LU505378B1 - Safety management system for hydraulic engineering construction and emergency command method thereof - Google Patents
Safety management system for hydraulic engineering construction and emergency command method thereof Download PDFInfo
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Abstract
The present invention discloses a safety management system for hydraulic engineering construction, and relates to the field of hydraulic engineering. The system includes a power supply module, specifically, an output end of the power supply module is connected to an input end of a data sensing module, and an output end of the data sensing module is connected to an input end of a communication transmission module. According to the present invention, various safety risks and safety accidents in hydraulic engineering construction are prevented and managed by various safety modules in the safety management module, so as to reduce the probability of safety risks in hydraulic engineering construction by means of automation and intelligent operation of the system.
Description
SAFETY MANAGEMENT SYSTEM FOR HYDRAULIC ENGINEERING 0505378
CONSTRUCTION AND EMERGENCY COMMAND METHOD THEREOF
The present invention relates to the field of hydraulic engineering, in particular to a safety management system for hydraulic engineering construction and an emergency command method thereof.
China's hydraulic engineering industry is developing rapidly and will be in a period of steady construction for a long time. However, in recent years, there have been frequent construction safety accidents in the hydraulic engineering industry, and most of them are caused by problems in safety management. The construction of hydraulic engineering has certain particularity, for example, hydraulic engineering 1s usually huge and the site where the projects are located often covers a wide area; the construction period of hydraulic engineering is long, and is greatly influenced by the natural environment; hydraulic engineering usually needs more manpower and construction machines, and the manpower and construction machines are scattered. It is precisely because of the particularity of hydraulic engineering construction that it brings challenges to the safety management of construction site. Therefore, a safety management system for hydraulic engineering construction 1s required.
However, the common safety management system for hydraulic engineering construction can not reduce the safety risks in hydraulic construction through the automation and intelligent operation of the system, so that the safety risks are high.
An objective of the present invention is to provide a safety management system for hydraulic engineering construction and an emergency command method thereof, so as to solve the problems raised in the above background.
In order to achieve the above objective, the present invention provides the following technical solution: a safety management system for hydraulic engineering construction includes a power supply module, specifically, an output end of the power supply module is connected to an input end of a data sensing module, an output end of the data sensing module is connected to an input end of a communication transmission module, an output end of the communication transmission module is connected to an input end of a processor module, an output end of the 905378 processor module is connected to an input end of a service management module, an output end of the service management module is connected to an input end of a safety management module, and an output end of the safety management module is connected to an input end of an early warning reminding module.
Further, a safety knowledge database module, a construction safety monitoring module and a safety risk calculation module are arranged at an interior of the safety management module, and output ends of the safety knowledge database module, the construction safety monitoring module and the safety risk calculation module are connected to the input end of the the safety management module.
Further, a hidden danger rectification module and an evaluation module are arranged at an interior of the service management module, and output ends of the hidden danger rectification module and the evaluation module are connected to the input end of the service management module.
Further, an emergency command method of the safety management system for hydraulic engineering construction includes the following steps: information collection: collecting hydraulic engineering information and geographic information from a hydraulic engineering information database and a geographic information database respectively, and collecting emergency scene information and hydraulic engineering power grid information from a hydraulic engineering power grid database in real time; information processing: analyzing the hydraulic engineering information, the geographic information and the hydraulic engineering power grid information, and parsing hydraulic engineering information data, geographic information data and hydraulic engineering power grid information data into data in preset formats to obtain preset format data; emergency strategy generating: automatically generating emergency information data with emergency strategies and emergency repair safety routes by combining accident types and real-time emergency scene information, the hydraulic engineering power grid information, the geographic information and the hydraulic engineering information; data storage: storing the emergency information data, the hydraulic engineering information data, the geographic information data and the hydraulic engineering power grid data information in preset formats in an emergency information data server, a hydraulic engineering information 905378 server, a geographic information server and a hydraulic engineering power grid information server respectively; information integration: extracting the emergency information data, the hydraulic engineering information data, the geographic information data and the hydraulic engineering power grid information data from a data storage module and associating them to obtain panoramic display data; information interactive query: accessing immediately and dynamically inquiring the hydraulic engineering information, emergency repair route and material supply point in an accident section according to address information input by a user, so as to realize information interaction between the site and a command center; and emergency command: receiving the panoramic display data and conducting remote video command on the emergency scene.
Compared with the prior art, the present invention has the following beneficial effects.
According to the present invention, various safety risks and safety accidents in hydraulic engineering construction are prevented and managed by various safety modules in the safety management module, so as to reduce the probability of safety risks in hydraulic engineering construction by means of automation and intelligent operation of the system.
FIG. 1 is a block diagram of a safety management system for hydraulic engineering construction of the present invention;
FIG. 2 is a block diagram of a safety management module of the present invention; and
FIG. 3 is a service management module of the present invention.
Among them: 1-power supply module; 2-data sensing module; 3-communication transmission module; 4-processor module; 5-service management module; 6-safety management module; 7-early warning reminding module; 8-safety knowledge database module; 9-construction safety monitoring module; 10-safety risk calculation module; 11-hidden danger rectification module; and 12-evaluation module.
The technical solutions in the examples of the present invention will be clearly and completely described below with reference to the attached drawings. Obviously, the described 905378 examples are only some exampled of the present invention, rather than all examples.
As shown in FIGs. 1-3, an example provided by the present invention is as follows: a safety management system for hydraulic engineering construction includes a power supply module 1, specifically, an output end of the power supply module 1 is connected to an input end of a data sensing module 2, an output end of the data sensing module 2 is connected to an input end of a communication transmission module 3, an output end of the communication transmission module 3 is connected to an input end of a processor module 4, an output end of the processor module 4 is connected to an input end of a service management module 5, an output end of the service management module 5 is connected to an input end of a safety management module 6, and an output end of the safety management module 6 is connected to an input end of an early warning reminding module 7.
A safety knowledge database module 8, a construction safety monitoring module 9 and a safety risk calculation module 10 are arranged at an interior of the safety management module 6, and output ends of the safety knowledge database module 8, the construction safety monitoring module 9 and the safety risk calculation module 10 are connected to the input end of the the safety management module 6.
A hidden danger rectification module 11 and an evaluation module 12 are arranged at an interior of the service management module 5, and output ends of the hidden danger rectification module 11 and the evaluation module 12 are connected to the input end of the service management module 5.
The data sensing module 2 designs data acquisition software in a sensing layer based on the existing 14.56 MHz radio frequency identification module. The radio frequency identification module reads and writes received tag data through a RS264 communication interface, and then transmits the read-written tag data to the upper computer; a communication function of a radio frequency identification module window is realized by calling SeriaPort component, so as to operate database; data in an electronic tag are collected by sectors by selecting connection between a serial port and the radio frequency identification module; and before the tag data are collected, sector number is set accordingly, and the data are updated and stored based on a network programming interface.
The communication transmission module 3 is designed based on a protocol stack 5 905378
Zigbee2007, and provides an application program interface function. Calling API may realize the following functions: coordinator node may automatically establish a network; terminal node may automatically discover the coordinator node, and may automatically bind with the coordinator 5 node if joining in the network; with a sending mode of end-to-end confirmation, the terminal node may send the collected data to the coordinator node periodically; and if the terminal node does not receive a confirmation message from the coordinator node, it will unbind from the coordinator node, and then rediscover and bind with another coordinator node.
The processor module 4 performs data management and information processing of hydraulic construction safety management in an application management layer, outputs graphic reports in a man-machine interface, and realizes construction information query through an information management system; the processor module 4 analyzes characteristics of hydraulic construction safety attributes in the data layer, and construct a monitoring database of the safety management system for hydraulic construction; and the processor module 4 constructs a server and a Internet of Things network structure of the safety management system for hydraulic construction in the operation support layer.
Safety inspection inside the hidden danger rectification module 11 involves the constructor, supervisor and government departments. When hidden dangers are found during daily inspection, safety personnel, supervisors or government personnel may upload inspection time, inspection location, hidden danger situations and rectification requirements through the module, and the system will automatically transmit the uploaded information to relevant rectification personnel and send a copy to the project manager and chief supervision engineer, and every step of rectification and acceptance may be queried in the system in real time until the rectification is implemented.
The evaluation module 12 sets evaluation standards for all work contents based on Standard
Jor Standardized Evaluation of Hydraulic Safety Production. Constructor may make self-evaluation through the module, and then supervisors and enterprise managers may comprehensively evaluate relevant personnel through the module. At the same time, the system has a function of summarizing and analyzing evaluation results.
The early warning reminding module 7 reminds the relevant personnel to handle online processes of other modules by messages and short messages in the system, and may also give an 905378 early warning for cases that are not handled for a long time, and keep files for responsible personnel who fails to handle within the handling period and submit the files to superior management personnel.
The safety knowledge database module 8 extracts relevant actual information through an intelligent inspection function, and compares the relevant actual information with theoretical information in the safety knowledge database to complete query and inspection of system data; the safety knowledge database mainly stores attribute data information of BIM members related to construction projects and a relationship among the members; the safety knowledge database mainly focuses on danger source information in the construction process of hydraulic engineering, and queries through a query specification of SQLServer, decomposes data into association rules of the specification and establishes an example to transform data mode and store in a structured storage mode; there is a certain topological relationship between data information in the database, mainly aiming at the unique mode of actual construction projects, and if the construction environments of hydraulic engineering and the construction methods of hydraulic engineering are different, then the topological relationship is also different; in the actual construction operation, the safety management personnel at the construction site of hydraulic engineering rationally arrange existing positions of materials and construction machinery and equipment of hydraulic engineering according to drawings and the relationship between the members in the hydraulic engineering; with the help of Revit plug-in, the database in the system is visually programmed, and the data information in the database is added and modified; and with Dynamo plug-in, internal member attributes of the system are extracted, and the topological relationship of the data is established through software to form a member topological management system for construction safety of hydraulic engineering, and generate the construction safety knowledge database for hydraulic engineering.
The construction safety monitoring module 9 uses WSN technology to obtain real-time location information and attribute information of people and things, and may track workers and equipment in the construction site of hydraulic engineering; the intelligent safety management function includes three steps: inspection and notification, receiving and result reporting; and in the module design, design is performed according to the inspection management logic business package, the logical business package is used to complete the inspection and management. 905378 operations, and the basic data layer of the system is used to classify the construction safety of hydraulic engineering. In order to effectively operate the risk management function of hydraulic engineering, safety influencing factors and sources are monitored, and solutions are formulated according to the risks. The construction safety early warning function of the system includes writing of safety plan, storage of dangerous goods and storage tanks in the construction site of hydraulic engineering, and emergency measures in case of unexpected leakage; and the source site that leads to potential safety risks is rectified to reduce the probability of dangerous situations from the source. A plan writing function of the system includes plan number, time and processing method, and adds relevant attribute information to help safety managers make emergency plans. The safety early warning function for hydraulic engineering construction also adds hydraulic engineering construction forms, describe result forms of accident management in detail, display the result forms circularly between pages, and encapsulate and store the plan of hydraulic engineering construction safety accident.
The safety risk calculation module 10 constructs a paired matrix based on the Internet of
Things technology, and calculates ratio of safety risks. When the matrix is inconsistent, a consistency index CI of the matrix is calculated based on a differentiation criterion by a relationship between a characteristic vector and a weight vector:
Cr = Lom" 8-1 where, n represents the sum of diagonal lines of paired matrices, Amax represents a characteristic root of risk. When multiple matrices are constructed in the system at the same time, an average of multiple consistency indexes is RI. A safety risk consistency ratio CR may be expressed as: CR=CI/RI; by calculating the safety risk consistency ratio of the matrix, an acceptable range of safety risks is obtained, and the safety risks of hydraulic engineering are managed by RFID and remote communication technology of the Internet of Things.
The emergency command method includes the following steps: information collection: collecting hydraulic engineering information and geographic information from a hydraulic engineering information database and a geographic information database respectively, and collecting emergency scene information and hydraulic engineering power grid information from a hydraulic engineering power grid database in real time; 0505378 information processing: analyzing the hydraulic engineering information, the geographic information and the hydraulic engineering power grid information, and parsing hydraulic engineering information data, geographic information data and hydraulic engineering power grid information data into data in preset formats to obtain preset format data; emergency strategy generating: automatically generating emergency information data with emergency strategies and emergency repair safety routes by combining accident types and real-time emergency scene information, the hydraulic engineering power grid information, the geographic information and the hydraulic engineering information; data storage: storing the emergency information data, the hydraulic engineering information data, the geographic information data and the hydraulic engineering power grid data information in preset formats in an emergency information data server, a hydraulic engineering information server, a geographic information server and a hydraulic engineering power grid information server respectively; information integration: extracting the emergency information data, the hydraulic engineering information data, the geographic information data and the hydraulic engineering power grid information data from the data storage module and associating them to obtain panoramic display data; information interactive query: accessing immediately and dynamically inquiring the hydraulic engineering information, emergency repair route and material supply point in an accident section according to address information input by a user, so as to realize information interaction between the site and a command center; and emergency command: receiving the panoramic display data and conducting remote video command on the emergency scene.
It is obvious to those skilled in the art that the present invention 1s not limited to the details of the above exemplary examples, but may be realized in other specific forms without departing from the spirit or essential characteristics of the present invention. Therefore, the examples are considered in all aspects as exemplary rather than restrictive, and the scope of the present invention is defined by the appended claims rather than the above descriptions, so it is intended to embrace all changes that come within the meaning and range of equivalents of the claims. Any
. . . 0, . LU505378 reference signs in the claims are not be construed as limiting the claims concerned.
Claims (4)
1. À safety management system for hydraulic engineering construction, comprising a power supply module (1), wherein an output end of the power supply module (1) is connected to an input end of a data sensing module (2), an output end of the data sensing module (2) is connected to an input end of a communication transmission module (3), an output end of the communication transmission module (3) is connected to an input end of a processor module (4), an output end of the processor module (4) is connected to an input end of a service management module (5), an output end of the service management module (5) is connected to an input end of a safety management module (6), and an output end of the safety management module (6) is connected to an input end of an early warning reminding module (7).
2. The safety management system for hydraulic engineering construction according to claim 1, wherein a safety knowledge database module (8), a construction safety monitoring module (9) and a safety risk calculation module (10) are arranged at an interior of the safety management module (6), and output ends of the safety knowledge database module (8), the construction safety monitoring module (9) and the safety risk calculation module (10) are connected to the input end of the the safety management module (6).
3. The safety management system for hydraulic engineering construction according to claim 1, wherein a hidden danger rectification module (11) and an evaluation module (12) are arranged at an interior of the service management module (5), and output ends of the hidden danger rectification module (11) and the evaluation module (12) are connected to the input end of the service management module (5).
4. An emergency command method of the safety management system for hydraulic engineering construction according to claim 1, comprising the following steps: information collection: collecting hydraulic engineering information and geographic information from a hydraulic engineering information database and a geographic information database respectively, and collecting emergency scene information and hydraulic engineering power grid information from a hydraulic engineering power grid database in real time; information processing: analyzing the hydraulic engineering information, the geographic information and the hydraulic engineering power grid information, and parsing hydraulic engineering information data, geographic information data and hydraulic engineering power end 905378 information data into data in preset formats to obtain preset format data; emergency strategy generating: automatically generating emergency information data with emergency strategies and emergency repair safety routes by combining accident types and real-time emergency scene information, the hydraulic engineering power grid information, the geographic information and the hydraulic engineering information; data storage: storing the emergency information data, the hydraulic engineering information data, the geographic information data and the hydraulic engineering power grid data information in preset formats in an emergency information data server, a hydraulic engineering information server, a geographic information server and a hydraulic engineering power grid information server respectively; information integration: extracting the emergency information data, the hydraulic engineering information data, the geographic information data and the hydraulic engineering power grid information data from a data storage module and associating them to obtain panoramic display data; information interactive query: accessing immediately and dynamically inquiring the hydraulic engineering information, emergency repair route and material supply point in an accident section according to address information input by a user, so as to realize information interaction between the site and a command center; and emergency command: receiving the panoramic display data and conducting remote video command on the emergency scene.
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| LU505378A LU505378B1 (en) | 2023-10-26 | 2023-10-26 | Safety management system for hydraulic engineering construction and emergency command method thereof |
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| Application Number | Priority Date | Filing Date | Title |
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| LU505378A LU505378B1 (en) | 2023-10-26 | 2023-10-26 | Safety management system for hydraulic engineering construction and emergency command method thereof |
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