CN110631852A - Modular structure monitoring system and monitoring method - Google Patents

Abstract

The invention discloses a modular structure monitoring system and a monitoring method, the scheme is mainly formed by matching a monitoring core logic platform with a universal data acquisition module, and the universal data acquisition module can carry out unified encapsulation of instructions and data on various types of sensor equipment so as to provide a standardized data acquisition operation mode; the universal data acquisition module constructs a universal extensible data interface, is in butt joint with various types of sensors and provides a unified instruction interface and a data format; the monitoring core logic platform is in data connection with the universal data acquisition module, and can be used for monitoring scheme design, equipment installation process recording, data acquisition, calculation analysis and evaluation display. The scheme provided by the invention has high compatibility and strong expansibility, and the whole framework integrates various functional modules, thereby effectively expanding the range of the monitoring objects of the traditional monitoring system, reducing the limitation of the traditional monitoring system on the types of data acquisition equipment and effectively overcoming the problems in the prior art.

Description

Modular structure monitoring system and monitoring method

Technical Field

The invention relates to a structure monitoring technology, in particular to a modular structure monitoring technology.

Background

The existing structure monitoring system adopts single bottom layer sensor hardware and can only support the structure monitoring of a single scene. If only the strain of the wall body can be monitored, only the displacement of the wall body under the influence of high-rise wind load can be monitored, and the like. The method has the advantages of single use scene and serious dependence on bottom hardware specification, and cannot adapt to diversified acquisition requirements in complex scenes.

Moreover, the existing structure monitoring system does not have a complete monitoring process for support, and usually only comprises data acquisition, calculation and calculation result display.

For a complete structure monitoring project, the whole process from early scheme preparation, monitoring data acquisition to evaluation result giving and report document confirmation is required to be included. Therefore, the existing structure monitoring system cannot meet the requirement and only can meet certain parts in the process.

Disclosure of Invention

In view of the problems of the existing structure monitoring system, a scheme of the structure monitoring system with a comprehensive monitoring range is needed.

Therefore, the invention aims to provide a monitoring system with a modular structure, which can effectively enlarge the range of a monitored object and reduce the limitation on the types of data acquisition equipment. On the basis, the invention further provides a structure monitoring method, which forms a flow of standard structure monitoring work.

In order to achieve the above object, the modular structure monitoring system provided by the invention comprises a general data acquisition module and a monitoring core logic platform;

the universal data acquisition module can carry out unified encapsulation of instructions and data on various types of sensor equipment so as to provide a standardized data acquisition operation mode; the universal data acquisition module constructs a universal extensible data interface, is in butt joint with various types of sensors and provides a unified instruction interface and a data format;

the monitoring core logic platform is in data connection with the universal data acquisition module, and can be used for monitoring scheme design, equipment installation process recording, data acquisition, calculation analysis and evaluation display.

Further, the general data acquisition module establishes a data connection with the corresponding sensor in a passive or active manner by establishing a TCP server.

Further, the general data acquisition module receives instruction information from monitoring personnel through an open unified TCP/HTTP interface, analyzes and recodes the instruction according to the type of the sensor, forwards the instruction to the corresponding sensor through the established connection, and waits for data information feedback.

Furthermore, the universal data acquisition module judges the working condition of connection with the sensor through a heartbeat package technical mechanism and provides corresponding state query service for monitoring personnel.

Further, the monitoring core logic platform comprises a monitoring scheme design module, an equipment installation process recording module, a data acquisition and calculation analysis module and an evaluation display module,

the monitoring scheme design module determines key difficulties in a monitoring project through a templated flow guide mode, and further determines a monitoring scheme;

the equipment installation process recording module is used for recording the field equipment installation process in real time and feeding back related information in time;

the data acquisition and calculation analysis module is used for monitoring data acquisition, data cleaning and structural calculation;

and the evaluation display module is used for displaying the structure evaluation data and automatically generating a structure monitoring report.

Furthermore, the monitoring core logic platform adopts an extensible architecture, defines a set of API interfaces on the bottom layer of the platform, and associates and calls other function modules through the API interfaces.

Further, the system also comprises a data storage module, and the data storage module is in data connection with the monitoring core logic platform.

Further, the data storage module comprises a TSDB database and a traditional database, and the TSDB database is in data connection with the monitoring core logic platform; and the traditional database is in data connection with the monitoring core logic platform.

Further, the system also comprises a calculation engine module, wherein the calculation engine module is respectively in data connection with the data storage module and the monitoring core logic platform and completes evaluation calculation based on input data.

Furthermore, the calculation engine module can call related calculation and evaluation mathematical models to calculate and return results according to input requirements, and the calculation and evaluation mathematical models can be added, deleted and modified according to actual conditions.

Furthermore, the system also comprises an automatic report generation module which is respectively in data connection with the data storage module and the monitoring core logic platform and can automatically generate standardized monitoring schemes and report documents according to the monitoring data.

Furthermore, the automatic report generation module is internally provided with a related professional term list, a monitoring specification and a document template style, and can automatically combine related resources according to the actual requirement of a monitoring project and generate a required format document.

Furthermore, the automatic report generation module selects corresponding templates and pictures according to the specific conditions of input data, and integrates data and exports the data into a complete report.

Furthermore, the system also comprises a user interaction module, wherein the user interaction module is respectively in data connection with the data storage module, the general data acquisition module and the monitoring core logic platform, and is used for real-time display of data and modification of project-related configuration.

In order to achieve the above object, the present invention provides a structure monitoring method, including:

(1) establishing a monitoring project, importing project basic information, and generating a monitoring scheme report according to the input related information;

(2) installing equipment on site and recording the installation process;

(3) automatically acquiring, processing and recording real-time monitoring data, simultaneously displaying on a user interaction interface in real time, and automatically producing periodic reports;

(4) and after the monitoring is finished, performing later-stage arrangement and evaluation on the collected data, generating a corresponding formal monitoring report and pushing the formal monitoring report to the user.

The scheme provided by the invention has high compatibility and strong expansibility, and the whole framework integrates various functional modules, thereby effectively expanding the range of the monitoring objects of the traditional monitoring system, reducing the limitation of the traditional monitoring system on the types of data acquisition equipment and effectively overcoming the problems in the prior art.

The scheme provided by the invention also optimizes the structure monitoring process, reduces the calculation and evaluation complexity of the monitoring data by utilizing a hierarchical calculation concept, extends the traditional monitoring process, integrates the same important parts in the actual work of project scheme design, report information feedback and the like, puts through all links of structure monitoring (such as scheme preparation, field arrangement, data acquisition, processing, evaluation, report delivery and the like), and improves the working efficiency and the overall control degree.

Drawings

The invention is further described below in conjunction with the appended drawings and the detailed description.

FIG. 1 is a diagram illustrating an exemplary configuration of a modular structure monitoring system according to an embodiment of the present invention;

FIG. 2 is a diagram illustrating a standardized structure monitoring workflow in an embodiment of the present invention.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further explained below by combining the specific drawings.

The problem that the application range of the structure monitoring system is small and the universality is not strong due to the fact that the monitoring range generally existing in the structure monitoring system is limited and the selection of the type of data acquisition equipment (sensors) is correspondingly limited is solved.

Moreover, the embodiment also extends the traditional monitoring process based on the modular structure monitoring system, adds the early-stage monitoring type selection, scheme design and later-stage evaluation result report generation part, puts through all links of structure monitoring (scheme preparation, field arrangement, data acquisition, processing, evaluation, report delivery and the like), and improves the working efficiency and the overall control degree.

Referring to fig. 1, a diagram illustrating an exemplary modular structure monitoring system is shown.

As can be seen from the figure, the modular structure monitoring system 100 is mainly formed by the interaction of a monitoring core logic platform 110, a general data acquisition module 120, a general computation engine module 130, a data storage module 140, an automation report generation module 150, and a user interaction module 160.

The general data acquisition module 120 can perform unified encapsulation of instructions and data for sensor devices of different manufacturers and models, and provide a standardized data acquisition operation mode for users.

A monitoring core logic platform 110 in data connection with the general data acquisition module 120, the general calculation engine module 130, the data storage module 140, the automated report generation module 150, and the user interaction module 160, respectively. The monitoring core logic platform 110 integrates various functional modules by using a set of architecture with high compatibility and strong expansibility, and provides monitoring personnel with functional services throughout the whole process of monitoring the structure from design of a monitoring scheme to recording of an equipment installation process, data acquisition, calculation analysis and evaluation display.

And the general computation engine module 130 is respectively in data connection with the monitoring core logic platform 110 and the data storage module 140. The general calculation engine module 130 takes the real-time monitoring data acquired by the general data acquisition module as input data, and performs evaluation calculation according to the input data.

And the data storage module 140 is used for storing various data required by the operation of the whole system and generated in the operation process.

And the automatic report generation module 150 is in data connection with the monitoring core logic platform 110, the data storage module 140 and the user interaction module 160, and is used for automatically generating a standardized monitoring scheme and a report document according to the monitoring data.

A user interaction module 160, which is mainly in data connection with the monitoring core logic platform 110, the general data acquisition module 120, the data storage module 140, and the automation report generation module 150. The user interaction module 160 supports real-time presentation of data and modification of project-related configurations, enabling the structural engineer to master the overall process of monitoring.

The modular structure monitoring system formed by the method has the characteristics of high compatibility, strong expansibility and the like, and meanwhile, the whole system architecture integrates various functional modules, so that various services including monitoring scheme design, equipment installation process recording, data acquisition and calculation analysis, evaluation and display and the like are provided for monitoring personnel.

To further illustrate the structure of the modular structure monitoring system, the structure of the modular structure monitoring system will be described in detail below by taking the scheme shown in fig. 1 as an example.

As can be seen, the universal data acquisition module 120 in the modular structure monitoring system 100 shown in fig. 1 specifically provides a set of universal extensible data interfaces, which can interface with sensors of multiple manufacturers, multiple models, and different types. The module provides a uniform instruction interface and data format for the system, and the compatibility problem possibly caused when the system uses different types of sensors is eliminated.

Further, the general data collecting module 120 may establish a data connection with the wireless module to which the sensor belongs passively/actively by establishing a TCP server.

Further, the general data acquisition module 120 receives instruction information from monitoring personnel through an open unified TCP/HTTP interface, analyzes and re-encodes the instruction according to the sensor type, and forwards the instruction to the corresponding sensor through the established connection, waiting for data information feedback. Besides the instruction and the data information, the data module also judges the working condition of the sensor connection through a heartbeat package technical mechanism and provides corresponding state query service for monitoring personnel.

Specifically, the universal data collection module 120 is mainly composed of a collection box instruction distribution server 121, a plurality of collection boxes 122, and a plurality of various sensors, which are mutually matched.

The collection box instruction distribution server 121 sends corresponding bottom layer device instructions to corresponding collection boxes according to different collection box types. The system can simultaneously support a plurality of collection boxes to be connected simultaneously, and guarantee that different collection boxes can normally receive instructions to collect data.

Meanwhile, the collection box instruction distribution server 121 is further provided with a corresponding RPC instruction set call interface 123 and a collection box communication interface 124. The collection box instruction distribution server 121 is in communication connection with a plurality of collection boxes 122 through a collection box communication interface 124, and is in data connection with modules in other systems through an RPC instruction set call interface 123.

The RPC instruction set call interface 123 is used to provide a cross-platform and cross-programming language call mode, so that other modules can smoothly call the functions of the module.

The collection box communication interface 124 establishes a wireless communication connection with the wireless module of the collection box based on wireless or mobile communication technology (such as 4G/5G, etc.), and is responsible for receiving and transmitting commands and data.

The monitoring core logic platform 110 in the system adopts an extensible architecture, and can selectively carry various functional modules to meet the requirements of actual conditions by defining a whole set of API protocol and corresponding module design specifications. Meanwhile, the platform supports simultaneous operation of multiple data sources/multiple monitoring projects by adopting a multi-process management scheme, and solves the problem of data time sequence consistency under the condition of multiple data sources through a multiple data source data acquisition algorithm.

Specifically, the monitoring core logic platform 110 mainly includes a monitoring module host process 111 and a plurality of collection box data monitoring processes 112, and the monitoring module host process 111 controls the plurality of collection box data monitoring processes 112.

The monitoring module main process 111 is responsible for monitoring, opening, closing the designated monitoring process of the collection box, and for receiving and transmitting interface data of the external module.

The listening module host process 111 also provides an RPC interface for the invocation and control of other modules.

Each collection box data monitoring process 112 is responsible for interfacing with a designated collection box, receiving and transmitting related instructions and data, and cleaning, calculating and analyzing received monitoring data.

Each of the collection box data monitoring processes 112 obtains the latest data record, calculates the measured physical quantity, calculates the direct physical quantity, and calculates the index quantity.

Specifically, the collection box data monitoring process 112 obtains data records by sending data collection instructions to the collection box, and then calls a related calculation formula to calculate the original data to obtain the measured physical quantity; on the basis, a related calculation formula is further called, and direct physical quantity is calculated; on the basis, a related calculation formula is further called, and an index quantity is calculated.

Accordingly, the monitoring core logic platform 110 can provide various services including monitoring scheme design, equipment installation process recording, data acquisition and calculation analysis, evaluation and display and the like for monitoring personnel through the mutual cooperation of the monitoring module main process 111 and the data monitoring processes 112 of the plurality of collection boxes.

Specifically, the monitoring core logic platform 110 may integrate a plurality of function modules through a set of architecture with high compatibility and strong expansibility to implement the above functions.

For example, the monitoring core logic platform 110 is functionally composed of a monitoring scheme design module, an equipment installation process recording module, a data acquisition and calculation analysis module, and an evaluation display module.

The monitoring scheme design module helps a structural engineer to determine key difficulties in a monitoring project through a templated flow guide mode, and further determines a monitoring scheme.

The equipment installation process recording module is used for recording the installation process of the field equipment in real time and feeding back related information to an owner in time.

The data acquisition and calculation analysis module is used for monitoring data acquisition, data cleaning and structural calculation.

The evaluation display module is used for displaying the structure evaluation data and generating an automatic report, and can directly provide a monitoring evaluation structure and a formal report for an owner.

The functional modules in the monitoring core logic platform 110 are basically composed as each stage of the complete monitoring process according to the sequence.

Furthermore, the monitoring core logic platform 110 can selectively carry various functional modules to meet the requirements of practical situations by defining a whole set of API protocols and corresponding module design specifications. Specifically, the monitoring core logic platform 110 defines a set of API interfaces at the bottom layer, including data call, module service registration, instruction transmission, and the like. Aiming at compiling corresponding function modules according to actual requirements, the correlation with the core logic platform can be realized through the API interface, so that the monitoring core logic platform 110 can call the related function functions of the function modules, and the carrying of expandability is realized.

The data storage module 140 in the present system mainly includes two major portions, namely, a TSDB database 141 and a conventional database 142.

The TSDB database 141 is directly connected to the data monitoring process 112 of the collection box in the monitoring core logic platform 110, and performs centralized optimization on streaming monitoring data, so as to support a higher and faster monitoring data collection method, i.e., support high-capacity and efficient reading and writing of monitoring data.

Specifically, the TSDB database 141 indexes time points, and stores data at relevant time points using an efficient and simple data structure.

Furthermore, the conventional database 142 is used for storing conventional information data such as project information, user information, and the like. The system is mainly composed of a storage database, a relational database and a constant resource database which are matched with each other, and the specific constitution is well known in the art and is not described herein again.

A general calculation engine module 130 in the system is respectively connected with a data storage module and a monitoring core logic platform in a data connection mode, and input data are calculated and evaluated through a series of calculation and evaluation mathematical models.

The general purpose computing engine module 130 acts as a single module, and its specific input data is determined by the caller to the module in the system. For example, when the monitoring process of the system calculates the direct physical quantity and the index quantity, the corresponding calculation formula and the evaluation mathematical model of the corresponding calculation module are called to evaluate whether the calculation result exceeds the expectation or not and reaches the structure safety warning line or not.

And the calculation engine calls the relevant calculation and evaluation mathematical model to calculate and returns a result according to the input requirement. The calculation and evaluation data model in the general calculation engine module 130 can be added, deleted and modified in real time according to actual needs, and monitoring needs under different conditions are met, so that the module has the characteristics of expandability, high calculation speed and various calculation modes.

Specifically, the general calculation engine module 130 mainly includes an RPC interface function unit 131, a calculation engine unit 132, and an HTTP interface function unit 133.

The RPC interface function unit 131 and the HTTP interface function unit 133 are configured to provide corresponding call interfaces for the outside, so as to provide different call modes and improve system compatibility.

The calculation engine unit 132 can obtain input data and parameters through two calling modes provided by the RPC interface function unit 131 and the HTTP interface function unit 133.

On this basis, the modification to the calculation and evaluation data formula is also passed to the calculation engine unit 132 through the interfaces provided by the RPC interface function unit 131 and the HTTP interface function unit 133.

The automated report generation module 150 in the system can automatically generate standardized monitoring schemes and report documents according to the monitoring data, thereby avoiding a great amount of repeated labor of structural engineers. Meanwhile, a large number of related professional term lists, monitoring specifications and document template styles are also built in the automatic report generation module 150, and related resources can be automatically combined according to the actual requirements of monitoring projects to generate required format documents (such as docx format documents).

The automated report generation module 150 can select corresponding templates and pictures according to the specific conditions of the input data, and integrate the data to export a complete report. The method has the characteristics of high expandability and high automation degree.

Specifically, the automatic report generating module 150 mainly includes a report generating unit 151 and a parameter configuring unit 152, wherein the report generating unit 151 obtains a formatted report configuration file from the parameter configuring unit 152, and obtains corresponding monitoring data from the TSDB database 141, so as to complete generation of a report document; the report generation unit 151 performs data connection with the listening module host process 111 through a corresponding RPC call interface to implement report control.

The parameter configuration unit 152 is directly connected to the legacy database 142 to obtain corresponding information such as the format protection configuration file, the project information, and the report template.

The user interaction module 160 in the present system is preferably presented in the form of a WEB client, but is not limited thereto, and can support multi-platform user interaction such as a WEB page side, a mobile side, and a PC side. The user interaction module 160 mainly includes a data access interface 161, a user behavior logic unit 162, an item information correlation logic unit 163, a collection box/sensor configuration logic unit 164, and the like, and the data access interface 161, the user behavior logic unit 162, the item information correlation logic unit 163, and the collection box/sensor configuration logic unit 164 are mutually matched to realize a friendly man-machine interaction function for a user.

The modular structure monitoring system formed by the method can be applied to large-span space structures, high-rise structures and various complex special-shaped structures, and can monitor various structural indexes including strain, stress, temperature, crack width, deflection, support reaction force and the like.

Meanwhile, the system reduces the calculation and evaluation complexity of the monitoring data by utilizing hierarchical calculation, and integrates the same important parts in the actual work of project scheme design, report information feedback and the like.

On the basis of the scheme of the modular structure monitoring system, the embodiment further forms a standardized structure monitoring work flow for standardizing the flow of the structure monitoring work, such as a monitoring mode selection mode, a scheme plan design method, a measuring point arrangement mode and the like, so as to help monitoring personnel to comb and optimize the monitoring work flow.

Referring to fig. 2, the standard workflow of structure monitoring formed based on the modular structure monitoring system in this embodiment mainly includes the steps of hierarchical classification of monitoring data content, data naming specification, and monitoring scheme design.

By way of example, the whole process mainly comprises the following steps:

step (1): and establishing a monitoring project and importing basic information of the project. The method specifically comprises project name, monitoring category, structure system, equipment installation plan and the like, and at the moment, the system automatically generates a monitoring scheme report according to the input related information.

Step (2): and (5) installing equipment on site and recording the installation process. The method specifically comprises the steps of recording the installation process of the equipment, testing the link between the field general data acquisition module and the system, pre-acquiring data, testing and the like.

And (3): formal monitoring begins. The process mainly carries out automatic acquisition, processing and recording of real-time monitoring data, meanwhile, real-time display is carried out on a user interaction interface, and periodic reports are automatically produced.

And (4) finishing formal monitoring. The process mainly carries out later-stage arrangement and evaluation on the collected data, generates a corresponding formal monitoring report and pushes the formal monitoring report to a user.

The following describes an implementation process of performing structural stress monitoring based on the modular structural monitoring system and the corresponding standard monitoring process provided by this example, taking structural stress monitoring as an example.

Firstly, determining a key component node to be measured (taking E001 as an example, hereinafter referred to as an E001 unit) in a target structure, inputting a system (namely a modular structure monitoring system, the same below), and automatically calculating and generating relevant parameters by the system after selecting a corresponding unit, a section and a material type of the structural unit through a user interaction module.

On the basis, the system calculates a reasonable monitoring measuring point arrangement mode (hereinafter referred to as a mode) suggestion of the unit according to the configured information through the data calculation module, and transmits the suggestion to the user through the user interaction module. One mode here includes unit physical quantity, process physical quantity, direct physical quantity and all related calculation formulas, parameters and evaluation thresholds, which are used to identify the calculation path of some unit evaluation index.

After the measuring point mode is selected, the system automatically generates all numbers corresponding to the physical quantities and the numbers corresponding to the sensors. The process is generated by relevant logic inside the user interaction module by matching with relevant number mapping rules stored in a conventional database.

After the configuration is completed, the system counts the types and the number of the sensors required by the monitoring project and the related data physical quantity, and generates a corresponding monitoring scheme report.

Further, corresponding sensors are arranged according to the scheme at the monitoring site, and corresponding communication connection is established with the system.

After actual monitoring starts, the system collects corresponding data according to preset configuration pre-entered by a user, calculates a final evaluation index according to the mode corresponding parameter and the calculation formula, and provides an evaluation result, wherein the result can be displayed through an interactive interface and can also be exported to be a corresponding monitoring report document. When data calculation is performed, the monitoring core logic platform 110 obtains data through the data acquisition module 120, and calls the data calculation module 130 to complete calculation.

Finally, it should be noted that, in the modular structure monitoring system provided in this example, the data storage module may also be in a conventional SQL/NOSQL manner as needed.

Furthermore, the communication protocol in the general data acquisition module 120 may be implemented by HTTP, UDP, or wired transmission.

In addition, the whole scheme of the system is in a modularized arrangement, and each module can be replaced and modified according to the requirement without influencing the normal use of other functions of the system.

The method of the present invention, or the specific system unit or some of the units thereof, is a pure software architecture, and can be distributed on a physical medium such as a hard disk, an optical disk, or any electronic device (e.g., a smart phone, a computer readable storage medium) through a program code, and when the program code is loaded and executed by a machine (e.g., loaded and executed by a smart phone), the machine becomes an apparatus for implementing the present invention. The methods and apparatus of the present invention may also be embodied in the form of program code transmitted over some transmission medium, such as electrical cable, fiber optics, or via any other form of transmission, wherein, when the program code is received and loaded into and executed by a machine, such as a smart phone, the machine becomes an apparatus for practicing the invention.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (15)

1. The modular structure monitoring system is characterized by comprising a general data acquisition module and a monitoring core logic platform;

the universal data acquisition module can carry out unified encapsulation of instructions and data on various types of sensor equipment so as to provide a standardized data acquisition operation mode; the universal data acquisition module constructs a universal extensible data interface, is in butt joint with various types of sensors and provides a unified instruction interface and a data format;

the monitoring core logic platform is in data connection with the universal data acquisition module, and can be used for monitoring scheme design, equipment installation process recording, data acquisition and calculation analysis and evaluation result display.

2. Modular structure monitoring system according to claim 1, characterised in that the generic data acquisition module establishes a data connection with the corresponding sensor in a passive or active manner by establishing a TCP server.

3. The modular structure monitoring system according to claim 1, wherein the general data collection module receives instruction information from monitoring personnel through an open unified TCP/HTTP interface, parses, re-encodes instructions according to sensor types, forwards the instructions to corresponding sensors through established connections, and waits for data information feedback.

4. The modular structure monitoring system according to claim 1, wherein the universal data acquisition module judges the working condition of connection with the sensor through a heartbeat packet technology mechanism and provides corresponding status inquiry service for monitoring personnel.

5. The modular structure monitoring system according to claim 1, wherein the monitoring core logic platform comprises a monitoring scheme design module, an equipment installation process recording module, a data acquisition and calculation analysis module and an evaluation display module,

the monitoring scheme design module determines key difficulties in a monitoring project through a templated flow guide mode, and further determines a monitoring scheme;

the equipment installation process recording module is used for recording the field equipment installation process in real time and feeding back related information in time;

the data acquisition and calculation analysis module is used for monitoring data acquisition, data cleaning and structural calculation;

and the evaluation display module is used for displaying the structure evaluation data and directly generating a structure monitoring report.

6. The modular structure monitoring system according to claim 5, wherein the monitoring core logic platform adopts an extensible architecture, a set of API interfaces are defined at the bottom of the platform, and the API interfaces are used for performing association and call with other function modules.

7. The modular structure monitoring system according to claim 1, further comprising a data storage module, wherein the data storage module is in data connection with the monitoring core logic platform.

8. Modular structure monitoring system according to claim 7, wherein the data storage module comprises a TSDB database and a legacy database, the TSDB database being in data connection with a monitoring core logic platform; and the traditional database is in data connection with the monitoring core logic platform.

9. The modular structure monitoring system according to claim 1, further comprising a computation engine module, wherein the computation engine module is respectively in data connection with the data storage module and the monitoring core logic platform, and performs evaluation computation based on input data.

10. The modular structure monitoring system according to claim 9, wherein the calculation engine module is capable of calling the relevant calculation and evaluation mathematical model to calculate and return the result according to the input requirement, and the calculation and evaluation mathematical model can be added, deleted and modified according to the actual situation.

11. The modular structure monitoring system according to claim 1, further comprising an automated report generation module, wherein the automated report generation module is respectively connected with the data storage module and the monitoring core logic platform, and can automatically generate standardized monitoring schemes and report documents according to the monitoring data.

12. The modular structure monitoring system according to claim 11, wherein the automatic report generation module is provided with a list of related professional terms, a monitoring specification and a document template style, and can automatically combine related resources according to the actual requirement of a monitoring project and generate a required format document.

13. The modular structure monitoring system of claim 11, wherein the automated report generation module selects corresponding templates and pictures according to the specific conditions of the input data, and the integrated data is exported to be a complete report.

14. The modular structure monitoring system according to claim 1, further comprising a user interaction module, wherein the user interaction module is respectively in data connection with the data storage module, the general data acquisition module and the monitoring core logic platform, and the user interaction module is used for real-time display of data and modification of project-related configuration.

15. A structure monitoring method, characterized in that the structure monitoring method comprises:

(1) establishing a monitoring project, importing project basic information, and generating a monitoring scheme report according to the input related information;

(2) installing equipment on site and recording the installation process;

(3) automatically acquiring, processing and recording real-time monitoring data, simultaneously displaying the real-time monitoring data on a user interaction interface in real time, and automatically generating a periodic report;

(4) and after the monitoring is finished, performing later-stage arrangement and evaluation on the collected data, generating a corresponding formal monitoring report and pushing the formal monitoring report to the user.

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