技术领域:Technical field:
本发明属于地下综合管廊数据分析技术领域,涉及一种地下综合管廊设备运用率控制系统,具体是一种针对地下管廊以及管廊内的管道和设备在运行过程中所产生的数据进行统计、测算和分析的装置及其系统。The invention belongs to the technical field of data analysis of underground comprehensive pipe gallery, and relates to a control system for the utilization rate of underground comprehensive pipe gallery equipment, in particular to a data analysis system for underground pipe gallery and pipelines and equipment in the pipe gallery during operation. Devices and systems for statistics, measurement and analysis.
背景技术:Background technique:
目前,随着现代城市文明建设的不断创新和环境优美的进步要求,城市的运行设施和管线正在趋于向地下管网或集聚化方向发展。城市地下综合管廊是指在城市地下用于集中铺设电力、通信、广播电视、给水、排水、热力、燃气等市政管线的公共隧道,其在推进统筹各类市政管线规划、建设和解决反复开挖路面、架空线网密集、管线事故频发等问题上具有突出的效果,因此建设城市地下智慧综合管廊是有利于保障城市安全、完善城市功能、美化城市景观、促进城市集约高效和转型发展的非常重要的一部分,是建设智慧城市重要的基础设施之一,是国家重点支持的一项民生工程。At present, with the continuous innovation of modern urban civilization construction and the progressive requirements of a beautiful environment, urban operating facilities and pipelines are tending to develop in the direction of underground pipeline networks or agglomeration. Urban underground comprehensive pipeline corridor refers to the public tunnel used to lay municipal pipelines such as electric power, communication, radio and television, water supply, drainage, heat, gas, etc. under the city. It has outstanding effects on problems such as digging roads, dense overhead line networks, and frequent pipeline accidents. Therefore, the construction of urban underground smart integrated pipe corridors is conducive to ensuring urban safety, improving urban functions, beautifying urban landscapes, and promoting urban intensive and efficient transformation. Development It is one of the important infrastructures for building a smart city and a livelihood project supported by the state.
现有的地下综合管廊的运用率控制技术、安全分析技术和运营数据分析技术,依然主要依托于传统的人工巡检得到的数据进行人工分析和运算,较少的运用大数据技术、互联网技术和物联网技术,对于管廊的具体运行状况分析、安全状况分析、设备和管道的运行状态分析和故障率的分析测算仍然不能实时的更新和快速的掌握;对于管廊的运行过程中采集不到的数据也无法进行很好的推算和模拟。中国专利申请号CN201710569770.1公开了一种城市地下综合管廊监测预警系统及其方法,该系统和方法仅针对地下综合管廊的监测和预警的管理、控制和分析,对地下综合管廊内的设备和管道的运用率分析和数据模拟分析等方面并未涉及。The existing utilization rate control technology, safety analysis technology and operation data analysis technology of the underground utility tunnel still mainly rely on the data obtained by traditional manual inspection for manual analysis and calculation, and seldom use big data technology and Internet technology And the Internet of Things technology, the specific operation status analysis, safety status analysis, equipment and pipeline operation status analysis and failure rate analysis and calculation of the pipe gallery still cannot be updated in real time and quickly grasped; The data obtained cannot be well calculated and simulated. Chinese patent application number CN201710569770.1 discloses a monitoring and early warning system and method for urban underground utility tunnels. The utilization rate analysis and data simulation analysis of equipment and pipelines are not involved.
因此,寻求设计一种以“物联网、大数据云计算、移动互联网”等信息技术为支撑,针对管廊运营中的各类数据进行整体的和全方位的测算分析,同时兼顾灾难事故预警和设备利用率分析,消除各类信息孤岛问题的地下综合管廊设备运用率控制系统具有重要的实际应用价值。Therefore, it is seeking to design an information technology such as "Internet of Things, Big Data Cloud Computing, and Mobile Internet" as the support, to conduct overall and all-round calculation and analysis of various data in the operation of the utility tunnel, and at the same time take into account disaster early warning and The analysis of equipment utilization rate and the control system of equipment utilization rate of underground comprehensive pipe gallery to eliminate various information island problems have important practical application value.
发明内容:Invention content:
本发明的目的在于克服现有技术存在的缺点,寻求设计提供一种地下综合管廊设备运用率控制系统,充分利用大数据技术、互联网技术和物联网技术,建立一体化的地下管廊智慧型数据分析模拟系统,实现对城市地下综合管廊的安全预测分析和故障率分析,并能够进行盲点数据模拟,实现地下管廊运营的数据化、可控化和模拟化。The purpose of the present invention is to overcome the shortcomings of the existing technology, seek to design and provide a control system for the utilization rate of underground comprehensive pipe gallery equipment, make full use of big data technology, Internet technology and Internet of Things technology, and establish an integrated intelligent underground pipe gallery The data analysis simulation system realizes the safety prediction analysis and failure rate analysis of the urban underground utility tunnel, and can perform blind spot data simulation to realize the digitalization, controllability and simulation of the underground utility tunnel operation.
为了实现上述目的,本发明涉及的涉及的地下综合管廊设备运用率控制系统主体结构包括硬件模块和程序处理模块。In order to achieve the above purpose, the main structure of the utilization rate control system of the underground comprehensive utility gallery equipment involved in the present invention includes a hardware module and a program processing module.
本实施例涉及的地下综合管廊设备运用率控制系统硬件模块包括数据处理终端和数据采集终端;数据处理终端包括:手动录入装置、触摸录入装置、电源装置A、数据处理装置A、数据存储装置、图形处理装置、图文显示装置和网络连接装置A;数据采集终端包括:网络连接装置B、数据处理装置B、电源装置B和数据采集装置;数据采集装置包括:管廊形变监测装置、管道运行状态监测装置、温度监测装置、湿度监测装置、有害气体监测装置、震动监测装置和影像采集装置;The hardware module of the utilization rate control system for underground comprehensive utility gallery equipment involved in this embodiment includes a data processing terminal and a data collection terminal; the data processing terminal includes: a manual input device, a touch input device, a power supply device A, a data processing device A, and a data storage device , a graphics processing device, a graphic display device and a network connection device A; the data collection terminal includes: a network connection device B, a data processing device B, a power supply device B and a data collection device; the data collection device includes: a pipe gallery deformation monitoring device, a pipeline Operating status monitoring device, temperature monitoring device, humidity monitoring device, harmful gas monitoring device, vibration monitoring device and image acquisition device;
本实施例涉及的地下综合管廊设备运用率控制系统程序处理模块包括:数据驾驶舱模块、智能数据报表模块、多维度分析模块、动态数据模型模块、故障率分析模块、安全分析模块、空置率分析模块和数据模拟模块。The program processing module of the underground comprehensive utility gallery equipment utilization rate control system involved in this embodiment includes: a data cockpit module, an intelligent data report module, a multi-dimensional analysis module, a dynamic data model module, a failure rate analysis module, a safety analysis module, and a vacancy rate module. Analysis module and data simulation module.
本发明涉及的地下综合管廊设备运用率控制系统在具体运转时,实现以下程序步骤:The utilization rate control system of the underground comprehensive utility gallery equipment involved in the present invention realizes the following procedural steps during specific operation:
(1)系统指令输入:管理人员在数据处理终端的控制界面使用手动录入装置或触摸录入装置选择调取查看某一程序模块进行数据分析的指令;(1) System command input: the manager uses a manual input device or a touch input device to select an instruction to view a certain program module for data analysis on the control interface of the data processing terminal;
(2)系统指令处理:数据处理装置A识别指令后,将指令转换成电信号;如果该指令为现有数据分析指令,则运行步骤(3)调取数据并进行分析后,传输给图形处理装置进行图形化处理,然后运行步骤(9);如果该指令为实时数据分析或现有数据与实时数据对比分析指令,则运行步骤(4);(2) System command processing: After the data processing device A recognizes the command, it converts the command into an electrical signal; if the command is an existing data analysis command, then run step (3) to retrieve and analyze the data, and then transmit it to the graphics processing The device performs graphical processing, and then executes step (9); if the instruction is real-time data analysis or a comparative analysis instruction between existing data and real-time data, then executes step (4);
(3)现有数据调取:数据存储模块接收到数据处理装置A发出的数据请求后,从存储器中筛选出指令所需要的数据信息,并传输给数据处理装置A;(3) Existing data retrieval: after the data storage module receives the data request sent by the data processing device A, it screens out the data information required by the instruction from the memory, and transmits it to the data processing device A;
(4)系统指令发出:数据处理装置A传输给网络连接装置A,网络连接装置A将接收到的实时数据分析指令通过网络传输给网络连接装置B;(4) System command is issued: the data processing device A transmits to the network connection device A, and the network connection device A transmits the received real-time data analysis command to the network connection device B through the network;
(5)采集指令接收:网络连接装置B将接收到的指令传输给数据处理装置B,并由数据处理装置B对指令识别处理后,根据具体的指令要求向一种或多种数据采集装置发出调取数据指令;(5) Collection command reception: the network connection device B transmits the received command to the data processing device B, and after the data processing device B recognizes and processes the command, it sends to one or more data collection devices according to specific command requirements Call data command;
(6)采集数据发送:数据采集装置接收到指令后将采集到的数据传输给数据处理装置B,数据处理装置B将接收到的数据进行初步处理并转化成电信号后传输给网络连接装置B;(6) Collected data transmission: After receiving the instruction, the data collection device transmits the collected data to the data processing device B, and the data processing device B performs preliminary processing on the received data and converts it into an electrical signal before transmitting it to the network connection device B ;
(7)采集数据上传:网络连接装置B将采集到的实时数据通过网络传输给网络连接装置A;网络连接装置A将数据传输给数据处理装置A;(7) Collecting data and uploading: the network connection device B transmits the collected real-time data to the network connection device A through the network; the network connection device A transmits the data to the data processing device A;
(8)数据分析处理:数据处理装置A接收到数据信息后,若指令为实时数据分析指令,则根据指令的要求进行数据的分析处理,将分析得出的结果按照指令的要求由图形处理装置进行图形化处理,并运行步骤(9);若指令为现有与实时数据对比分析指令,则运行步骤(3)调取数据存储装置中的现有数据后,再将实时数据和现有数据进行对比数据分析,将分析得出的结果按照指令的要求由图形处理装置进行图形化处理,并运行步骤(9);(8) Data analysis and processing: after the data processing device A receives the data information, if the instruction is a real-time data analysis instruction, then the analysis and processing of the data is carried out according to the requirements of the instruction, and the result of the analysis is processed by the graphics processing device according to the requirements of the instruction. Carry out graphical processing, and run step (9); if the command is an existing and real-time data comparison analysis command, then run step (3) to transfer the existing data in the data storage device, and then compare the real-time data and the existing data Perform comparative data analysis, and perform graphical processing on the analyzed results by the graphics processing device according to the requirements of the instruction, and run step (9);
(9)数据信息输出:图形处理装置将分析处理后的数据和图表传输给图文显示装置,由图文显示装置进行显示输出。(9) Data information output: the graphic processing device transmits the analyzed and processed data and graphs to the graphic display device, and the graphic display device performs display and output.
本发明与现有技术相比,利用人工智能技术、大数据技术和互联网技术,解决了故障率分析不准、运营成本失控和空置率不明确等问题,通过结构化的数据收集分析系统和计算机网络技术,将各个独立应用子系统的数据集成到相互关联、统一协调和综合运算的平台中,使监测和监控资源达到充分共享,实现数据集中共享,构建成一个强大的可视化的地下管廊设备运用率控制装置及其系统;其设计理念科学、技术方案先进,控制原理可靠,操作使用便捷,实时可控性好,应用环境友好。Compared with the prior art, the present invention uses artificial intelligence technology, big data technology and Internet technology to solve the problems of inaccurate failure rate analysis, out-of-control operating cost and unclear vacancy rate, etc., through structured data collection and analysis system and computer Network technology integrates the data of each independent application subsystem into an interrelated, unified coordination and comprehensive computing platform, so that monitoring and monitoring resources can be fully shared, data can be shared centrally, and a powerful and visualized underground pipe corridor equipment can be built The utilization rate control device and its system; its design concept is scientific, the technical scheme is advanced, the control principle is reliable, the operation is convenient, the real-time controllability is good, and the application environment is friendly.
附图说明:Description of drawings:
图1为本发明涉及的地下综合管廊设备运用率控制系统的主体结构原理示意框图。Fig. 1 is a schematic block diagram of the principle of the main structure of the equipment utilization rate control system of the underground comprehensive utility gallery involved in the present invention.
图2为本发明涉及的地下综合管廊设备运用率控制系统的程序处理模块示意框图。Fig. 2 is a schematic block diagram of the program processing module of the utilization rate control system of the underground comprehensive utility gallery equipment involved in the present invention.
图3为本发明涉及的地下综合管廊设备运用率控制系统具体运转时工作步骤原理示意框图。Fig. 3 is a schematic block diagram of working steps and principles during specific operation of the equipment utilization rate control system of the underground comprehensive utility gallery involved in the present invention.
具体实施方式:Detailed ways:
下面结合附图并通过实施例进一步描述本发明的具体实施方案。The specific implementation of the present invention will be further described below in conjunction with the accompanying drawings and examples.
实施例1:Example 1:
本实施例涉及的地下综合管廊设备运用率控制系统主体结构包括硬件模块和程序处理模块。The main structure of the equipment utilization rate control system for the underground comprehensive utility gallery involved in this embodiment includes a hardware module and a program processing module.
本实施例涉及的地下综合管廊设备运用率控制系统硬件模块包括数据处理终端和数据采集终端;数据处理终端包括:手动录入装置、触摸录入装置、电源装置A、数据处理装置A、数据存储装置、图形处理装置、图文显示装置和网络连接装置A;数据采集终端包括:网络连接装置B、数据处理装置B、电源装置B和数据采集装置;数据采集装置包括:管廊形变监测装置、管道运行状态监测装置、温度监测装置、湿度监测装置、有害气体监测装置、震动监测装置和影像采集装置;The hardware module of the utilization rate control system for underground comprehensive utility gallery equipment involved in this embodiment includes a data processing terminal and a data collection terminal; the data processing terminal includes: a manual input device, a touch input device, a power supply device A, a data processing device A, and a data storage device , a graphics processing device, a graphic display device and a network connection device A; the data collection terminal includes: a network connection device B, a data processing device B, a power supply device B and a data collection device; the data collection device includes: a pipe gallery deformation monitoring device, a pipeline Operating status monitoring device, temperature monitoring device, humidity monitoring device, harmful gas monitoring device, vibration monitoring device and image acquisition device;
所述的手动录入装置和触摸录入装置与数据处理装置电信息连接;电源装置A与数据处理装置相连接;数据处理装置与数据存储装置、图形处理装置电信息连接;数据存储装置、图形处理装置与图文显示装置电信息连接;网络连接装置A与数据处理装置电信息连接;数据处理终端的网络连接装置A与数据采集终端的网络连接装置B通过网络连接;网络连接装置B与数据处理装置B 电信息连接;电源装置B与数据处理装置B相连接;管廊形变监测装置、管道运行状态监测装置、温度监测装置、湿度监测装置、有害气体监测装置、震动监测装置、影像采集装置与数据处理装置B电信息连接;The manual input device and the touch input device are electrically connected to the data processing device; the power supply unit A is connected to the data processing device; the data processing device is connected to the data storage device and the graphics processing device; the data storage device and the graphics processing device The electrical information connection with the graphic display device; the electrical information connection between the network connection device A and the data processing device; the network connection device A of the data processing terminal and the network connection device B of the data collection terminal are connected through the network; the network connection device B and the data processing device B electrical information connection; power supply unit B is connected to data processing unit B; pipeline deformation monitoring device, pipeline operation status monitoring device, temperature monitoring device, humidity monitoring device, harmful gas monitoring device, vibration monitoring device, image acquisition device and data The electrical information connection of the processing device B;
所述手动录入装置和触摸录入装置用于对地下综合管廊设备运用率控制系统进行控制、输入指令和人工输入数据;所述电源装置A用于给数据处理终端提供电能;所述数据处理装置A用于处理通过网络传输过来的数据,并将数据传输给数据存储装置进行存储,或传输给图形处理装置进行数据图形化处理;所述数据存储装置用于储存数据处理装置A或图形处理装置传输的数据;所述图形处理装置用于对数据进行图形化处理;所述图文显示装置用于根据指令需要显示文字化和图形化的数据;所述网络连接装置A用于连接网络,使数据处理终端和数据采集终端之间进行双向数据传输;所述网络连接装置B用于连接网络,使数据处理终端和数据采集终端之间进行双向数据传输;所述数据处理装置B用于接收和初步处理各传感器上传的数据,并处理应用接收到的数据处理终端发送的指令;所述电源装置B用于给数据采集终端提供电能;所述管廊形变监测装置用于监测管廊内部的形变状态;所述管道运行状态监测装置用于监测各个管道的运行状态;所述温度监测装置用于监测管廊的温度状态;所述湿度监测装置用于监测管廊内部湿度,是否发生液体泄漏等故障;所述有害气体监测装置用于监测管廊内的有害气体是否超标;所述震动监测装置用于监测管廊内部的振动情况;所述影像采集装置用于采集管廊内部的影像数据。The manual input device and the touch input device are used to control the utilization rate control system of the underground comprehensive pipe gallery equipment, input instructions and manually input data; the power supply device A is used to provide power for the data processing terminal; the data processing device A is used to process the data transmitted through the network, and transmit the data to the data storage device for storage, or to the graphics processing device for data graphics processing; the data storage device is used to store the data processing device A or the graphics processing device The data transmitted; the graphics processing device is used to graphically process the data; the graphic display device is used to display textual and graphical data according to the instructions; the network connection device A is used to connect to the network, so that Two-way data transmission is performed between the data processing terminal and the data collection terminal; the network connection device B is used to connect the network to enable two-way data transmission between the data processing terminal and the data collection terminal; the data processing device B is used for receiving and Preliminarily process the data uploaded by each sensor, and process the instructions sent by the data processing terminal received by the application; the power supply device B is used to provide electric energy for the data collection terminal; the pipe gallery deformation monitoring device is used to monitor the deformation inside the pipe gallery state; the pipeline operation status monitoring device is used to monitor the operation status of each pipeline; the temperature monitoring device is used to monitor the temperature state of the pipe gallery; the humidity monitoring device is used to monitor the internal humidity of the pipe gallery, whether liquid leakage occurs, etc. Fault; the harmful gas monitoring device is used to monitor whether the harmful gas in the pipe gallery exceeds the standard; the vibration monitoring device is used to monitor the vibration inside the pipe gallery; the image acquisition device is used to collect image data inside the pipe gallery.
本实施例涉及的地下综合管廊设备运用率控制系统程序处理模块包括:数据驾驶舱模块、智能数据报表模块、多维度分析模块、动态数据模型模块、故障率分析模块、安全分析模块、空置率分析模块和数据模拟模块;The program processing module of the underground comprehensive utility gallery equipment utilization rate control system involved in this embodiment includes: a data cockpit module, an intelligent data report module, a multi-dimensional analysis module, a dynamic data model module, a failure rate analysis module, a safety analysis module, and a vacancy rate module. Analysis module and data simulation module;
所述的数据驾驶舱模块能够将需要重点关注的信息凸显在首页上,针对性的加强对各个区域及管道的信息监控力度,系统提供了表格和曲线两种数据读取显示方式,同时对管廊各项指标数据进行了对比,以柱状图形象的表现出来,用户点击查询可以将各分类的曲线信息直观展示出来,极大增强数据读取和分析速率,有效的提升突发事件的响应处理能力;The data cockpit module can highlight the information that needs to be focused on on the home page, and strengthen the information monitoring of various areas and pipelines in a targeted manner. The system provides two data reading and display methods: tables and curves. The data of various indicators in the gallery are compared and displayed in the image of a histogram. Users can directly display the curve information of each category by clicking on the query, which greatly enhances the speed of data reading and analysis, and effectively improves the response to emergencies. ability;
所述的智能数据报表模块能够通过大数据实时数据库,存储海量管廊日常运维数据信息,通过云计算数据抽取,把数据源源不断的抽取出来,经过多维建模形成的立方体结构;每一个立方体描述一个业务主题,将多维立方体中的数据信息以丰富多彩的数据报表方式展现出来;The intelligent data reporting module can store a large amount of daily operation and maintenance data information of the pipe gallery through the big data real-time database, extract the data continuously through the cloud computing data extraction, and form a cube structure through multi-dimensional modeling; each cube Describe a business theme and display the data information in the multidimensional cube in a colorful data report form;
所述的多维度分析模块能够深度挖掘客户需求,结合大数据云计算的数据信息,直观生动的将各种业务数据、监测数据,通过不同种类的数据图表展示出来,丰富系统的数据挖掘和数据钻取功能,为客户的生产运营提供生动的数据素材;The multi-dimensional analysis module can dig deep into customer needs, combined with the data information of big data cloud computing, intuitively and vividly display various business data and monitoring data through different types of data charts, enriching the system's data mining and data Drilling function to provide vivid data materials for customers' production and operation;
所述的动态数据模型模块能够根据管廊内部各类管线的业务情况,建立不同管线分析模型,能够针对爆管、联通和管阀等各类情况实现智能模拟、智能调度,丰富了管廊运维部门对突发事件的应急指挥能力和手段;The dynamic data model module described above can establish different pipeline analysis models according to the business conditions of various pipelines inside the pipeline corridor, and can realize intelligent simulation and intelligent scheduling for various situations such as pipe burst, China Unicom, and pipe valves, which enriches the pipeline operation of the pipeline corridor. The emergency command capabilities and means of the maintenance department for emergencies;
所述的故障率分析模块能够将某一时间段内或某一区间段内综合管廊的管线设备和运行维护设备等出现故障的设备进行故障率的分析,按照故障率的高低制作成具有明显对比的表格,便于工作人员有针对性和预防性的对故障率高的设备或管线进行排查巡检;The failure rate analysis module can analyze the failure rate of equipment that fails, such as pipeline equipment and operation and maintenance equipment in the comprehensive utility gallery within a certain period of time or within a certain interval, and make a failure rate according to the level of the failure rate. The comparison table is convenient for the staff to conduct targeted and preventive inspections on equipment or pipelines with high failure rates;
所述的安全分析模块能够利用大数据技术,将前期综合管廊的运行环境状态和设备运行状态等数据进行整合分析,进行综合管廊安全性能的评估预测,可以及时发现安全薄弱的区域或设备,防患于未然;The safety analysis module can use big data technology to integrate and analyze data such as the operating environment status and equipment operating status of the comprehensive utility corridor in the early stage, and perform evaluation and prediction of the safety performance of the comprehensive utility corridor, so that areas or equipment with weak security can be found in time , prevent problems before they happen;
所述的空置率分析模块能够就一定区间或时间内的设备和管线运用率和功效进行分析评价,将空置率较高的设备或管线制作成图表或书面的形势,并对空置原因进行分析总结,保证设备或管线的利用率,避免资源浪费;The vacancy rate analysis module can analyze and evaluate the utilization rate and effectiveness of equipment and pipelines within a certain interval or time, make equipment or pipelines with high vacancy rates into charts or written situations, and analyze and summarize the reasons for vacancy , to ensure the utilization of equipment or pipelines and avoid waste of resources;
所述的数据模拟模块能够以模块传感器监测到的讯息和三维地理数据为基础数据,将综合管廊内部数据的不足部分通过运算内插或者预算出来,并以图形色彩的方式显示在三维地理数据上,可以针对可能出现问题的盲点提前做出处理方案。The data simulation module can use the information monitored by the module sensor and the three-dimensional geographic data as the basic data, interpolate or estimate the insufficient part of the internal data of the comprehensive utility corridor, and display it on the three-dimensional geographic data in the form of graphics and colors. On the other hand, it is possible to make a treatment plan in advance for blind spots that may cause problems.
实施例2:Example 2:
本实施例涉及的地下综合管廊设备运用率控制系统的硬件模块和程序处理模块与实施例1相同,本实施例主要描述地下综合管廊设备运用率控制系统在具体运转时,实现以下程序步骤:The hardware module and program processing module of the utilization rate control system of the underground comprehensive pipe gallery equipment involved in this embodiment are the same as those in Embodiment 1. This embodiment mainly describes the following program steps to be implemented by the underground comprehensive pipe gallery equipment utilization rate control system during specific operation. :
(1)系统指令输入:管理人员在数据处理终端的控制界面使用手动录入装置或触摸录入装置选择调取查看某一程序模块进行数据分析的指令;(1) System command input: the manager uses a manual input device or a touch input device to select an instruction to view a certain program module for data analysis on the control interface of the data processing terminal;
(2)系统指令处理:数据处理装置A识别指令后,将指令转换成电信号;如果该指令为现有数据分析指令,则运行步骤(3)调取数据并进行分析后,传输给图形处理装置进行图形化处理,然后运行步骤(9);如果该指令为实时数据分析或现有数据与实时数据对比分析指令,则运行步骤(4);(2) System command processing: After the data processing device A recognizes the command, it converts the command into an electrical signal; if the command is an existing data analysis command, then run step (3) to retrieve and analyze the data, and then transmit it to the graphics processing The device performs graphical processing, and then executes step (9); if the instruction is real-time data analysis or a comparative analysis instruction between existing data and real-time data, then executes step (4);
(3)现有数据调取:数据存储模块接收到数据处理装置A发出的数据请求后,从存储器中筛选出指令所需要的数据信息,并传输给数据处理装置A;(3) Existing data retrieval: after the data storage module receives the data request sent by the data processing device A, it screens out the data information required by the instruction from the memory, and transmits it to the data processing device A;
(4)系统指令发出:数据处理装置A传输给网络连接装置A,网络连接装置A将接收到的实时数据分析指令通过网络传输给网络连接装置B;(4) System command is issued: the data processing device A transmits to the network connection device A, and the network connection device A transmits the received real-time data analysis command to the network connection device B through the network;
(5)采集指令接收:网络连接装置B将接收到的指令传输给数据处理装置 B,并由数据处理装置B对指令识别处理后,根据具体的指令要求向一种或多种数据采集装置发出调取数据指令;(5) Collection command reception: the network connection device B transmits the received command to the data processing device B, and after the data processing device B recognizes and processes the command, it sends to one or more data collection devices according to specific command requirements Call data command;
(6)采集数据发送:数据采集装置接收到指令后将采集到的数据传输给数据处理装置B,数据处理装置B将接收到的数据进行初步处理并转化成电信号后传输给网络连接装置B;(6) Collected data transmission: After receiving the instruction, the data collection device transmits the collected data to the data processing device B, and the data processing device B performs preliminary processing on the received data and converts it into an electrical signal before transmitting it to the network connection device B ;
(7)采集数据上传:网络连接装置B将采集到的实时数据通过网络传输给网络连接装置A;网络连接装置A将数据传输给数据处理装置A;(7) Collecting data and uploading: the network connection device B transmits the collected real-time data to the network connection device A through the network; the network connection device A transmits the data to the data processing device A;
(8)数据分析处理:数据处理装置A接收到数据信息后,若指令为实时数据分析指令,则根据指令的要求进行数据的分析处理,将分析得出的结果按照指令的要求由图形处理装置进行图形化处理,并运行步骤(9);若指令为现有与实时数据对比分析指令,则运行步骤(3)调取数据存储装置中的现有数据后,再将实时数据和现有数据进行对比数据分析,将分析得出的结果按照指令的要求由图形处理装置进行图形化处理,并运行步骤(9);(8) Data analysis and processing: after the data processing device A receives the data information, if the instruction is a real-time data analysis instruction, then the analysis and processing of the data is carried out according to the requirements of the instruction, and the result of the analysis is processed by the graphics processing device according to the requirements of the instruction. Carry out graphical processing, and run step (9); if the command is an existing and real-time data comparison analysis command, then run step (3) to transfer the existing data in the data storage device, and then compare the real-time data and the existing data Perform comparative data analysis, and perform graphical processing on the analyzed results by the graphics processing device according to the requirements of the instruction, and run step (9);
(9)数据信息输出:图形处理装置将分析处理后的数据和图表传输给图文显示装置,由图文显示装置进行显示输出。(9) Data information output: the graphic processing device transmits the analyzed and processed data and graphs to the graphic display device, and the graphic display device performs display and output.
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201810708710.8ACN108573072A (en) | 2018-07-02 | 2018-07-02 | A control system for equipment utilization rate of underground comprehensive utility gallery |
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201810708710.8ACN108573072A (en) | 2018-07-02 | 2018-07-02 | A control system for equipment utilization rate of underground comprehensive utility gallery |
| Publication Number | Publication Date |
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| CN108573072Atrue CN108573072A (en) | 2018-09-25 |
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| CN201810708710.8APendingCN108573072A (en) | 2018-07-02 | 2018-07-02 | A control system for equipment utilization rate of underground comprehensive utility gallery |
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