KR20210076230A - Safety vessel set for reagent - Google Patents

Abstract

The present invention relates to a safety vessel set for reagent. An object of the present invention is to provide a safety vessel set for reagent in which spillage of stored liquid reagents is prevented even if reagent vessels are tilted, so safe experiments can be performed. The safety vessel set of the present invention comprises: a reagent vessel having an internal space for accommodating a liquid reagent; a reagent supply unit integrally installed in the reagent vessel; and a quantitative control unit connected to the reagent supply unit to supply a liquid reagent into the reagent vessel or to suck the liquid reagent in the reagent vessel. The reagent supply unit comprises: a body block integrally installed on one side of the reagent vessel and having two or more coupling holes communicating with the inner space of the reagent vessel; a connector configured to be inserted and installed in the coupling hole of the body block; and a suction supply pipe having one side connected to one end of the connector and the other side installed so as to be immersed in the liquid reagent accommodated in the inner space of the reagent vessel. A quantitative control unit is installed in the connector or the coupling hole of the body block, so the liquid reagent in the quantitative control unit is injected and supplied into the internal space of the reagent vessel, or the liquid reagent in the internal space of the reagent vessel is sucked into the quantitative control unit through the suction supply pipe and the connector.

Description

Safety vessel set for reagent}

The present invention relates to a safety reagent container set, and to a safety reagent container set capable of safely supplying and inhaling a liquid reagent stored in a reagent container in a fixed quantity without opening the lid of the reagent container.

In general, a reagent container is a container that mainly stores chemicals used in reactions for detection or quantification of substances in chemical analysis, and is generally used in laboratories, etc., and the liquid reagent in the reagent container is transported and supplied by a dropper and supplied with various chemical substances. being used in experiments.

That is, the reagent container used in the prior art is used only as a means for storing the liquid reagent, and a dropper is used to suck a small amount of the chemical solution from the reagent container.

The dropper is composed of an elastic pressure tube made of rubber and a glass tube coupled thereto, a chemical liquid guide tube. To suck a chemical, press the elastic pressure tube and then immerse the chemical liquid guide tube in a liquid reagent, and the pressing force of the elastic pressure tube When release, the liquid reagent is sucked by vacuum pressure, and the sucked inhaled liquid reagent is transferred to another container or beaker and used for various experiments.

However, in the conventional reagent vessel as described above, since the experimenter holds the dropper with one hand during the experiment, the entrance of the reagent vessel cannot be closed. As such, the reagent vessel is tilted or tilted while the entrance of the reagent vessel is open. When it falls, there is a problem that the liquid reagent in the reagent container flows out.

In particular, since the entrance of the reagent container is open during use, the odor of the liquid reagent in the reagent container is continuously exposed to the outside, resulting in an unpleasant indoor environment. In addition to being contaminated, there was a problem in that the safety of the experimenter was threatened due to the spilled liquid reagent.

In addition, since the liquid reagent in the reagent container is to be moved by the dropper, it is inconvenient to separately prepare the dropper, and when the dropper is used, an excessive amount of the liquid reagent is transferred than the liquid reagent required for the actual experiment, Since a separate instrument for measuring the amount of liquid reagent is required, the amount of experimental equipment used is increased, and there is a problem in that the experiment is conducted in an untidy environment.

In addition, in order to solve the above problems, a reagent container in which a nozzle is integrally coupled to the lid of the reagent container has been developed. However, such a reagent container is also difficult to control the amount of ejection of the liquid reagent stored therein. There were several problems, such as requiring a separate instrument to measure the amount of use.

Registered Utility Model Gazette Registration No. 20-0166684 (1999.10.28) Registered Utility Model Gazette Registration No. 20-0307299 (2003.03.03) Registered Patent Publication No. 10-1178596 (2012.08.24) Laid-Open Patent Publication No. 10-2013-0021156 (2013.03.05)

It is an object of the present invention to provide a set of safe reagent containers in which spillage of stored liquid reagents is prevented even if the reagent containers are tilted, so that safe experiments can be performed.

Another object of the present invention is to provide a set of safe reagent containers in which a quantitative supply and quantitative suction of a liquid reagent stored in a reagent container improves the accuracy of the experiment, and anyone can easily perform the experiment.

The present invention relates to a reagent container having an internal space in which a liquid reagent is accommodated; a reagent supply unit integrally installed in the reagent vessel; A quantitative control unit connected to the reagent supply unit to supply a liquid reagent into the reagent vessel or to suck the liquid reagent in the reagent vessel; including,

The reagent supply unit includes a body block integrally installed on one side of the reagent container and having two or more coupling holes communicating with the inner space of the reagent container, a connector inserted and installed into the coupling hole of the body block, and one end of the connector on one side and a suction supply pipe which is connected and the other side is installed so as to be immersed in the liquid reagent accommodated in the inner space of the reagent container, and a quantitative control unit is installed in the coupling hole of the connector or the body block, so that the liquid reagent in the quantitative control unit is stored inside the reagent container. It is configured so that the liquid reagent in the inner space of the reagent container is sucked into the quantitative control unit through injection and supply into the space or through the suction supply pipe and the connection port.

According to the present invention, the liquid reagent is discharged and sucked through the reagent supply part rather than the main entrance of the reagent container, so that even if the reagent container falls, the liquid reagent inside does not leak to the outside.

In the present invention, since a predetermined amount of liquid reagent is supplied or sucked by the operation of the quantitative control unit, loss of the liquid reagent due to supply/suction of more liquid reagent than necessary is prevented.

In the present invention, since a display unit such as a scale is installed in the quantitative control unit, the suction amount and the supply amount of the liquid reagent can be accurately set and adjusted, thereby improving the accuracy and reliability of the experiment.

The present invention has a structure in which the internal space of the reagent container in which the liquid reagent is stored is sealed, so that gas emission and odor generation due to the liquid reagent are reduced even during suction/supply of the liquid reagent for an experiment.

According to the present invention, the liquid reagent flowing on the floor can be easily suctioned and removed by connecting the quantitative control unit and the connecting supply pipe, thereby improving the safety of the experimenter.

In the present invention, since the reagent vessel can be washed through the main entrance of the reagent vessel, the cleaning operation of the reagent vessel is performed smoothly, and contamination of the liquid reagent stored in the vessel is prevented, and there are many effects.

1 is an exemplary view showing a configuration according to the present invention;
2 is an exemplary view showing the configuration of a reagent container and a reagent supply unit according to the present invention;
3 is an exemplary view showing the internal configuration of a reagent container and a reagent supply unit according to the present invention;
4 is an exemplary view showing an operating state according to the present invention (liquid reagent discharge)
5 is an exemplary view showing an operating state according to the present invention (liquid reagent suction)
6 is an exemplary view showing a state of use of the present invention;

1 is an exemplary view showing a configuration according to the present invention, FIG. 2 is an exemplary view showing the configuration of a reagent container and a reagent supply unit according to the present invention, and FIG. 3 is an internal configuration of a reagent vessel and a reagent supply unit according to the present invention. 4 is an exemplary view showing an operating state according to the present invention (liquid reagent discharge), FIG. 5 is an exemplary view showing an operating condition according to the present invention (liquid reagent suction), and FIG. 6 is the present invention As an example diagram showing the use state of

The present invention provides a reagent container 10 having an internal space 11 for accommodating a liquid reagent; a reagent supply unit 20 integrally installed in the reagent vessel 10; It is connected to the reagent supply unit 20 and is installed to supply the liquid reagent 60 into the reagent container 10, or a quantitative control unit 70 for sucking the liquid reagent 60 in the reagent container; including;

The reagent supply unit 20 includes a body block 30 integrally installed on one side of the reagent vessel 10 and having two or more coupling holes 31 communicating with the internal space 11 of the reagent vessel, and A connector 40 inserted and installed in the coupling hole 31, and one end is connected to the end of the connector and the other end is installed so as to be immersed in the liquid reagent accommodated in the inner space of the reagent container It includes a suction supply pipe 50,

A quantitative control unit 70 is installed in the connection port 40 or the coupling hole 31 of the body block, so that the liquid reagent 60 in the quantitative control unit is injected and supplied into the internal space 11 of the reagent container, or a suction supply pipe It is configured such that the liquid reagent 60 in the reagent container inner space 11 is sucked into the quantitative control unit 70 through the 50 and the connector 40 .

In addition, the present invention further includes a connection supply pipe 80 connected to another connection port of the reagent supply unit in which the quantitative control unit 70 is not installed or to one side coupling hole of the body block.

The reagent container 10 has an internal space 11 in which a liquid reagent is accommodated, and a main inlet 12 for supplying a liquid reagent 60 and cleaning the internal space 11 is formed on one side. have.

The main inlet 12 is opened and closed by a stopper 13, and the main inlet 12 and the stopper 13 are provided with a screw thread method or a clamping method to maintain the watertightness of the inner space 11. are combined Since such a coupling method of the main inlet and the stopper is a known technique, a detailed description thereof will be omitted.

The reagent supply unit 20 has a function of supplying the liquid reagent 60 into the reagent vessel 10 with the stopper 13 installed at the main inlet 12 of the reagent vessel, and within the reagent vessel 10 . It has a function of allowing the stored liquid reagent 60 to be discharged to the outside.

The reagent supply unit 20 is integrally coupled to a body block 30 having a plurality of coupling holes 31 formed on one side of the reagent container 10 , and a connector 40 is coupled to at least one coupling hole 31 . A suction supply pipe 50 made of a flexible material (flexible material) connected to the liquid reagent in the inner space of the reagent container is installed in at least one of the connected connectors 40 .

The body block 30 is installed integrally with one side of the reagent vessel in surface contact, and a plurality of coupling holes 31 communicating with the inner space of the reagent vessel are formed. At this time, the body block 30 may be integrally attached to the reagent container 10 by an adhesive or the like, or may be integrally molded when the reagent container 10 is manufactured.

One or more coupling holes 31 are formed so that one side communicates with the inner space 11 of the reagent container and the other side communicates with the outside of the body block, preferably at least two coupling holes 31a and 31b are provided. It is designed to be provided. At this time, the reagent container 10 is formed with a through hole 14 communicating with the coupling hole 31 of the body block.

In addition, two or more coupling holes 31 are formed in the body block 30 , and the body block 30 having two coupling holes 31 is shown in the drawing.

The connector 40 is integrally formed with the upper connector 41 to which the quantitative adjustment part 70 or the connection supply pipe 80 is connected, and the upper connector 41, and is screwed or fitted into the coupling hole 31 . A pipe connector that is integrally formed with the lower connector 42 and the lower connector 41, or is formed integrally with the upper connector 42 through the lower connector 41 to connect the suction supply pipe 50 ( 43), the upper connector 42, the lower connector 41, and the connector hole 44 formed to pass through the pipe connector 43, and the upper connector 41 and the lower connector 42 are formed to protrude to be positioned between the It is to include a flange 45 that is supported in contact with the body block 30 .

The connector hole 44 includes an upper hole 44a formed in the upper connector 41 , a lower hole 44b formed in the lower connector 42 , and a pipe hole 44c formed in the pipe connector 43 , The upper hole 44a, the lower hole 44b, and the tube hole 44c are formed to communicate with each other so as to have a straight line. At this time, the connector hole 44 has a predetermined small diameter so that the liquid reagent 60 can be transferred only when the pressing force or suction force of the quantitative control unit 70 is generated.

In addition, when the connector 40 is formed so that the pipe connector 43 is integrally connected to the upper connector 41, the connector hole 44 has an upper hole 44a and a pipe hole 44c without a lower hole 44b. This leads to direct communication.

In addition, when the pipe connector 43 is directly connected to the upper connector 41 , the pipe connector 43 is located in the lower connector 42 , and between the lower connector 42 and the pipe connector 43 . The suction supply pipe 50 is fitted into the space 46 .

In addition, a packing material 48 may be further installed in the upper hole 44a of the connector hole 44 to maintain watertightness and airtightness.

The connector configured as described above is installed in one or more coupling holes among a plurality of coupling holes 31 provided in the body block.

In addition, when the quantitative adjustment unit 70 or the connection supply pipe 80 is not connected to the connector 40, the connector cap 47 is installed in the upper connector 41 of the connector, and the connector hole 44 passes through the connector 40. The inflow or discharge of the liquid reagent 60 is blocked. The coupling of the connector cap 47 and the upper connector 41 is coupled to maintain watertightness by fitting by means of a screw thread or packing.

In addition, the coupling of the quantitative control unit 70 or the connection supply pipe 80 and the upper end connector 41 is coupled to maintain watertightness/tightness by thread coupling or fitting coupling.

The suction supply pipe 50 is installed so that one side is connected to the pipe connection port 43 of the connector, and the other side is located in the liquid reagent 60 stored in the reagent container inner space 11, and it is made of a hose type made of a flexible material. have. At this time, the suction supply pipe 50 is installed with a sufficient length so that the other side is located in the liquid reagent 60 .

The liquid reagent 60 refers to various chemical solutions used in the laboratory, such as acids, bases, and the like.

The quantitative control unit 70 is connected to and coupled to the connector 40 of the reagent supply unit and has a storage case 71 having a receiving space 71a of a predetermined volume therein, and the storage case 71 is airtight. It is inserted so as to include a pressure band 72 for compressing or expanding (relaxing) the receiving space (71a).

At this time, on the outer surface of the storage case 71, the capacity of the liquid reagent sucked into the accommodation space 71a, the capacity of the liquid reagent stored in the accommodation space 71a, or the internal space 11 of the reagent container is pressed. A display portion 71b such as a scale is formed to measure the amount of air. The quantitative control unit 70 configured as described above may be, for example, a piston syringe widely used in a laboratory.

The quantitative control unit 70 configured as described above applies pressure into the internal space 11 in which the liquid reagent is stored to push the liquid reagent 60 in the direction of the suction supply pipe 50, or the internal space through the suction supply pipe 50 ( 11) has a function of sucking the liquid reagent (60) stored therein.

That is, the quantitative control unit 70 is coupled to the one side connector 40a to which the suction supply pipe 50 is connected and installed, when the liquid reagent 60 stored in the reagent container is to be sucked, and the pressure into the inner space 11 is applied. When the liquid reagent is pushed in the direction of the suction supply pipe 50 by applying it, the suction supply pipe 500 is connected to another connector 40b where it is not installed.

In addition, the quantitative adjustment unit 70 has a scale 71b formed in the storage case, so that the quantitative suction and discharge of the liquid reagent is performed.

In addition, the quantitative control unit 70 may be configured to be directly connected to the coupling hole 31 formed in the main block of the reagent supply unit.

The connection supply pipe 80 has a function of transferring and supplying the liquid reagent 60 stored in the safety reagent container 100 according to the present invention to another experimental apparatus 300, and the stored/generated liquid in the other experimental apparatus 300. It has a function of sucking/transferring the reagent 60 into the safety reagent container 100 .

The connection supply pipe 80 includes a valve body 81 coupled to the reagent supply unit 20 of the safety reagent container 100 , and a connection hose 82 connected to the valve body 81 .

The valve body 81 has a 2 way or 3 wau or 4 way valve structure, and one port 81a is connected to the connector 40 to which the suction supply pipe 50 is connected.

Such a valve body 81 may be made manually or automatically, but is preferably installed such that the direction of the fluid is changed by manual operation.

When the connection supply pipe 80 is installed between the safety reagent container 100 and the experimental apparatus 300 according to the present invention, one side of the connection hose 82 is connected to the valve body 81, and the other side is the experimental apparatus. (200) is installed to be connected.

In addition, the connection hose 82 may be installed so that one side is connected to the valve body 81 and the other side has a free end. When the connection hose is installed in this way, the bottom is passed through the other side having a free end. The liquid reagent spilled into the can be sucked and sucked/transferred into the inner space 11 of the safety reagent container 100 .

That is, the connection supply pipe 80 is connected to one connector 40a to which the suction supply pipe 50 is connected, and the quantitative control unit 70 is connected to another connector 40b to which the suction supply pipe 50 is not connected and installed. In the installed state, when the quantitative control unit is operated so that the receiving space 71a is expanded, the liquid reagent spilled on the floor through the other side of the connecting hose having a free end is transferred to the inner space 11 in the safety reagent container 100 . ) will be sucked/transferred into the

In addition, the connection supply pipe 80 may be configured to be directly coupled to the coupling hole formed in the body block of the reagent supply unit without a connector, and in this case, the suction supply pipe 50 is, as shown in FIG. 5 , Not the connector 40, but directly connected to one port 81a of the valve body 81 of the connection supply pipe, and the port 81a is inserted and installed into the coupling hole 31 of the body block.

The present invention is not limited to the specific preferred embodiments described above, and without departing from the gist of the present invention as claimed in the claims, anyone with ordinary skill in the art to which the invention pertains can make various modifications. Of course, such modifications are intended to be within the scope of the claims.

(10): Reagent container (11): Internal space
(12): main entrance (13): stopper
(14): through hole (20): reagent supply unit
(30): body block (31): coupling hole
(40): Connection port (41): Top connection port
(42): bottom connector (43): pipe connector
(44): connector hole (44a): upper hole
(44b): lower hole (44c): pipe hole
(45): Flange (46): Interspace
(47): connector cap (48): packing material
(50): suction supply pipe (60): liquid reagent
(70): quantitative control unit (71): storage case
(71a): accommodating space (71b): display part
(72): pressure band (80): connection supply pipe
(81): valve body (81a): one side port
(82): Connection hose (100): Safety reagent container
(200): Experimental device

Claims (6)

a reagent container 10 having an internal space 11 for accommodating a liquid reagent;
a reagent supply unit 20 integrally installed in the reagent vessel 10;
It is connected to the reagent supply unit 20 and is installed to supply the liquid reagent 60 into the reagent container 10, or a quantitative control unit 70 for sucking the liquid reagent 60 in the reagent container; including;
The reagent supply unit 20,
a body block 30 integrally installed on one side of the reagent container 10 and having two or more coupling holes 31 communicating with the internal space 11 of the reagent container;
A connector 40 inserted and installed in the coupling hole 31 of the body block, and
It includes a suction supply pipe 50 having one end connected to one end of the connector and the other end installed to be immersed in the liquid reagent accommodated in the reagent container inner space,
A quantitative control unit 70 is installed in the connection port 40 or the coupling hole 31 of the body block, so that the liquid reagent 60 in the quantitative control unit is injected and supplied into the internal space 11 of the reagent container, or a suction supply pipe A safety reagent container set, characterized in that the liquid reagent (60) in the reagent container inner space (11) is sucked into the quantitative control unit (70) through the (50) and the connector (40).
The method of claim 1 ;
The connector 40 includes an upper connector 41 to which the quantitative adjustment unit 70 is connected, and a lower connector 42 that is formed integrally with the upper connector 41 and is screwed or fitted into the coupling hole 31 and , a pipe connector 43 integrally formed with the lower connector 41, or integrally connected to the upper connector 42 through the lower connector 41, to which the suction supply pipe 50 is coupled, and the upper connector ( 42), a connector hole 44 formed to pass through the lower connector 41 and the pipe connector 43, and the upper connector 41 and the lower connector 42 are formed to protrude to be positioned between the body block 30 and the body block 30 A set of safety reagent vessels comprising a supported flange (45).
3. The method of claim 2;
The connector hole 44 includes an upper hole 44a formed in the upper connector 41 , a lower hole 44b formed in the lower connector 42 , and a pipe hole 44c formed in the pipe connector 43 , Safety reagent container set, characterized in that the upper hole (44a), the lower hole (44b) and the tube hole (44c) are formed to communicate with each other to have a straight line.
3. The method of claim 1 or 2;
The quantitative control unit 70 is connected to and coupled to the connector 40 of the reagent supply unit and has a storage case 71 having a receiving space 71a of a predetermined volume therein, and the storage case 71 is airtight. Safety reagent container set, characterized in that it is inserted so as to include a pressure band 72 for compressing or expanding (relaxing) the receiving space (71a).
The method of claim 1 ;
Further comprising a connection supply pipe 80 that is connected to another connector of the reagent supply unit in which the quantitative control unit 70 is not installed,
The connection supply pipe (80) comprises a valve body (81) coupled to the reagent supply unit (20) of the safety reagent container (100), and a connection hose (82) connected to the valve body (81). Safe reagent container set.
The method of claim 1 ;
It further includes a connection supply pipe 80 that is connected and installed in a coupling hole on one side of the body block to which the quantitative control unit 70 is not connected,
The connection supply pipe 80 includes a valve body 81 coupled to the reagent supply unit 20 of the safety reagent container 100 and a connection hose 82 connected to the valve body 81,
A safety reagent container set, characterized in that one port 81a of the valve body 81 is inserted into the coupling hole 31 of the body block, and the suction supply pipe 50 is directly connected to the one port 81a. .

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