KR20210017861A - Chemical management system that manage laboratory using reagent container identification code - Google Patents

Abstract

A comprehensive chemical management system comprises: a reagent cabinet that can continuously detect the individual weights of a plurality of reagent containers, automatically recognizes an identification code attached to each reagent container each time each reagent container is brought in or taken out, and at the same time detects the point where the weight change occurs to figure out the internal positions of the plurality of reagent containers in real time, and generates a final identification code by combining a position code corresponding to the internal position of each reagent container and the identification code attached to each reagent container; a management server that wirelessly exchanges data with the reagent cabinet to receive and manage in real time the loading status, exit status, usage, expiration date, and internal position of the plurality of reagent containers in managing the reagent cabinet by assigning a unique ID to the reagent cabinet; and a user terminal that automatically displays material safety data sheets (MSDS) for material components of the plurality of reagent containers whenever each reagent container is brought in and taken out in displaying information provided by the management server. Accordingly, user safety can be promoted.

Description

Chemical management system that manage laboratory using reagent container identification code}

The present invention relates to a comprehensive chemical management system, and more particularly, to a comprehensive chemical management system for managing a reagent reservoir and a laboratory using an identification code of a reagent container.

The reagent cabinet is a kind of furniture for storing reagents used in chemical, biological and radiation experiments, and is mainly used in laboratories such as research institutes, companies, factories, and schools.

There are various types of reagents, and each type has its own characteristics, so the reagents are classified among the same characteristics and stored in the same place.

In addition, according to the characteristics of the reagent, the gas generated from the reagent and the reagent are classified and stored so as not to cause a chemical reaction when the reagents are mixed.

That is, it is very important that the reagent chamber is configured to safely store the reagents inside, and ventilation and management of the inside are important to prevent suffocation, fire, and explosion accidents from occurring.

Meanwhile, in laboratories, companies, factories, schools, etc. that use reagent stores, there is a problem in that management is not performed properly when handling various types of reagents.

In particular, considering that several types of reagents are stored in one reagent storage and many users use reagents, it can be seen that it is natural that reagents are not well organized.

To prevent this problem from occurring, it is necessary to put the used reagents in the place where the reagents were, but there is a limit of memory to take out and place various kinds of reagents in the correct place, and if the reagents are not placed in place, it may cause inconvenience to others. Is done.

In addition, in order to determine the location of the reagent, a table for stock and location of reagents is created and managed on one side of the reagent field, but there is a problem that it is not properly performed.

In order to solve this problem, a system for managing reagents using a barcode or RFID tag has been developed and used. However, if the number of reagents to be managed is too large, there is a disadvantage that an additional operation is required to create and attach a new barcode or RFID tag to every reagent bottle.

KR 10-818795 B

The present invention has been proposed to solve the above technical problems, and comprehensive management of chemical substances capable of generating a final identification code by combining the location code corresponding to the internal location of the reagent container and the identification code attached to each reagent container. System.

According to an embodiment of the present invention for solving the above problem, individual weights of a plurality of reagent containers can be continuously detected, and the identification code attached to each reagent container is automatically loaded whenever each reagent container is brought in or taken out. At the same time, it recognizes and detects the point where the weight change has occurred to identify the internal positions of the plurality of reagent containers in real time, and the final identification by combining the location code corresponding to the internal position of each reagent container and the identification code attached to each reagent container. In managing the reagent reservoir that generates the code and the reagent reservoir by assigning a unique ID to the reagent reservoir, data is exchanged wirelessly with the reagent reservoir to receive the loading and unloading status, usage, expiration date and internal location of a plurality of reagent vessels in real time. When displaying information provided by the management server and the management server, material safety data sheets (MSDS) for the material components of multiple reagent containers are automatically generated whenever each reagent container is brought in or taken out. There is provided a chemical substance comprehensive management system including a display user terminal.

In addition, the reagent field included in the present invention is characterized in that the final identification code is generated by combining all of the unique ID, location code, and identification code of the reagent field.

In addition, the management server included in the present invention is connected to the research safety integrated system that provides regulatory information and deviates from the regulatory information based on the loading status, removal status, usage, and expiration date of a plurality of reagent containers stored in the reagent chamber. It is characterized in that the identification is transmitted to the user terminal.

In addition, the user terminal included in the present invention is a radiation laboratory, a biosafety laboratory, and a precision safety diagnosis laboratory on the floor plan of the building based on the material composition of the reagent container stored in the reagent chamber in displaying information provided from the management server. , Hazardous and dangerous machinery locations are classified and marked, Class 3, Class 4, and Class 5 under the Dangerous Goods Safety Management Act are marked separately, and the presence/absence of automated fire extinguishing facilities is indicated, and combustible gas, auxiliary gas, and toxic gas are classified. It is characterized by displaying.

In addition, the management server included in the present invention, when the information on the occurrence of fire is received in the building where the reagent reservoir is placed, the location of the building on the map, the location of the reagent reservoir on the floor plan of the building, and is maintained in a state of being carried into the reagent reservoir. It is characterized in that the material components of the plurality of reagent containers are transmitted to a designated manager terminal.

In addition, the management server included in the present invention, when receiving information on the occurrence of a fire in a building in which the reagent reservoir is disposed, the location of the building on the map, the location of the reagent reservoir on the floor plan of the building, and is maintained in a state of being carried into the reagent reservoir. When the material components of a plurality of reagent containers are transferred to the designated manager terminal, and substances that react chemically with water are stored in the reagent room, the amount of storage of substances that react chemically with water through the fire department terminal and the location of the reagent room on the floor plan of the building It characterized in that it transmits.

The integrated chemical substance management system according to an embodiment of the present invention may generate a final identification code by itself by combining a location code corresponding to an internal location of a reagent container and an identification code attached to each reagent container. Therefore, there is an advantage that the existing identification code attached to each reagent container can be used as it is.

In addition, the user's safety can be promoted by automatically displaying the Material Safety Data Sheet (MSDS) on the material components of the reagent container on the user terminal whenever the reagent container is brought in or taken out.

In addition, the management server can identify the contents that deviate from the regulatory information based on the carry-in status, the carry-out status, the amount of use, and the expiration date of the reagent container stored in the reagent cabinet and transmit it to the user terminal.

1 is a conceptual diagram showing the overall operation of the comprehensive chemical substance management system 1 according to an embodiment of the present invention
2 is a configuration diagram of a comprehensive chemical substance management system 1 according to an embodiment of the present invention
3 is an exemplary diagram of an installed application of a user terminal
4 is an exemplary diagram of an identification code attached to a reagent container
5 is a configuration diagram of the reagent chamber 100
6 is an exemplary diagram of the reagent chamber 100
7 is a diagram showing fire fighting information provided by the management server 200

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings in order to describe in detail enough to allow those of ordinary skill in the art to easily implement the technical idea of the present invention.

1 is a conceptual diagram showing the overall operation of the comprehensive chemical substance management system 1 according to an embodiment of the present invention.

Referring to FIG. 1, the comprehensive chemical substance management system 1 performs an integrated management of the entire period from purchase to disposal.

The purchasing processor is in charge of MSDS (Material Safety Data Sheet), LOC management, COC management, new product management, preliminary stability management, legal regulation review, etc. The inspection processor is in charge of material tracking management and identification code management. The processor is in charge of MSDS education management, special health check-up management, work environment measurement management, handling log management, use management, hazardous material specified quantity management, and storage storage processor is in charge of shelf life (validity) management, storage management. The processor is in charge of disposal management after checking the usage and expiration date.

In other words, the comprehensive chemical substance management system automates the analysis of risk of harmful factors in advance, safety management of all cycles of laboratory chemicals, designated quantity management of dangerous substances, laboratory safety education / radiation safety education / LMO safety education integrated management, laboratory safety accident firefighting information, SIGMA ALDRICH. It can systematically and effectively handle various tasks such as providing the latest MSDS for each product manufacturer.

In addition, the comprehensive chemical substance management system (1) links the various safety information requirements of the laboratory necessary for conducting a pre-hazardous factor risk analysis with the “Research Safety Integrated Information System” with one-click access to laboratory information, chemical substances, machinery, and living organisms. It is automatically reflected to support the implementation of risk analysis in advance easily.

In addition, the comprehensive chemical substance management system (1) provides automatic laboratory characteristic information, chemical substance (reagent / gas) information, equipment information, and dangerous substance information on the floor plan according to the layout diagram icon composition, so that risk identification in case of an accident occurs. Support for quick and easy response.

In addition, the comprehensive chemical substance management system (1) provides life cycle management from purchase to disposal, linking with institutional (university) purchase and payment systems, to respond to legal regulations, automate pre-hazard risk analysis, and automatically select subjects for health checkups. We support tasks such as managing the designated quantity of dangerous goods and responding to reports on imported reagents.

In addition, the comprehensive chemical substance management system (1) solves the problems of redundancy and double education by integrating and managing laboratory general safety environment education, genetically modified organism education, and radiation safety education, and is a periodic system such as university personnel organization information and academic records. It provides real-time linkage with and accurate personnel information to support the management of trainees and those who completed the training.

In addition, the comprehensive chemical substance management system 1 can automatically provide a guide for responding to the chemical substance regulatory review by using a regulatory database.

2 is a block diagram of a comprehensive chemical substance management system 1 according to an embodiment of the present invention.

The comprehensive chemical substance management system 1 according to this embodiment includes only a simple configuration for clearly explaining the technical idea to be proposed.

Referring to FIG. 2, the integrated chemical substance management system 1 includes a plurality of reagent stations 100, a management server 200, a firefighter terminal 300, and a user terminal 400.

The main operations of the comprehensive chemical substance management system 1 configured as described above are as follows.

The reagent cabinet 100 is a kind of furniture for storing reagents used in chemistry, biology, and radiation experiments, and is mainly used in laboratories such as research institutes, companies, factories, and schools.

There are various types of reagents, and each type has its own characteristics, so the reagents are classified among the same characteristics and stored in the same place. In addition, according to the characteristics of the reagent, the gas generated from the reagent and the reagent are classified and stored so as not to cause a chemical reaction when the reagents are mixed.

That is, it is very important that the reagent cabinet 100 is configured to safely store reagents therein, and has a structure in which suffocation, fire, explosion, and the like do not occur.

The reagent compartment 100 of the present invention is configured to continuously detect individual weights of a plurality of reagent containers.

That is, the reagent cabinet 100 has a multi-stage table, and each table has a plurality of weight sensing units capable of detecting the weight of the reagent container. That is, since each weight sensing unit is arranged to individually measure the weight of the allocated area, the weight of each reagent container can be independently detected.

In addition, the reagent compartment 100 is provided with a scanner that automatically recognizes the identification code attached to each reagent container whenever each reagent container is brought in or taken out. In particular, the reagent compartment 100 may automatically recognize an identification code whenever a reagent container is brought in or taken out, and at the same time detect a point at which a weight change occurs, thereby grasping the internal positions of the plurality of reagent containers in real time. For example, if a point where the weight change is detected occurs within a predetermined time after the identification code is recognized, the reagent container has been carried. In addition, when the weight change is detected and the identification code is recognized within a predetermined time, the reagent container has been taken out.

Meanwhile, an identification code such as a barcode or QR code is attached to the reagent container. This identification code is not an identification code given by the chemical substance management system (1) to the reagent container, but is defined as an identification code attached by the company that manufactured/sold the reagent container.

Therefore, the reagent chamber 100 performs a process of generating a separate identification code for managing the reagent container by itself.

That is, the reagent chamber 100 generates a final identification code by itself by combining the identification code attached to each reagent container and a location code corresponding to the internal location of each reagent container. In this case, when a plurality of reagent reservoirs 100 are provided, a final identification code may be generated by combining all of the reagent reservoir's unique ID, location code, and identification code. In addition, it is possible to generate a final identification code by combining all of the reagent reservoir's unique ID, location code, identification code, and initial weight value of the reagent container.

For reference, it is common for the weight of the reagent container to decrease when the removal state is repeated after the reagent container is initially loaded. Therefore, when the weight of the reagent container is increased when the reagent container is transferred from the carrying-out state to the carrying-in state, the reagent container 100 automatically transmits a warning message to the user terminal 400 to check whether the reagent container has deviated from the initially set internal position. To be.

In this way, the integrated chemical management system (1) creates the final identification code by combining the location code corresponding to the internal location of the reagent container and the identification code attached to each reagent container, thereby identifying the existing identification attached to each reagent container. There is an advantage of being able to use the code as it is.

The management server 200 wirelessly exchanges data with the reagent reservoir 100 to receive and manage the loading and unloading status, usage, expiration date, and internal location of a plurality of reagent containers in real time.

In addition, the management server 200 assigns and manages the reagent reservoir 100 with a unique ID of the reagent reservoir. In particular, the location of the building where the reagent reservoir is placed and the location of the reagent reservoir on the floor plan of the building are databaseized and managed.

3 is an exemplary diagram of an installed application of a user terminal.

Referring to FIG. 3, the user terminal 400 displays information provided from the management server 200. In particular, material safety data sheets for the material components of a plurality of reagent containers whenever each reagent container is carried in or taken out. Material Safety Data Sheet, MSDS) is automatically displayed so that users can recognize safety matters when handling materials.

For reference, in this embodiment, a terminal is a generic term for a device that can be used while carrying a user, such as a mobile phone, a smart phone, and a smart pad, and in this embodiment, it is assumed that it is a terminal composed of a smart phone.

Meanwhile, Material Safety Data Sheet (MSDS)

-Chemical Product and Company Identification

-Hazards Identification

-Name and content of ingredients (Composition/Information on Ingredients)

-First-Aid Measures

-Fire-Fighting Measures

-Accidental Release Measures

-Handling and Storage

-Exposure Controls and Personal Protection

-Physical and Chemical Properties

-Stability and Reactivity

-Toxicological Information

-Ecological Information

-Disposal Considerations

-Transport Information

-Regulatory Information

-Other Information

It consists of the configuration items, in the present invention, the display priority of the MSDS item for each user is automatically reset.

That is, even if the same reagent container is handled, the display order of MSDS items displayed on the portable terminal of the first user and the portable terminal of the second user is automatically set differently.

For example, after being classified into new employees and experienced employees according to the user's experience, for new employees, exposure controls and personal protection items and Hazards Identification items have the highest priority. It can be highlighted as it appears.

At this time, in the case of experienced employees, the names and contents of ingredients (Composition/Information on Ingredients) and Physical and Chemical Properties items are displayed first and can be emphasized.

In addition, when information on reagent containers with a history of accidents due to recent negligence in handling is stored in the management server 200, the items of Exposure Controls and Personal Protection, regardless of their career, and The Hazards Identification item is displayed as the first priority, and at the same time, the accident history can be further highlighted.

The integrated research safety system is a system that provides regulatory information and is built in the management server 200. For reference, the integrated research safety system may be separately constructed outside the management server 200 and configured to share data with the management server.

The management server 200 searches for a research safety integrated system that provides regulatory information, and identifies the contents deviating from the regulatory information based on the loading status, removal status, usage, and expiration date of a plurality of reagent containers stored in the reagent storage 100. And transmits it to the user terminal 400. Therefore, the user can automatically recognize whether the substance stored in the reagent chamber conforms to the regulatory information.

4 is an exemplary diagram of an identification code attached to a reagent container.

Referring to FIG. 4, an identification code attached by a company that manufactures/sells the reagent container is attached. At least one identification code, such as a barcode, a QR code, and an RFID tag, may be attached.

The integrated chemical substance management system of this embodiment can generate the final identification code by combining the location code corresponding to the internal location of the reagent container and the identification code attached to each reagent container. There is an advantage that the identification code can be used as it is.

The management server 200 separates and displays the location of the radiation laboratory, the biosafety laboratory, the precision safety diagnosis laboratory, and the hazardous machine on the floor plan of the building based on the material composition of the reagent container stored in the reagent chamber. The container is marked as being located in the laboratory where the reagent field is placed for a predetermined period, classified into Class 3, Class 4, and Class 5 under the Hazardous Materials Safety Management Act, indicating the presence/absence of automated fire extinguishing equipment, and combustible gas, supporting flammability Gas and toxic gas can be classified and labeled. In this case, the management server 200 may transmit the above-described information to the user terminal 400 or a fire fighting terminal to support efficient work.

For reference, the management server 200 may indicate that the reagent container carried out from the reagent reservoir is located in a laboratory in which the reagent reservoir is disposed for a predetermined period. That is, in many cases, researchers take out the reagent containers stored in the reagent cabinet and use them in the laboratory, so the management server 200 is assumed to be located in the laboratory for a predetermined period of time when the reagent containers are carried in the reagent cabinet and then taken out again. To indicate.

In addition, the management server may provide a material safety data sheet (MSDS) for the material components of the plurality of reagent containers to the user terminal 400.

For reference, the Material Safety Data Sheet (MSDS) contains basic safety/health data for chemical substances (including chemical name, Chemical Abstracts Service (CAS) registration number, harmful properties, and known acute/chronic health data). It is a document for the purpose of preventing accidents caused by handling substances by using them and presenting them to workers by subdividing the items accordingly.

In Korea, based on Article 41 of the Occupational Safety and Health Act (preparation/location of material safety data sheets, etc.), a business owner who manufactures/imports/uses/transports/stores chemical substances prepares MSDS and keeps it at the workplace. Warning signs are affixed to containers or packaging to inform them of hazards, and to provide safety and health education to workers.

That is, when a user carrying the user terminal 400 removes the reagent container from the reagent storage 100, the management server 200 provides material safety and health for the material components of the reagent container that is being carried out to the user terminal 400. By automatically sending data (Material Safety Data Sheet, MSDS) to users who handle chemical substances of hazards and dangers, users themselves can protect themselves and promptly respond to unexpected chemical accidents.

5 is a configuration diagram of the reagent chamber 100, and FIG. 6 is an exemplary diagram of the reagent chamber 100.

5 and 6, the reagent compartment 100 includes a scanner 101, a weight detection unit 102, a communication module 103, a temperature sensor 104, a humidity sensor 105, and a harmful gas detection sensor 106. ) And a control unit 120.

The scanner 101 is a device that recognizes an identification code attached to a reagent container. The identification code may include at least one or more of a barcode, a QR code, and an RF tag.

The weight detection unit 102 is mounted on a table of a reagent chamber, and detects a point where a weight change occurs to detect the positions of the plurality of reagent containers. For example, the table of the reagent chamber is internally divided into a two-dimensional matrix arrangement, and a weight detector is disposed at each point to detect the weight of a reagent bottle disposed in the corresponding area. At this time, it is assumed that a plurality of weight sensors are arranged in each weight detection unit.

Meanwhile, when a reagent bottle with a large size is first placed on the table, two weight detection units may be in a state to measure the weight at the same time. In this case, when the reagent bottle is first placed in the corresponding area, the two weight detection units The size of the pre-allocated area is automatically adjusted to detect the weight of one reagent bottle.

That is, the plurality of weight sensors of the first weight detection unit and the plurality of weight sensors of the second weight detection unit do not individually measure weight, but are automatically integrated to measure the weight of one reagent bottle. As described above, the size of the two-dimensional array is variably adjusted according to the size of the reagent bottle, and the size of the pre-allocated area is adjusted so that the plurality of weight detection units can detect the weight of one reagent bottle.

The communication module 103 is provided to exchange data wirelessly with the management server 200.

The temperature sensor 104 is provided to detect the temperature inside the reagent chamber, and the humidity sensor 105 is provided to detect the humidity inside the reagent chamber. The harmful gas detection sensor 106 detects the harmful gas leaked inside the reagent chamber, and the control unit 120 is a scanner 101, a weight detection unit 102, a communication module 103, a temperature sensor 104, a humidity sensor. It serves to control the operation of (105) and the harmful gas detection sensor (106).

As shown in FIG. 6, the reagent compartment 100 can automatically recognize the identification code whenever the reagent container is brought in or taken out, and at the same time detect the point where the weight change has occurred, and grasp the internal positions of the plurality of reagent containers in real time. .

For example, if a point where the weight change is detected occurs within a predetermined time after the identification code is recognized, the reagent container has been carried. In addition, when the weight change is detected and the identification code is recognized within a predetermined time, the reagent container has been taken out.

Identification codes such as barcodes or QR codes are attached to the reagent container. This identification code is not an identification code given by the chemical substance management system (1) to the reagent container, but is defined as an identification code attached by the company that manufactured/sold the reagent container.

Therefore, the reagent chamber 100 performs a process of generating a separate identification code for managing the reagent container by itself.

That is, the reagent chamber 100 generates a final identification code by itself by combining the identification code attached to each reagent container and a location code corresponding to the internal location of each reagent container. In this case, when a plurality of reagent reservoirs 100 are provided, a final identification code may be generated by combining all of the reagent reservoir's unique ID, location code, and identification code.

It is common for the weight of the reagent container to decrease when the removal state is repeated after the reagent container is first loaded. Therefore, when the weight of the reagent container is increased when the reagent container is transferred from the carrying-out state to the carrying-in state, the reagent container 100 automatically transmits a warning message to the user terminal 400 to check whether the reagent container has deviated from the initially set internal position. To be.

In this way, the integrated chemical management system (1) creates the final identification code by combining the location code corresponding to the internal location of the reagent container and the identification code attached to each reagent container, thereby identifying the existing identification attached to each reagent container. There is an advantage of being able to use the code as it is.

7 is a view showing fire fighting information provided by the management server 200.

Referring to FIG. 7, the management server 200 of the integrated chemical substance management system 1 includes the location of the building where the fire occurred on the map, and the building when fire information is received in the building where the reagent reservoir 100 is placed. Automatically transfers the location of the reagent reservoir to the designated manager terminal on the plan Here, the fire occurrence information is managed in a separate fire fighting system and transmitted to the management server 200 in real time.

In addition, when the information on the occurrence of fire is received in the building in which the reagent reservoir is placed, the management server 200 maintains the location of the building where the fire occurred on the map, the location of the reagent reservoir on the floor plan of the building, and carried into the reagent reservoir. The substance components of a plurality of reagent containers are transmitted to the designated manager terminal. At this time, the management server 200 considers that the reagent container carried out from the reagent reservoir is located in the laboratory in which the reagent reservoir is placed for a predetermined period of time, and transmits the material components of the discharged reagent container to the manager terminal or the fire department terminal. That is, in many cases, researchers take out the reagent containers stored in the reagent cabinet and use them in the laboratory, so the management server 200 is assumed to be located in the laboratory for a predetermined period of time when the reagent containers are carried in the reagent cabinet and then taken out again. To indicate.

In addition, when the information on the occurrence of fire is received in the building in which the reagent reservoir is placed, the management server 200 maintains the location of the building where the fire occurred on the map, the location of the reagent reservoir on the floor plan of the building, and carried into the reagent reservoir. In addition to transferring the material components of multiple reagent containers to the designated manager terminal, if substances that react chemically with water are stored in the reagent center, the amount of storage of substances that react chemically with water to the fire department terminal and the location of the reagent cabinet on the floor plan of the building It can help to efficiently proceed with fire suppression by transmitting.

For example, alkali metal refers to all chemical elements other than hydrogen in Group 1 of the periodic table. Lithium (Li), sodium (Na), potassium (K), rubidium (Rb), cesium (Cs) , Francium (Fr) belongs to this chemical family. It is very reactive and reacts quickly when it encounters oxygen, water, or halogen elements.

That is, since the reactivity is very high, when water comes into contact, the reaction occurs at a rapid rate and reacts explosively. Therefore, the fire must be extinguished with limited use of water around the reagent chamber where such substances are stored.

The management server 200 may determine the amount of change in temperature and humidity of all reagent plants in real time, and then calculate the risk based on the amount of change.

In particular, when the fire occurrence information is received, the management server 200 may calculate the degree of destruction risk based on the temperature change amount and the humidity change amount of all reagent plants. This information is transmitted to the manager terminal and the fire station terminal so that the fire propagation path can be indirectly transmitted.

The management server 200 can receive real-time information on the operation of the air conditioner of the building where the fire has occurred from the firefighting system. Based on the operation information of the air conditioner, the hazardous substance is predicted when a fire occurs at the location of the reagent room on the floor plan of the building. The diffusion path can be simulated and provided.

In addition, when multiple reagent sites are damaged due to a fire, the predicted diffusion path of hazardous substances is simulated, but information indicating the predicted points where chemical reactions can occur due to leaking substances can be provided on the floor plan of the building. .

In addition, after simulating the predicted points where chemical reactions can occur due to the leaked substances and the expected diffusion path of hazardous substances, the neutralizing agent that can be used based on the operation information of the air conditioner-the neutralizing agent of the leaked substance-and each neutralizing agent It is possible to provide information that displays the optimal point to put in on the floor plan of the building.

The integrated chemical substance management system according to an embodiment of the present invention may generate a final identification code by itself by combining a location code corresponding to an internal location of a reagent container and an identification code attached to each reagent container. Therefore, there is an advantage that the existing identification code attached to each reagent container can be used as it is.

In addition, the user's safety can be promoted by automatically displaying the Material Safety Data Sheet (MSDS) on the material components of the reagent container on the user terminal whenever the reagent container is brought in or taken out.

In addition, the management server can identify the contents that deviate from the regulatory information based on the carry-in status, the carry-out status, the amount of use, and the expiration date of the reagent container stored in the reagent cabinet and transmit it to the user terminal.

In addition, when information about a fire occurrence is received in a building in which the reagent reservoir is disposed, the storage amount of substances that react chemically with water and the location of the reagent reservoir on the floor plan of the building may be transmitted to the firefighter terminal.

Therefore, firefighting personnel can try to extinguish the fire effectively using water or neutralizing substances after grasping the characteristics of the material stored in the reagent room.

As such, those skilled in the art to which the present invention pertains will be able to understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. Therefore, the embodiments described above are illustrative in all respects and should be understood as non-limiting. The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

100: reagent chamber
101: scanner
102: weight detection unit
103: communication module
104: temperature sensor
105: humidity sensor
106: harmful gas detection sensor
120: control unit
200: management server
300: firefighter terminal
400: user terminal

Claims (6)

Individual weights of a plurality of reagent containers can be continuously detected, and the identification code attached to each reagent container is automatically recognized whenever each reagent container is brought in or taken out, and at the same time, the point where the weight change occurs is detected and the plurality of reagents A reagent chamber that identifies the internal location of the container in real time, and generates a final identification code by combining a location code corresponding to the internal location of each reagent container and an identification code attached to each reagent container;
In managing the reagent reservoir by assigning a unique ID to the reagent reservoir, a management server that wirelessly exchanges data with the reagent reservoir to receive and manage the loading and unloading status, usage, expiration date, and internal location of the plurality of reagent vessels in real time. ;
In displaying information provided by the management server, a user terminal that automatically displays material safety data sheets (MSDS) for the material components of the plurality of reagent containers whenever each reagent container is brought in or taken out. ;
Comprehensive chemical substance management system comprising a.
The method of claim 1,
The reagent field,
A chemical substance comprehensive management system, characterized in that the final identification code is generated by combining all of the unique ID of the reagent plant, the location code, and the identification code.
The method of claim 1,
The management server,
Searches a research safety integrated system that provides regulatory information, identifies the contents deviating from the regulatory information based on the carry-in status, the carry-out status, usage, and expiration date of the plurality of reagent containers stored in the reagent cabinet and transmits it to the user terminal. Chemical substance comprehensive management system, characterized in that.
The method of claim 1,
The user terminal,
In displaying the information provided by the management server, the location of the radiation laboratory, the biosafety laboratory, the precision safety diagnosis laboratory, and the hazardous machine is classified and displayed on the floor plan of the building based on the material composition of the reagent container stored in the reagent chamber. and,
Classified 3, 4, and 5 under the Dangerous Goods Safety Management Act, and
Display the presence/absence of automated fire extinguishing facilities,
Comprehensive chemical substance management system, characterized in that combustible gas, auxiliary gas, and toxic gas are classified and displayed.
The method of claim 1,
The management server,
When fire information is received in the building where the reagent storage is located,
A chemical substance, characterized in that transmitting the location of the building on the map, the location of the reagent pond on the floor plan of the building, and the substance components of the plurality of reagent containers carried in the reagent reservoir to a designated manager terminal Total management system.
The method of claim 1,
The management server,
When fire information is received in the building where the reagent storage is located,
Transmits the location of the building on the map, the location of the reagent pond on the floor plan of the building, and the substance components of the plurality of reagent containers carried in the reagent chamber to a designated manager terminal, and chemically reacts with water. When a substance is stored in the reagent reservoir, the storage amount of the substance chemically reacting with the water and the location of the reagent reservoir on a plan view of the building are transmitted to a firefighter terminal.

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