection scope of the present disclosure shall be subject to the protection scope of the claims.

Claims (7)

1. The intelligent monitoring system for the high-pier long-span bridge construction process is characterized by comprising a bridge girder linear monitoring device, a high pier stud verticality measuring device, a bridge construction management device, a construction safety monitoring device and a central controller, wherein the bridge girder linear monitoring device, the high pier stud verticality measuring device, the bridge construction management device and the construction safety monitoring device are all connected with the central controller;

the bridge girder linear monitoring device comprises girder linear detection equipment, a first inductive mobile device for installing the girder linear monitoring equipment and a plurality of linear detection points, wherein the linear detection points are arranged on the vertical central axis of a girder and two end parts of the girder in the horizontal direction, the plurality of linear detection points are connected with the girder linear detection equipment, and the output end of the girder linear detection equipment is connected with a central controller; the first inductive mobile device is arranged on the main beam, the bottom of the first inductive mobile device comprises a position signal receiver which is used for automatically adjusting the position when the inductive position does not reach a linear detection point, and a position signal emitter matched with the first inductive mobile device is arranged at the linear detection point;

the high pier column verticality measuring device comprises a laser plummet instrument and a second inductable moving device, wherein the laser plummet instrument is installed on the second inductable moving device, the high pier column verticality measuring device further comprises a plurality of verticality detection points and position signal transmitters arranged at the vertical detection points, and a position signal receiver matched with the position signal transmitters at the vertical detection points is arranged at the bottom of the second inductable moving device and used for automatically adjusting the position when the induced position does not reach the vertical detection points;

the intelligent monitoring system for the high-pier long-span bridge construction process further comprises an alarm device, and the alarm device is connected with the control system; the intelligent monitoring system for the high-pier long-span bridge construction process further comprises a stress sensor, wherein the stress sensor is installed on the frame body and used for monitoring the stress of each position of the frame body.

2. The intelligent monitoring system for the construction process of the high-pier large-span bridge according to claim 1, wherein the bridge construction management device comprises a BIM platform, a BIM software platform, a transmission device and an intelligent monitoring device, the BIM software platform is connected with the bridge BIM platform, and the intelligent monitoring device is connected with the bridge BIM platform through the transmission device; the bridge BIM platform comprises a three-dimensional design cooperation module, a construction information management module and an operation maintenance service module, wherein the three-dimensional design cooperation module is used for carrying out BIM parameterized modeling on a bridge and is connected with an external GIS system, a BIM system and an FEA system to realize lossless transmission of a BIM information model; the construction information management module is used for carrying out information management on the construction, progress, safety and quality of the bridge; and the operation maintenance service module is used for carrying out information management on the disease information, the structural state, the maintenance measures and the maintenance equipment of the bridge.

3. The intelligent monitoring system for the construction process of the high-pier large-span bridge according to claim 2, wherein the construction safety monitoring device comprises a constructor installation monitoring device, the constructor safety monitoring device comprises a personnel safety protection device with a wireless camera, an interactive intelligent assistant, a sensor and a cloud server, the interactive intelligent assistant comprises the wireless camera, an ARM cluster, an alarm, a display, a hard disk and an interface device, and the wireless camera, the intelligent monitoring equipment and the cloud server are all in wireless connection with the intelligent assistant.

4. The intelligent monitoring system for the construction process of the high-pier large-span bridge according to claim 2, further comprising a construction work environment monitoring device, wherein the construction work environment monitoring device comprises a data acquisition module, a data preprocessing module, a dust fall coefficient analysis module, a data input module, a noise analysis module, a management database, a regulation and control module and an early warning module; the data preprocessing module is connected with the data acquisition module, the dust fall coefficient analysis module is respectively connected with the data preprocessing module, the management database and the central controller, the noise analysis module is respectively connected with the data preprocessing module, the management database, the data input module and the central controller, and the central controller is respectively connected with the management database, the dust fall coefficient analysis module, the noise analysis module, the regulation and control module, the early warning module and the display terminal.

5. The intelligent monitoring system for the construction process of the high-pier large-span bridge according to claim 4, wherein the data acquisition module comprises a dust concentration sensor, a humidity sensor, a wind speed sensor and a noise sensor, and is used for acquiring the dust concentration, the air humidity, the wind speed and the noise volume in the construction working environment of the building in real time and sending the acquired data to the data preprocessing module and the intelligent monitoring equipment.

6. The intelligent monitoring system for the construction process of the high-pier large-span bridge according to claim 2, wherein the intelligent monitoring equipment comprises a mobile phone and a computer.

7. The intelligent monitoring system for the construction process of the high-pier large-span bridge according to claim 2, further comprising a video detection device for monitoring image information of a construction site and transmitting the acquired image information to an intelligent monitoring device.

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