CN113189896A - System and method for carrying out centralized control on operation of underground pipe gallery - Google Patents

Abstract

The invention discloses a system and a method for centralized control of operation and operation of an underground pipe gallery, which are characterized in that the three-dimensional visualization system based on GIS and BIM technology respectively realizes visualization of equipment utilization rate, equipment operation state, states of drainage pumps of fire prevention subareas, states of ventilation devices, lighting states, fire detection states, environment temperature/humidity, oxygen content, illegal invasion and other various alarm signals and the like through the cooperative cooperation of a three-dimensional visualization display system, an intelligent management and control system, an Internet of things perception system, a multi-source data acquisition system, a camera monitoring system, an alarm early warning system and the like, and the hidden dangers can be found in advance through analysis rules configured by 0 code, so that the centralized control is realized, the stable and efficient operation and management is realized, and the operation and operation efficiency of the underground pipe gallery is improved.

Description

System and method for carrying out centralized control on operation of underground pipe gallery

Technical Field

The present invention relates to the field of pipe gallery control technology, and more particularly, to a system and method for centralized control of the operation of an underground pipe gallery.

Background

The construction of the urban underground comprehensive pipe gallery realizes the orderly access of a plurality of urban important pipelines including water supply, drainage, gas, heat, power, communication, broadcast television, industry and the like, solves the problem of disordered management of a plurality of government departments, a plurality of jurisdictions and a plurality of use units in the past, and also improves the problems of urban waterlogging, low underground space resource utilization rate and the like to the greatest extent. The utility tunnel brings city engineering pipelines such as water supply, rainwater, sewage, reclaimed water, natural gas, heating power, electric power, communication into being respected of unified planning, design, construction and maintenance requirements, satisfies the use and operation maintenance requirements of pipelines, and the utility tunnel also constructs facilities such as fire control, power supply, illumination, control and warning, ventilation, drainage, sign in step simultaneously. Along with the popularization of city utility tunnel construction, the utility tunnel scale is constantly enlarged, the development of relevant design, design and construction all tend to maturity, the difficult problem that the management problem becomes in order to face, like the state diagnosis of all kinds of pipelines, failure diagnosis and failure prediction, unmanned on duty etc, current development mode has not been satisfied to traditional operation mode, if the operation management of piping lane does not have effectual management, do not possess the health of equipment, stable and efficient operation, not only do not have the facility that make full use of piping lane brought, cause the paralysis of a plurality of systems in city on the contrary.

Therefore, there is a need for a method of centrally controlling the operational operations of an underground utility tunnel to efficiently control the underground utility tunnel.

Disclosure of Invention

The invention provides a system and a method for carrying out centralized control on the operation of an underground pipe gallery, which aim to solve the problem of how to efficiently control the underground pipe gallery.

In order to solve the above problems, according to an aspect of the present invention, there is provided a system for centrally controlling an operation of an underground pipe gallery, the system including:

the intelligent management and control system is used for collecting and controlling different devices of the underground pipe gallery through linkage of a collection program and a control program of the server side, so that remote monitoring is realized;

the multi-source data acquisition system is used for acquiring the running state data of different equipment in the underground pipe gallery in real time so as to obtain the running state data of the different equipment;

and the alarm early warning system is used for generating a corresponding calculation task according to a set alarm rule and/or a reverse control rule, performing parallel calculation according to the acquired running state data of different equipment and the calculation task, and alarming and/or triggering corresponding direction control according to the reverse control rule when a trigger value is reached.

Preferably, wherein the system further comprises:

the three-dimensional visual digital twin system is used for displaying data of a whole pipeline gallery by means of a Geographic Information System (GIS) technology, displaying a model of any partition by means of a Building Information Model (BIM), displaying statistical data and real-time data which take the partition as a dimension in a view port range in a GIS scene under the condition of no abnormality, and displaying the statistical data and the real-time data in any partition under the BIM scene; and the data display of the corresponding topic is realized through the switching of different topics.

Preferably, the intelligent management and control system collects the position of each subsection in the pipe gallery, the utilization rate of equipment, the running state of the equipment, the state of each fire-proof subarea draining pump, the state of a ventilating device, the state of lighting equipment, the state of fire detection equipment, ambient temperature and/or humidity data, oxygen content data, alarm signals, equipment parameter data and inventory parameter data through a collection program.

Preferably, wherein the system further comprises:

the sensing system of the Internet of things is used for connecting various devices and sensors of each subarea of the underground pipe gallery to construct an Internet of things sensing network;

the camera monitoring system is used for visually monitoring the field running state of various devices in the underground pipe gallery.

Preferably, wherein the system further comprises: a rule configuration unit to:

based on a knowledge base template, randomly combining equipment address variables, acquisition address variables and control address variables in a 0 code mode through a python script to generate different types of alarm rules and/or reverse control rules; wherein, any one of the alarm rules or the reverse control rules comprises: calculating a formula, an alarm value, an alarm action and a reverse control action; the knowledge base template comprises: an emergency scheme; the emergency scheme comprises the following steps: and prompting an emergency scheme and a control scheme of a reverse control device address variable and control address variable combination.

Preferably, the intelligent management and control system is further configured to: managing device address variables, acquisition address variables and control address variables of each system.

According to another aspect of the present invention, there is provided a method of centrally controlling the operational operation of a subterranean pipe gallery, the method comprising:

the intelligent management and control system is linked with the control program through the acquisition program of the server side to acquire and control different devices of the underground pipe gallery, so that remote monitoring is realized;

the multisource data acquisition system acquires the running state data of different equipment in the underground pipe gallery in real time to obtain the running state data of the different equipment;

the alarm early warning system generates a corresponding calculation task according to a set alarm rule and/or a reverse control rule, performs parallel calculation according to the acquired running state data of different equipment and the calculation task, and performs alarm and/or triggers corresponding direction control according to the reverse control rule when a trigger value is reached.

Preferably, wherein the method further comprises:

the three-dimensional visual digital twin system displays data of the whole pipeline gallery by means of a Geographic Information System (GIS) technology, displays a model of any subarea by means of a Building Information Model (BIM), displays statistical data and real-time data which take the subarea as a dimension in a view port range in a GIS scene under the condition of no abnormality, and displays the statistical data and the real-time data in any subarea under the BIM scene; and the data display of the corresponding topic is realized through the switching of different topics.

Preferably, the intelligent management and control system collects the position of each subsection in the pipe gallery, the utilization rate of equipment, the running state of the equipment, the state of each fire-proof subarea draining pump, the state of a ventilation device, the state of lighting equipment, the state of fire detection equipment, ambient temperature and/or humidity data, oxygen content data, alarm signals, equipment parameter data and inventory parameter data through a collection program.

Preferably, wherein the method further comprises:

the sensing system of the internet of things is connected with various devices and sensors of each subarea of the underground pipe gallery to construct a sensing network of the internet of things;

the camera monitoring system visually monitors the field running state of various devices in the underground pipe gallery.

Preferably, wherein the method further comprises:

randomly combining equipment address variables, acquisition address variables and control address variables in a 0 code mode by using a rule configuration unit based on a knowledge base template to generate different types of alarm rules and/or reverse control rules; wherein, any one of the alarm rules or the reverse control rules comprises: calculating a formula, an alarm value, an alarm action and a reverse control action; the knowledge base template comprises: an emergency scheme; the emergency scheme comprises the following steps: and prompting an emergency scheme and a control scheme of a reverse control device address variable and control address variable combination.

Preferably, wherein the method further comprises:

and managing the equipment address variables, the acquisition address variables and the control address variables of each system by using an intelligent management and control system.

The invention provides a system and a method for centralized control of operation and operation of an underground pipe gallery, which are characterized in that the three-dimensional visualization system based on GIS and BIM technology respectively realizes visualization of equipment utilization rate, equipment operation state, states of drainage pumps of fire prevention subareas, states of ventilation devices, lighting states, fire detection states, environment temperature/humidity, oxygen content, illegal invasion and other various alarm signals and the like through the cooperative cooperation of a three-dimensional visualization display system, an intelligent management and control system, an Internet of things perception system, a multi-source data acquisition system, a camera monitoring system, an alarm early warning system and the like, and the hidden dangers can be found in advance through analysis rules configured by 0 code, so that the centralized control is realized, the stable and efficient operation and management is realized, and the operation and operation efficiency of the underground pipe gallery is improved.

Drawings

A more complete understanding of exemplary embodiments of the present invention may be had by reference to the following drawings in which:

fig. 1 is a schematic structural diagram of a system 100 for centralized control of the operational operation of a subterranean passageway according to an embodiment of the present invention;

fig. 2 is an exemplary diagram of a system for centralized control of the operational operation of a subterranean pipe gallery in accordance with an embodiment of the present invention;

FIG. 3 is a flow diagram of configuration code for alarm and reverse control according to an embodiment of the present invention;

fig. 4 is a flow chart of a method 400 of centrally controlling the operational operation of a subterranean pipe gallery in accordance with an embodiment of the present invention.

Detailed Description

The exemplary embodiments of the present invention will now be described with reference to the accompanying drawings, however, the present invention may be embodied in many different forms and is not limited to the embodiments described herein, which are provided for complete and complete disclosure of the present invention and to fully convey the scope of the present invention to those skilled in the art. The terminology used in the exemplary embodiments illustrated in the accompanying drawings is not intended to be limiting of the invention. In the drawings, the same units/elements are denoted by the same reference numerals.

Unless otherwise defined, terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Further, it will be understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense.

Fig. 1 is a schematic structural diagram of a system 100 for centralized control of the operational operation of a subterranean pipe gallery in accordance with an embodiment of the present invention. As shown in fig. 1, the system for performing centralized control on the operation of the underground pipe gallery provided by the embodiment of the present invention realizes visualization of various alarm signals based on the GIS and the BIM technologies, such as the equipment utilization rate, the equipment operation state, the state of each fire-prevention partition drainage pump, the state of a ventilation device, the state of illumination, the state of fire detection, the ambient temperature/humidity and oxygen content, and illegal intrusion, through the cooperative coordination of the three-dimensional visualization display system, the intelligent management and control system, the internet of things sensing system, the multi-source data acquisition system, the camera monitoring system, the alarm early warning system, and the like, and discovers hidden dangers in advance from various possibilities through an analysis rule configured by 0 code, realizes centralized control, realizes stable and efficient operation management, and improves the operation efficiency of the underground pipe gallery. The system 100 for centralized control of the operation of the underground pipe gallery provided by the embodiment of the invention comprises: the system comprises an intelligent management and control system 101, a multi-source data acquisition system 102 and an alarm early warning system 103.

Preferably, the intelligent management and control system 101 is used for collecting and controlling different devices of the underground pipe gallery by linkage of a collection program and a control program of the server side, so as to realize remote monitoring.

Preferably, the intelligent management and control system 101 collects the position of each partition in the pipe gallery, the utilization rate of the equipment, the running state of the equipment, the state of each fire-protection partition drainage pump, the state of a ventilation device, the state of lighting equipment, the state of fire detection equipment, ambient temperature and/or humidity data, oxygen content data, alarm signals, equipment parameter data and inventory parameter data through a collection program.

Preferably, the intelligent management and control system 101 is further configured to: managing device address variables, acquisition address variables and control address variables of each system.

In the invention, the system for the operation centralized control of the underground pipe gallery is a central monitoring system, which comprises: the system comprises a three-dimensional visual display system, an intelligent management and control system, an Internet of things sensing system, a multi-source data acquisition system, a camera monitoring system and an alarm early warning system. The sensing system of the internet of things is responsible for communicating with hardware, the multi-source data acquisition system is responsible for data acquisition and processing, the alarm early warning system is responsible for alarming and processing, the camera monitoring system is responsible for on-site monitoring, the intelligent management and control system is responsible for reverse control equipment, the central monitoring system is responsible for fusing video, alarm and reverse control, and the three-dimensional visual display system is responsible for visually displaying underground pipe gallery entities, data and alarm lamps. The intelligent management and control system, the internet of things sensing system, the multi-source data acquisition system, the camera monitoring system and the alarm early warning system are integrated in the central monitoring system. The central monitoring system is composed of a management monitoring computer, a server, a communication computer, an intelligent simulation screen and other equipment arranged in a monitoring center, wherein the intelligent simulation screen can visually display the running conditions of various equipment in a pipe gallery, timely know the occurrence and positions of disasters and illegal invasion, and acquire the positions of all sections in the pipe gallery, the equipment utilization rate, the equipment running state, the states of drainage pumps of all fire-proof subareas, the states of ventilation devices, the states of illumination, the states of fire detection, the ambient temperature/humidity and oxygen content, various alarm signals of illegal invasion and the like through acquisition programs. The central monitoring system is used for receiving the information data, forming monitoring and making related intelligent response.

The intelligent management and control system collects and controls the drainage equipment, the power distribution room, the fire-fighting facilities, the ventilation system, the lighting system and other systems through linkage of the control program and the collection program of the server, realizes the remote monitoring function, and constructs the monitoring station on the pipe gallery site into an unattended monitoring station. Each system mainly divides the dimensionality by taking equipment as a main division dimensionality, manages equipment address variables of each system in an intelligent management and control system, and collects the address variables and control address variables; meanwhile, the system comprises a perception layer of the docking equipment to realize the control function of the equipment, and is used for receiving instruction data of the central monitoring system and making related intelligent response according to the instruction pair.

Preferably, the multi-source data acquisition system is used for acquiring 102 the operation state data of different devices in the underground pipe gallery in real time so as to acquire the operation state data of the different devices.

The multi-source data acquisition system is used for acquiring parameters such as equipment operation state, states of drainage pumps of all fire prevention subareas, states of ventilation devices, states of illumination, states of fire detection, various alarm signals of environment temperature/humidity, oxygen content, illegal invasion and the like, equipment parameters, inventory and the like in real time.

Preferably, the alarm early warning system 103 is configured to generate a corresponding calculation task according to a set alarm rule and/or a reverse control rule, perform parallel calculation according to the acquired running state data of different devices and the calculation task, and perform alarm and/or trigger corresponding direction control according to the reverse control rule when a trigger value is reached.

Preferably, wherein the system further comprises: a rule configuration unit to:

based on a knowledge base template, randomly combining equipment address variables, acquisition address variables and control address variables in a 0 code mode through a python script to generate different types of alarm rules and/or reverse control rules; wherein, any one of the alarm rules or the reverse control rules comprises: calculating a formula, an alarm value, an alarm action and a reverse control action; the knowledge base template comprises: an emergency scheme; the emergency scheme comprises the following steps: and prompting an emergency scheme and a control scheme of a reverse control device address variable and control address variable combination.

Preferably, wherein the system further comprises:

the three-dimensional visual digital twin system is used for displaying data of a whole pipeline gallery by means of a Geographic Information System (GIS) technology, displaying a model of any partition by means of a Building Information Model (BIM), displaying statistical data and real-time data which take the partition as a dimension in a view port range in a GIS scene under the condition of no abnormality, and displaying the statistical data and the real-time data in any partition under the BIM scene; and the data display of the corresponding topic is realized through the switching of different topics.

Preferably, wherein the system further comprises:

the sensing system of the Internet of things is used for connecting various devices and sensors of each subarea of the underground pipe gallery to construct an Internet of things sensing network;

the camera monitoring system is used for visually monitoring the field running state of various devices in the underground pipe gallery.

In the invention, in a rule configuration unit of a central control system, by means of a python script and a 0 code mode and through equipment address variables, address variables and control address variables are collected, various code formulas (formulas, namely rules) for alarming, reverse control and the like are generated, and variables among systems are combined at will. In addition, the database can be provided with a knowledge base template, how to quickly process a certain class or a plurality of classes for the use of a 0 code configuration formula, and simultaneously, when an emergency occurs, the database guides the working personnel to carry out emergency processing. A code formula comprises a formula, an alarm value, an alarm action and a reverse control action, wherein the reverse control is not necessary, the alarm can have a plurality of sections of alarms, and the direction control corresponding to different interval values can be different. And generating one server job task by the configured code formula, carrying out parallel calculation on the acquired data according to the job task in a big data FLink frame, and alarming or triggering the direction control specified by the formula after a trigger value is reached.

In addition, the Internet of things sensing system is used for connecting various devices and sensors of all the subareas of the underground pipe gallery and constructing an Internet of things sensing network. The camera monitoring system is used for visually monitoring various states of various equipment operation and the like of the underground pipe gallery. Three-dimensional visual system can the display system, can show the data of full line piping lane with the help of the GIS means, shows the model of certain subregion with the help of the BIM model, under the condition that does not have any anomaly, shows statistical data and the real-time data with the subregion dimension in the viewport scope under the GIS scene, shows statistical data and the real-time data in certain subregion under the BIM scene, switches the data of corresponding special topic through different special topics.

After alarming, the central monitoring system can rapidly transmit and collect the condition data of any corner in the pipe gallery in the monitoring center through automatic monitoring and detecting equipment, locate the window where alarming occurs in the GIS and BIM scenes respectively, check corresponding real-time data, count data and automatically control the execution condition of a scheme, so that a manager can easily master all conditions at any time. On each viewing control computer, 32 windows for alarming can be opened, and possible alarming can be displayed without omission.

According to the invention, by means of a GIS technology, partition information is initialized on a GIS base map, the GIS base map can be randomly enlarged and reduced, only statistical data and real-time data in a view port range are displayed in a scene, data is divided into topics of a monitoring system, a security system, an alarm system, an emergency plan and operation and maintenance dimensions, data of different topics is clicked, and the data is sourced from other background systems. The method comprises the steps of establishing a three-dimensional visual model in a subarea by means of a BIM technology, adopting a visual engine to highly restore a three-dimensional scene, and integrating implementation data and a three-dimensional scene equipment model in the three-dimensional scene to bind, so that the display of real data in the three-dimensional scene is realized, the real data is divided into statistical data and real-time data, and only the statistical data and the implementation data of a cabin and equipment can be displayed in a viewport scene.

Fig. 2 is an exemplary diagram of a system for centrally controlling the operation of a subterranean pipe gallery in accordance with an embodiment of the present invention. As shown in fig. 2, the central monitoring system 20 is a large platform integrating data such as an intelligent management and control system, an internet of things sensing system, a multi-source data acquisition system (i.e., multi-source data acquisition software), a camera monitoring system, an alarm early warning system and the like, and supports basic data and services of a three-dimensional visualization platform; providing a knowledge base template, managing emergency schemes and a control scheme comprising a prompt emergency scheme and a reverse control device address variable and control address variable combination; providing a Python editor, providing a 0 code editor, editing a formula, and setting alarms of different levels, wherein each level points to different same or different control schemes; generating a corresponding joba for the started formula, calculating the joba in parallel in a FLink frame based on big data calculation, and triggering corresponding alarm and direction control according to the formula; once an alarm occurs, a control computer viewport in the central monitoring system respectively puts corresponding scenes at a GIS visual angle and a BIM visual angle, and simultaneously independently displays the corresponding alarm scenes.

The intelligent management and control system 21 is linked with the acquisition program through the control program of the server end to acquire and control systems such as drainage equipment, a power distribution room, fire-fighting facilities, a ventilation system and a lighting system, so as to realize a remote monitoring function. The networked sensing system 22 is various devices and sensors in the underground pipe gallery, and constructs an internet of things sensing network. The multi-source data acquisition system 23 is used for acquiring parameters such as equipment running state, states of drainage pumps of all fire-proof subareas, states of ventilation devices, states of illumination, states of fire detection, environmental temperature/humidity, oxygen content, illegal invasion and various alarm signals, equipment parameters, inventory and the like in real time. The camera monitoring system 24 is used for visually monitoring various states of various equipment operation and the like of the underground pipe gallery. The alarm early warning system 25 is used for various alarms, and pushes a corresponding fault handling scheme, and is also used for fault handling feedback.

In the central control system, the process of integrating each system variable is the soul of the central control, and the flow is shown in fig. 3, and the following is described in detail: the intelligent control system opens the equipment address variable, the collected address variable and the controlled address variable are opened in an interface variable mode, and the variable can be inquired in the central control system, for example, an environment and equipment monitoring system is mainly composed of intelligent sensors (environment monitoring and equipment monitoring), a multifunctional base station, an intelligent LED display, an alarm horn and other equipment, the variable address of the intelligent sensor is opened to the central control system, the variable address is input by the intelligent LED, and the opening and closing address of the alarm horn is opened and closed. The knowledge base module provides an emergency scheme and a control scheme comprising a prompt emergency scheme and a reverse control device address variable and control address variable combination. The alarm early warning system 0 codes compile a code formula, provides a Python editor, provides a 0 code editor, edits the formula, can set alarms of different levels, and each level points to different or same control schemes. Generating a JOB task, performing parallel calculation in a FLink frame, generating a corresponding jobto a starting formula, performing parallel calculation on the JOBs in the FLink frame based on big data calculation, and triggering corresponding alarm and direction control according to the formula. And alarming and reverse control are carried out, a joba is subjected to parallel calculation in an FLink frame, alarming occurs once the value meets the set requirement of formula alarming, a viewport of a control computer in the central monitoring system is respectively put into corresponding scenes at a GIS visual angle and a BIM visual angle, and colleagues independently display the alarming scenes.

The operation and operation centralized control system and method for the underground pipe gallery can realize the centralized control of the pipe gallery as a whole through the states of the drainage pumps of the fire prevention subareas, the states of the ventilation devices, the states of the illumination, the states of the fire detection, the ambient temperature/humidity, the oxygen content, the illegal invasion and the like, and improve the operation and operation efficiency of the underground pipe gallery.

Fig. 4 is a flow chart of a method 400 of centrally controlling the operational operation of a subterranean pipe gallery in accordance with an embodiment of the present invention. As shown in fig. 4, in a method 400 for performing centralized control on operation of an underground pipe gallery according to an embodiment of the present invention, starting from step 401, an intelligent management and control system performs linkage between an acquisition program and a control program of a server side to acquire and control different devices of the underground pipe gallery, so as to implement remote monitoring.

Preferably, the intelligent management and control system collects the position of each subsection in the pipe gallery, the utilization rate of equipment, the running state of the equipment, the state of each fire-proof subarea draining pump, the state of a ventilation device, the state of lighting equipment, the state of fire detection equipment, ambient temperature and/or humidity data, oxygen content data, alarm signals, equipment parameter data and inventory parameter data through a collection program.

In step 402, the multi-source data acquisition system acquires the operating state data of different devices in the underground pipe gallery in real time to obtain the operating state data of the different devices.

In step 403, the alarm and early warning system generates a corresponding calculation task according to the set alarm rule and/or the reverse control rule, performs parallel calculation according to the acquired running state data of different devices and the calculation task, and performs alarm and/or triggers corresponding direction control according to the reverse control rule when a trigger value is reached.

Preferably, wherein the method further comprises:

the three-dimensional visual digital twin system displays data of the whole pipeline gallery by means of a Geographic Information System (GIS) technology, displays a model of any subarea by means of a Building Information Model (BIM), displays statistical data and real-time data which take the subarea as a dimension in a view port range in a GIS scene under the condition of no abnormality, and displays the statistical data and the real-time data in any subarea under the BIM scene; and the data display of the corresponding topic is realized through the switching of different topics.

Preferably, wherein the method further comprises:

the sensing system of the internet of things is connected with various devices and sensors of each subarea of the underground pipe gallery to construct a sensing network of the internet of things;

the camera monitoring system visually monitors the field running state of various devices in the underground pipe gallery.

Preferably, wherein the method further comprises:

randomly combining equipment address variables, acquisition address variables and control address variables in a 0 code mode by using a rule configuration unit based on a knowledge base template to generate different types of alarm rules and/or reverse control rules; wherein, any one of the alarm rules or the reverse control rules comprises: calculating a formula, an alarm value, an alarm action and a reverse control action; the knowledge base template comprises: an emergency scheme; the emergency scheme comprises the following steps: and prompting an emergency scheme and a control scheme of a reverse control device address variable and control address variable combination.

Preferably, wherein the method further comprises:

and managing the equipment address variables, the acquisition address variables and the control address variables of each system by using an intelligent management and control system.

The method 400 for performing centralized control on the operation of the underground pipe gallery in the embodiment of the present invention corresponds to the system 100 for performing centralized control on the operation of the underground pipe gallery in another embodiment of the present invention, and is not described herein again.

The invention has been described with reference to a few embodiments. However, other embodiments of the invention than the one disclosed above are equally possible within the scope of the invention, as would be apparent to a person skilled in the art from the appended patent claims.

Generally, all terms used in the claims are to be interpreted according to their ordinary meaning in the technical field, unless explicitly defined otherwise herein. All references to "a/an/the [ device, component, etc ]" are to be interpreted openly as referring to at least one instance of said device, component, etc., unless explicitly stated otherwise. The steps of any method disclosed herein do not have to be performed in the exact order disclosed, unless explicitly stated.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting the same, and although the present invention is described in detail with reference to the above embodiments, those of ordinary skill in the art should understand that: modifications and equivalents may be made to the embodiments of the invention without departing from the spirit and scope of the invention, which is to be covered by the claims.

Claims (12)

1. A system for centralized control of the operational operations of a subterranean pipe gallery, the system comprising:

the intelligent management and control system is used for collecting and controlling different devices of the underground pipe gallery through linkage of a collection program and a control program of the server side, so that remote monitoring is realized;

the multi-source data acquisition system is used for acquiring the running state data of different equipment in the underground pipe gallery in real time so as to obtain the running state data of the different equipment;

and the alarm early warning system is used for generating a corresponding calculation task according to a set alarm rule and/or a reverse control rule, performing parallel calculation according to the acquired running state data of different equipment and the calculation task, and alarming and/or triggering corresponding direction control according to the reverse control rule when a trigger value is reached.

2. The system of claim 1, further comprising:

the three-dimensional visual digital twin system is used for displaying data of a whole pipeline gallery by means of a Geographic Information System (GIS) technology, displaying a model of any partition by means of a Building Information Model (BIM), displaying statistical data and real-time data which take the partition as a dimension in a view port range in a GIS scene under the condition of no abnormality, and displaying the statistical data and the real-time data in any partition under the BIM scene; and the data display of the corresponding topic is realized through the switching of different topics.

3. The system of claim 1, wherein the intelligent management and control system collects, via a collection program, the location of each partition within the piping lane, the availability of equipment, the operational status of equipment, the status of each fire zone drain pump, the status of ventilation devices, the status of lighting equipment, the status of fire detection equipment, ambient temperature and/or humidity data, oxygen content data, alarm signals, equipment parameter data, and inventory parameter data.

4. The system of claim 1, further comprising:

the sensing system of the Internet of things is used for connecting various devices and sensors of each subarea of the underground pipe gallery to construct an Internet of things sensing network;

the camera monitoring system is used for visually monitoring the field running state of various devices in the underground pipe gallery.

5. The system of claim 1, further comprising:

a rule configuration unit to: based on a knowledge base template, randomly combining equipment address variables, acquisition address variables and control address variables in a 0 code mode through a python script to generate different types of alarm rules and/or reverse control rules; wherein, any one of the alarm rules or the reverse control rules comprises: calculating a formula, an alarm value, an alarm action and a reverse control action; the knowledge base template comprises: an emergency scheme; the emergency scheme comprises the following steps: and prompting an emergency scheme and a control scheme of a reverse control device address variable and control address variable combination.

6. The system of claim 1, wherein the intelligent management and control system is further configured to: managing device address variables, acquisition address variables and control address variables of each system.

7. A method of centrally controlling the operational operation of a subterranean pipe gallery, the method comprising:

the intelligent management and control system is linked with the control program through the acquisition program of the server side to acquire and control different devices of the underground pipe gallery, so that remote monitoring is realized;

the multisource data acquisition system acquires the running state data of different equipment in the underground pipe gallery in real time to obtain the running state data of the different equipment;

the alarm early warning system generates a corresponding calculation task according to a set alarm rule and/or a reverse control rule, performs parallel calculation according to the acquired running state data of different equipment and the calculation task, and performs alarm and/or triggers corresponding direction control according to the reverse control rule when a trigger value is reached.

8. The method of claim 7, further comprising:

the three-dimensional visual digital twin system displays data of the whole pipeline gallery by means of a Geographic Information System (GIS) technology, displays a model of any subarea by means of a Building Information Model (BIM), displays statistical data and real-time data which take the subarea as a dimension in a view port range in a GIS scene under the condition of no abnormality, and displays the statistical data and the real-time data in any subarea under the BIM scene; and the data display of the corresponding topic is realized through the switching of different topics.

9. The method of claim 7, wherein the intelligent management and control system collects the location of each section within the piping lane, the utilization of equipment, the operational status of equipment, the status of each fire zone drain pump, the status of ventilation, the status of lighting, the status of fire detection equipment, ambient temperature and/or humidity data, oxygen content data, alarm signals, equipment parameter data, and inventory parameter data via a collection program.

10. The method of claim 7, further comprising:

the sensing system of the internet of things is connected with various devices and sensors of each subarea of the underground pipe gallery to construct a sensing network of the internet of things;

the camera monitoring system visually monitors the field running state of various devices in the underground pipe gallery.

11. The method of claim 7, further comprising:

randomly combining equipment address variables, acquisition address variables and control address variables in a 0 code mode by using a rule configuration unit based on a knowledge base template to generate different types of alarm rules and/or reverse control rules; wherein, any one of the alarm rules or the reverse control rules comprises: calculating a formula, an alarm value, an alarm action and a reverse control action; the knowledge base template comprises: an emergency scheme; the emergency scheme comprises the following steps: and prompting an emergency scheme and a control scheme of a reverse control device address variable and control address variable combination.

12. The method of claim 7, further comprising:

and managing the equipment address variables, the acquisition address variables and the control address variables of each system by using an intelligent management and control system.

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