CN114926969A - Intelligent laboratory safety control system and method - Google Patents
Intelligent laboratory safety control system and method Download PDFInfo
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Abstract
The application relates to the technical field of intelligent laboratory parts, in particular to an intelligent laboratory safety control system and a method, which comprises a perception judgment subsystem, a central processing subsystem, a terminal subsystem, an early warning subsystem and a communication subsystem; the invention realizes the monitoring of full-factor dynamic information, and realizes the real-time progress and multidimensional workload statistical display of the mass transfer and quality inspection service; the method comprises the steps of realizing the evaluation and risk reminding of the health degree of a metering system of an organization and a jurisdiction by acquiring all-element information and service capability data in real time, realizing the early warning of the quality risk of the whole service flow and the whole life cycle of assets by intelligently analyzing the data trend, and realizing the online real-time accurate evaluation of the service quality and suppliers by designing an evaluation index system of multi-dimensional data; the comprehensive test process safety risk prevention and control system is established by acquiring the sensing information of the equipment monitoring equipment, the intelligent safety protection equipment and the like in real time, and the comprehensive test process safety risk prevention and control system has a very strong market application prospect.
Description
Technical Field
The application relates to the technical field of intelligent laboratory parts, in particular to a safety control system and method for an intelligent laboratory.
Background
In the prior art, the system is connected with a bench body upper computer, the bench body is transformed, a digital laboratory system issues a verification task to the bench body upper computer through a TCP/IP protocol, the bench body upper computer executes a test according to the issued verification task, and the test completion background body upper computer also completes test result data and uploads the test result data to the digital laboratory system.
The digital laboratory system directly communicates with the platform body through a platform body communication protocol, the platform body directly executes the verification task in the system, after the platform body completes the test, the test result is directly displayed in the digital laboratory system, and the system can directly generate a verification report.
The data capture can be divided into two modes, firstly, the digital laboratory system captures data by reading a test bench body verification result database, and the test result of the bench body system is synchronized to the digital laboratory system under the condition of ensuring the data consistency; and secondly, generating report reading data information by the digital laboratory system through the bench body test result, and synchronizing the report reading data information to the digital laboratory system.
Therefore, the intelligent laboratory safety control system and method are provided, and comprehensive risk management and control is designed based on system online, business online and element full perception capability construction.
Disclosure of Invention
An object of the embodiments of the present application is to provide a system and a method for intelligent laboratory security control, which are used for designing comprehensive risk management and control based on system online, business online, and element full perception capability construction.
The invention is realized by the following technical scheme:
in a first aspect, the present invention provides an intelligent laboratory safety control system, comprising
The perception judgment subsystem is used for sensing and judging the environment and data in all directions and outputting a perception judgment result according to a preset processing standard value;
the central processing subsystem is used for setting a standard value for the perception judgment subsystem and simultaneously used as a control system main control center for generating an autonomous control instruction or generating a control instruction after matching the received instruction;
the terminal subsystem is a metering system control and service control system and is used for receiving and executing the control instruction sent by the central processing subsystem;
the early warning subsystem is provided with an alarm threshold value and selects early warning after comparing the early warning with the perception judgment result output by the perception judgment subsystem;
and the communication subsystem is used for data interaction and instruction uploading and issuing among the perception judgment subsystem, the central processing subsystem, the terminal subsystem and the early warning subsystem.
Furthermore, the perception judging subsystem comprises a testing device, an environment perception device, a power supply monitoring device, an access control device and a biological characteristic intelligent identification device.
Furthermore, when the biological characteristics are sampled, the unique characteristics are extracted and converted into digital codes, the codes are combined to form a characteristic template and then the characteristic template is interacted with an identification system for identity authentication, the identification system acquires the characteristics of the biological characteristics, compares the characteristics with the characteristic template in the data to determine whether the characteristics are matched, and finally outputs a result.
Furthermore, the environment sensing equipment comprises a temperature and humidity sensor, a volatile organic compound sensor, an air particle concentration sensor and an open fire monitoring sensor, and is used for detecting the temperature and humidity, the volatile organic compound concentration, the air suspended particle concentration and a fire disaster in a laboratory.
Furthermore, the central processing subsystem is integrated with various flow management and control, test operation and state monitoring functions.
Furthermore, the communication subsystem comprises an edge proxy server and a standardized interface, the edge proxy server is used as a core to build a laboratory local area internet of things for supporting an off-line working mode of the whole business process, and meanwhile, test data meeting the requirements of the verification/detection technical standard are uploaded through the standardized interface on a test data acquisition link.
Further, the edge proxy server comprises a firewall server, a cache server, a load balancing server, a DNS server, an application server, a Web presentation server, a Web application server and a back-end database server.
Furthermore, the early warning subsystem collects related data information through the perception judgment subsystem, monitors the variation trend of risk factors, evaluates the strength of deviation of various risk states from an early warning line, sends out early warning signals to the central processing subsystem and takes early warning control measures in advance.
Furthermore, the early warning subsystem is firstly constructed with an evaluation index system and analyzes and processes the index types; and generating an early warning model through an early warning threshold value, carrying out comprehensive judgment on the evaluation index system, setting an early warning interval according to a judgment result, and taking corresponding countermeasures.
In a second aspect, the present invention provides a method for intelligent laboratory safety control, when executed, using the intelligent laboratory safety control system of the first aspect, comprising the steps of:
s1, acquiring the all-round environment and data perception of the laboratory through the perception judgment subsystem, and outputting a perception judgment result according to a preset processing standard value;
the S2 early warning subsystem receives the result in S1, matches the early warning interval generated by the early warning model to perform early warning judgment, selects corresponding countermeasures and uploads the countermeasures to the central processing subsystem;
s3, the central processing subsystem generates an instruction after processing according to the corresponding strategy sent by the early warning subsystem and sends the instruction to the terminal subsystem;
and the S4 terminal subsystem receives the instruction and then performs corresponding actions according to the instruction, and finally realizes full-element, full-flow and all-around risk management and control.
Furthermore, the method is downwards interconnected with the test equipment, the monitoring equipment, the intelligent interaction equipment and the safety protection equipment, full-element state information of a sensing layer is obtained in real time, meanwhile, issued test tasks and control instructions are automatically analyzed, and then intelligent verification is carried out on data uploaded by the test equipment.
The invention has the beneficial effects that:
the invention realizes the monitoring of full-factor dynamic information, and realizes the real-time progress and multidimensional workload statistical display of the mass transfer and quality inspection service; the method comprises the steps of acquiring all-factor information and service capability data in real time, realizing evaluation and risk reminding of the health degree of a metering system of an organization and a jurisdiction, realizing early warning of quality risks of a service overall process and an asset overall life cycle through intelligent analysis of data trends, and realizing online real-time accurate evaluation of service quality and suppliers through the design of an evaluation index system of multi-dimensional data; the comprehensive test process safety risk prevention and control system is established by acquiring the sensing information of the equipment monitoring equipment, the intelligent safety protection equipment and the like in real time, and the comprehensive test process safety risk prevention and control system has a very strong market application prospect.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.
FIG. 1 is a block diagram of a safety control method for an intelligent laboratory.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Example 1
The embodiment provides a safety control system for an intelligent laboratory, which comprises a perception judgment subsystem, a data processing subsystem and a safety control subsystem, wherein the perception judgment subsystem is used for sensing and judging all-around environment and data and outputting a perception judgment result according to a preset processing standard value;
the central processing subsystem is used for setting a standard value for the perception judgment subsystem and simultaneously used as a control system main control center for generating an autonomous control instruction or generating a control instruction after matching the received instruction;
the terminal subsystem is a metering system control and service control system and is used for receiving and executing the control instruction sent by the central processing subsystem;
the early warning subsystem is provided with an alarm threshold value and selects early warning after comparing the alarm threshold value with a perception judgment result output by the perception judgment subsystem;
and the communication subsystem is used for data interaction and instruction uploading and issuing among the perception judgment subsystem, the central processing subsystem, the terminal subsystem and the early warning subsystem.
In this embodiment, the perception judging subsystem includes a testing apparatus, an environment sensing device, a power monitoring device, an access control device, and a biological characteristic intelligent recognition device.
This embodiment environmental perception equipment includes temperature and humidity sensor, volatile organic compounds sensor, air particle concentration sensor and naked light monitoring sensor for the detection of the humiture of laboratory, volatile organic compounds concentration, air suspension particle concentration and conflagration.
In the embodiment, biological characteristics are sampled, unique characteristics of the biological characteristics are extracted and converted into digital codes, the codes are combined to form a characteristic template, and then the characteristic template is interacted with an identification system to perform identity authentication, the identification system acquires the characteristics of the biological characteristics and compares the characteristics with the characteristic template in data to determine whether the biological characteristics are matched, and finally a result is output.
The central processing subsystem of this embodiment is integrated with various flow management and control, test operation and state monitoring functions.
In further implementation of this embodiment, the communication subsystem includes an edge proxy server and a standardized interface, and the edge proxy server is used as a core to build a local internet of things in a laboratory for supporting an offline working mode of a full business process, and simultaneously, in a test data acquisition link, test data meeting the requirements of a verification/detection technical standard is uploaded through the standardized interface.
Preferably, the edge proxy server includes a firewall server, a cache server, a load balancing server, a DNS server, an application server, a Web presentation server, a Web application server, and a backend database server.
The early warning subsystem of the embodiment collects related data information through the perception judgment subsystem, monitors the variation trend of risk factors, evaluates the strength of deviation of various risk states from an early warning line, sends out early warning signals to the central processing subsystem and takes early control countermeasures in advance.
When the embodiment is further implemented, the early warning subsystem firstly constructs an evaluation index system and analyzes and processes the index type; and generating an early warning model through an early warning threshold value, carrying out comprehensive judgment on the evaluation index system, setting an early warning interval according to a judgment result, and taking corresponding countermeasures.
In the embodiment, remote control of the test equipment and automatic collection and recording of test data are realized by researching and applying the interconnection and intercommunication technology of the test equipment. The local Internet of things of the laboratory is built by taking the edge proxy server as a core, and an off-line working mode of the whole business process can be supported. In a test data acquisition link, the design of a standard interface is standardized to ensure that the uploaded test data meets the requirements of the calibration/detection technical standard.
In the embodiment, the multi-point temperature and humidity sensor is arranged in the laboratory, the environmental change condition of the laboratory is monitored in real time, the conformity judgment is carried out on the environmental information corresponding to the service by adopting edge calculation, the quality risk possibly caused by the environment overrun is timely reminded and early warned, and the accuracy and effectiveness of the detection result data are ensured.
The embodiment is transferred from sample receiving and dispatching to the laboratory, and then to leaving a sample to store and the sample returns, and different links customization research and development intelligence storage facilities and intelligent logistics equipment ensure that the sample life cycle state dynamic monitoring and the accurate location of position, have thoroughly realized removing the manual work completely of sample management.
Example 2
In other aspects, the embodiment provides a physical architecture including a three-layer structure of a service layer, a management and control layer, and a sensing layer.
The service layer of the embodiment mainly comprises a metering system control and service control system, and the main devices comprise a server, a computer and the like.
The management and control layer of the embodiment is various flow management and control, test operation and state monitoring equipment, and comprises edge internet of things agent equipment, an operation visualization terminal, a mobile operation terminal and the like.
The sensing layer of the embodiment is an operation execution system and equipment at various ends, and comprises a testing device, environment sensing equipment, power monitoring equipment, access control equipment, a camera and the like.
The embodiment further provides a technical mechanism, which is developed by adopting the current latest micro-service framework technology, and is communicated with the MDS through a data linkage mode, so that on the basis of ensuring the multiplexing linkage of historical information construction results, a brand-new interface style is expanded, and meanwhile, preparation is provided for the integration with a new architecture platform of a subsequent national network.
This embodiment provides a network architecture simultaneously, and in this embodiment, when the condition (national network attack and defense rehearsal) of laboratory and external network disconnection, intelligent detection edge acquisition terminal carries out the analysis with AI high definition digtal camera, RFID data collection ware, electric energy quality analysis appearance, the information of humiture collection terminal equipment collection as the processing terminal in the laboratory, still can guarantee under the condition of laboratory and external network disconnection that production work lasts, provides the stage body operation.
Example 3
On the basis of the embodiments 1 and 2, the embodiment provides an intelligent hardware including interconnection and intercommunication classes, and in order to improve the automation and intelligence level of the test operation layer, a series of test equipment interconnection and intercommunication hardware is developed on the basis of the test equipment control and test data interaction standards.
The device can be interconnected with the testing device, the monitoring device, the intelligent interaction device and the safety protection device downwards, full-element state information of the sensing layer is obtained in real time, meanwhile, the testing task and the control command issued by the platform layer can be automatically analyzed, and intelligent verification can be carried out on data uploaded by the testing device.
The hardware of the embodiment comprises: intelligent edge proxy equipment, measurement test adapter.
In order to enable equipment participating in laboratory activities to have unique identity identifications and establish dynamic asset management association based on the identifications and business activities, the intelligent hardware of the embodiment develops a series of hardware equipment for asset storage and logistics management and establishes a new management operation mode covering the whole life cycle of the laboratory equipment and samples.
The hardware of the embodiment comprises: electronic identity authentication identification, RFID recognition device, intelligent detection edge acquisition terminal, biological sign intelligent recognition AI high definition digtal camera etc..
The intelligent hardware of the embodiment is also in an intelligent sensing type, and a series of intelligent sensing hardware equipment at the tail end of a laboratory is developed for establishing the real-time monitoring capability of all-element state information in the test process and improving the risk identification capability and the safety prevention and control capability of the laboratory.
In the embodiment, a standardized system index and risk index system is established, and comprehensive controllability of system elements and accuracy and effectiveness of test results are ensured through intelligent comparison with real-time monitoring data of a sensing layer.
The hardware of the embodiment comprises: temperature and humidity sensor, test power supply quality monitor, biological sign intelligent identification AI high definition digtal camera etc..
On the basis, the software system provided by the embodiment has full sensing capability of the equipment, is designed for realizing the comprehensive access control of the equipment layer and the comprehensive collection and recording of data, and is a standardized platform for realizing the service, the control and the data between the sensing layer and the service system.
The embodiment realizes the splitting of the test task through the sensing service bus and completes the matching with the capability of the test equipment; all hardware equipment of a sensing layer is connected through an edge proxy server, so that interconnection and intercommunication of various equipment are realized; environmental perception, equipment sample monitoring, safety prevention and control and intelligent interaction are achieved through diversified intelligent hardware.
The software system of the embodiment has comprehensive risk control designed based on system online, business online and element full perception capability construction, and is full-element, full-flow and all-around risk control developed based on an organization quality management system.
In the embodiment, the establishment of 'EOI intelligent measurement' realizes the monitoring of the whole-element dynamic information of 'man-machine-material method loop' of the organization and the district, and realizes the real-time progress and multidimensional workload statistical display of the volume transmission and quality inspection services.
The method establishes an EOI data insight module, realizes evaluation and risk reminding of the health degree of a metering system of an organization and a district in jurisdiction by acquiring all-factor information and service capability data in real time, realizes early warning of quality risks of a service full flow and a full life cycle of assets by intelligently analyzing data trends, and realizes online real-time accurate evaluation of service quality and suppliers by designing an evaluation index system of multi-dimensional data.
According to the embodiment, an omnibearing test process safety risk prevention and control system is established by acquiring sensing information such as equipment monitoring equipment and intelligent safety protection equipment in real time.
Example 4
Referring to fig. 1, the present embodiment provides an intelligent laboratory safety control method, including the following steps:
s1, acquiring the all-round environment and data perception of the laboratory through the perception judgment subsystem, and outputting a perception judgment result according to a preset processing standard value;
the S2 early warning subsystem receives the result in S1, matches the early warning interval generated by the early warning model to perform early warning judgment, selects corresponding countermeasures and uploads the countermeasures to the central processing subsystem;
s3, the central processing subsystem generates an instruction and sends the instruction to the terminal subsystem after processing according to the corresponding countermeasures sent by the early warning subsystem;
and the S4 terminal subsystem receives the instruction and then performs corresponding actions according to the instruction, and finally realizes full-element, full-flow and all-around risk management and control.
The method comprises the steps of interconnecting the test equipment, the monitoring equipment, the intelligent interaction equipment and the safety protection equipment downwards, acquiring the state information of all elements of the sensing layer in real time, automatically analyzing a issued test task and a control instruction, and then intelligently checking the data uploaded by the test equipment.
In conclusion, the invention adopts advanced technology and equipment to gradually establish a three-dimensional safety risk prevention and control system aiming at the test operation process. From the angles of safety tools, operation behaviors, key areas, test equipment and the like, on the basis of ensuring that the safety management regulation requirements and technical standards are met, the safety risk can be early warned, violation behaviors can be timely warned and dealt with, and equipment safety elements can be monitored in real time. Through the digital transformation, safety protection becomes safety prevention and control, and safety management and control becomes safety service.
The invention realizes the monitoring of full-factor dynamic information, and realizes the real-time progress and multidimensional workload statistical display of the mass transfer and quality inspection service; the method comprises the steps of realizing the evaluation and risk reminding of the health degree of a metering system of an organization and a jurisdiction by acquiring all-element information and service capability data in real time, realizing the early warning of the quality risk of the whole service flow and the whole life cycle of assets by intelligently analyzing the data trend, and realizing the online real-time accurate evaluation of the service quality and suppliers by designing an evaluation index system of multi-dimensional data; the comprehensive test process safety risk prevention and control system is established by acquiring the sensing information of the equipment monitoring equipment, the intelligent safety protection equipment and the like in real time, and the comprehensive test process safety risk prevention and control system has a very strong market application prospect.
The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.
Claims (10)
1. An intelligent laboratory safety control system is characterized by comprising
The perception judgment subsystem is used for sensing and judging the environment and data in all directions and outputting a perception judgment result according to a preset processing standard value;
the central processing subsystem is integrated with various flow management and control, test operation and state monitoring functions, is used for setting a standard value for the perception judgment subsystem, and is used as a control system main control center for generating an autonomous control instruction or generating a control instruction after matching processing is carried out on a received instruction;
the terminal subsystem is a metering system control and service control system and is used for receiving and executing the control instruction sent by the central processing subsystem;
the early warning subsystem is provided with an alarm threshold value and selects early warning after comparing the early warning with the perception judgment result output by the perception judgment subsystem;
and the communication subsystem is used for data interaction and instruction uploading and issuing among the perception judgment subsystem, the central processing subsystem, the terminal subsystem and the early warning subsystem.
2. The intelligent laboratory safety control system according to claim 1, wherein the perception judgment subsystem comprises a testing device, an environment perception device, a power monitoring device, an entrance guard device and a biological characteristic intelligent identification device.
3. The system of claim 2, wherein the biometric feature is sampled, the unique feature is extracted and converted into a digital code, and the code is combined to form a feature template, and then the feature template is interacted with the recognition system to perform identity authentication, and the recognition system obtains the feature of the biometric feature and compares the feature with the feature template in the data to determine whether the feature matches the feature template, and finally outputs the result.
4. The system of claim 2, wherein the environmental sensor comprises a temperature and humidity sensor, a volatile organic compound sensor, an air particle concentration sensor and an open fire monitoring sensor, and is used for detecting temperature and humidity, volatile organic compound concentration, air suspended particle concentration and fire in the laboratory.
5. The intelligent laboratory safety control system according to claim 1, wherein the communication subsystem comprises an edge proxy server and a standardized interface, and a laboratory local area internet of things is built by taking the edge proxy server as a core, so as to support an offline working mode of a full business process, and simultaneously test data meeting the requirements of a verification/detection technical standard are uploaded through the standardized interface in a test data acquisition link.
6. The intelligent laboratory security control system of claim 5, wherein the edge proxy server comprises a firewall server, a cache server, a load balancing server, a DNS server, an application server, a Web presentation server, a Web application server, and a back-end database server.
7. The system as claimed in claim 1, wherein the early warning subsystem collects relevant information through the perception judgment subsystem, monitors the variation trend of risk factors, evaluates the degree of deviation of various risk states from an early warning line, sends out early warning signals to the central processing subsystem, and takes early warning countermeasures.
8. The intelligent laboratory safety control system according to claim 7, wherein the early warning subsystem is first constructed with an evaluation index system and analyzes and processes the index category; and generating an early warning model through an early warning threshold value, carrying out comprehensive judgment on the evaluation index system, setting an early warning interval according to a judgment result, and taking corresponding countermeasures.
9. An intelligent laboratory safety control method, when executed, using the intelligent laboratory safety control system according to any one of claims 1-8, comprising the steps of:
s1, acquiring the all-round environment and data perception of the laboratory through the perception judgment subsystem, and outputting a perception judgment result according to a preset processing standard value;
the S2 early warning subsystem receives the result in S1, matches the early warning interval generated by the early warning model to perform early warning judgment, selects corresponding countermeasures and uploads the countermeasures to the central processing subsystem;
s3, the central processing subsystem generates an instruction and sends the instruction to the terminal subsystem after processing according to the corresponding countermeasures sent by the early warning subsystem;
and the S4 terminal subsystem receives the instruction and then performs corresponding actions according to the instruction, and finally realizes full-element, full-flow and all-around risk management and control.
10. The intelligent laboratory safety control method according to claim 9, wherein the method is interconnected with a testing device, a monitoring device, an intelligent interaction device and a safety protection device, real-time acquisition of sensing layer full-element state information is achieved, and meanwhile issued testing tasks and control commands are automatically analyzed, so that intelligent verification is conducted on data uploaded by the testing device.
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