KR101501882B1 - Equipment for manufacturing diagnostic kit having a dehumidifying portion and method for manufacturing diagnostic kit and diagnostic kit - Google Patents

Abstract

The purpose of the present invention is to mold a diagnostic kit body and a humidifying unit as one body. The present invention provides an apparatus for manufacturing a diagnostic kit, having an integral type humidifying unit, wherein the apparatus comprises: an upper molding member supply unit; a lower molding member supply unit; an upper molding unit which is disposed on a first movement path, and simultaneously molds an upper diagnostic kit body composed of an upper humidification unit and an upper diagnostic unit as one body, which are set on the supplied upper molding member, and an upper diagnostic liquid suction and discharge unit connected to the upper diagnostic kit body; a lower molding unit which is disposed on a second movement path, and sequentially molds a lower diagnostic kit body composed of a lower humidification unit and a lower diagnostic unit as one body, which are set on the supplied lower molding member, and a lower diagnostic liquid suction and discharge unit connected to the lower diagnostic kit body; an object input unit which is disposed on the second movement path, and puts a humidifier into the lower humidification unit and a diagnostic strip into the lower diagnostic unit; a binding unit which binds the upper diagnostic kit body and the lower diagnostic kit body and binds the upper diagnostic liquid suction and discharge unit and the lower diagnostic liquid suction and discharge unit; and a cutting unit which is disposed on a third movement path, and cuts the bound upper diagnostic kit body and lower diagnostic kit body and the bound upper diagnostic liquid suction and discharge unit and lower diagnostic liquid suction and discharge unit into predetermined sized.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for manufacturing a diagnostic kit having an integral type dehumidifying unit, a method of manufacturing the same,

The present invention relates to a diagnostic kit manufacturing facility, and more particularly, to a diagnostic kit manufacturing facility having an integrated dehumidifying portion integrally formed with an integrated type dehumidifying portion such that a sucking and discharging means such as a syringe is removable A diagnostic kit manufacturing method, and a diagnostic kit.

In general, a device for examining or examining the presence of a single or multiple substances in a liquid sample, for example a urine or blood sample, is referred to as a diagnostic kit.

Specifically, the modern diagnostic business field is integrated into one of the Point-Of-Care Testing (POCT).

Point-Of-Care Testing (POCT) is a test that is performed outside of the centralized laboratory and refers to equipment that is available to the general public without expert knowledge. Currently, diagnostic fields are expanding from hospitals to field and individual.

In particular, the rapid diagnostic kits typified by immunochromatographic analysis are used to identify diseases or detect changes in the healthcare field, and they can be used for qualitative and quantitative analysis of trace analytes in a variety of fields, It is being developed in a simple way. In the field of health care, applications are being extended to pregnancy, ovulation, infectious diseases, drug abuse, acute myocardial infarction, and cancer.

Such a diagnostic kit is generally composed of a case having a diagnostic strip for the purpose of diagnosis.

Here, the case of such a diagnostic kit is manufactured by molding to have a certain thickness.

In particular, the diagnostic kit is a one-time kit because it can not be reused after the diagnostic strip is used.

Accordingly, there is a problem that the diagnostic kit manufactured through the plastic mold formation is used as a one-time use, and waste of the product is increased due to discarding.

In addition, the volume of the diagnostic kit itself is increased due to the reason that it is manufactured through the molding process, thereby increasing the cost of logistics when the product is moved after production.

Prior art relating to the present invention includes Korean Patent Laid-Open Publication No. 10-2012-0086985 (published on Aug. 20, 2012).

An object of the present invention is to provide a diagnostic kit manufacturing facility having an integral type dehumidifying portion which is formed integrally with a body of a diagnostic kit and integrally formed with a dehumidifying portion in a process of molding, A kit manufacturing method, and a diagnostic kit.

It is another object of the present invention to provide a diagnostic kit manufacturing facility having an integrated type dehumidifying portion capable of forming a measurement object liquid sucking and discharging means so as to be detachable from a diagnostic kit body during a process of forming a diagnostic kit, And a diagnostic kit.

It is a further object of the present invention to provide a diagnostic kit which can confirm the space of a dehumidifying part formed integrally with a body of a diagnostic kit and input a set amount of dehumidifying agent in accordance with the space of the dehumidifying part, And an integrated type dehumidifying portion which can be removed by an amount of injected or not injected, and a diagnostic kit manufacturing method and a diagnostic kit using the same.

In a preferred aspect of the present invention, the present invention provides an image forming apparatus comprising: an upper molding member supply unit for supplying an upper molding member along a first movement path; A lower molding member supply unit for supplying the lower molding member along the second movement path; An upper diagnostic kit body disposed on the first movement path and having an upper dehumidifying unit and an upper diagnostic unit formed integrally with the upper molded member to be supplied, and an upper diagnostic liquid suction and discharge unit connected to the upper diagnostic kit body, An upper shaping section for shaping at the same time; A lower diagnosis kit body disposed on the second movement path and having a lower dehumidification part and a lower diagnosis part integrally formed in the lower molded member to be supplied, and a lower diagnosis liquid suction and discharge unit connected to the lower diagnosis kit body, A lower molding unit for molding at the same time; An object dispensing part disposed on the second moving path for dispensing a dehumidifying agent into the lower dehumidifying part and injecting a diagnostic strip into the lower diagnosis part; Wherein the first moving path and the second moving path are disposed on a third moving path forming a path, and the body of the upper diagnostic kit, the body of the lower diagnostic kit, and the lower side of the upper diagnostic liquid sucking- A sticking portion for sticking the diagnostic liquid suction and discharge means together; And a cutting unit which is disposed on the third movement path and cuts the upper side diagnostic kit body and the lower side of the diagnosis kit body together with the upper side diagnostic liquid suction and discharge means and the lower side diagnostic liquid suction and discharge means, The present invention provides a diagnostic kit manufacturing facility having an integral type dehumidifying portion including an integrated type dehumidifying portion.

The upper shaping unit press-molds the upper diagnostic kit body.

Wherein the upper diagnosis unit is formed so as to form a visible window and one or more diagnosis liquid injection holes and the upper dehumidification unit is integrally formed on the side of the upper diagnosis unit and is formed so as to protrude upward and to form a plurality of through holes, It is preferable that the upper diagnostic liquid sucking and discharging means is formed so as to be connected through the side portion of the upper side diagnostic kit body and the upper side connecting line.

The lower molding section press-molds the lower diagnostic kit body.

Wherein the lower diagnosis part is formed so as to form a strip seating groove on which a diagnostic strip is seated and the lower dehumidification part is integrally formed on a side of the lower diagnosis part and is formed so as to form a depressed moisture storage recess in a downward direction, It is preferable that the discharging means is formed so as to be connected through the side of the lower diagnostic kit body and the lower connection line.

The upper end of the upper diagnostic kit body and the lower end of the lower end of the diagnostic kit body are joined together by ultrasonic welding, high frequency welding, or thermal welding.

Wherein the upper diagnosing portion and the lower diagnosing portion are joined together to form a diagnostic portion, the upper dehumidifying portion and the lower dehumidifying portion are joined together to form a dehumidifying portion, and the upper diagnostic liquid suction and discharge means and the lower diagnostic liquid suction and discharge means So that the diagnostic liquid suction and discharge means is formed.

Wherein the upper and lower connecting lines are joined together to form a connecting line, the diagnostic liquid sucking and discharging means has suction and discharge holes formed at one end thereof, a space connected to the suction and discharge holes is formed therein, It is preferable that the line is broken when a predetermined external force is applied.

It is preferable that the diagnostic liquid sucking and discharging means is formed of a flexible and transparent material having a hardness equal to or lower than that of the diagnostic kit body.

The cutting section includes a first cut section for cutting along the rim of the diagnostic liquid suction and discharge means and a second cut section for cutting along the rim of the diagnostic kit body.

It is preferable that the second cut portion is further provided with an auxiliary cutter which punctures holes at predetermined intervals in the connection line or cuts a portion at a predetermined interval.

The object dispensing part includes a strip dispensing part disposed on the second moving path and sequentially injecting a diagnostic strip into the strip receiving groove formed in the lower diagnostic kit body to be molded and moved, And a dehumidifying agent introducing unit for sequentially introducing dehumidifying agent into the dehumidifying agent storage groove formed in the lower diagnostic kit body which is sequentially formed and moved.

The dehumidifying agent input unit may include a measuring unit for measuring the groove size of the dehumidifying agent storage groove through image capturing and a control unit for controlling the driving of the dehumidifying agent input unit so as to input the dehumidifying agent at a predetermined input amount according to the measured groove size .

The dehumidifying agent input unit may further include a sensor for detecting an input amount of the dehumidifying agent to be introduced, and a discharger for forcibly discharging the dehumidifying agent introduced into the dehumidifying agent storage groove using a vacuum.

Preferably, the control unit further controls the amount of the dehumidifying agent to be added by using the dehumidifying agent input unit so that the amount of the dehumidified agent detected is equal to the predetermined amount, or the dehumidifying agent is forced to be discharged using the discharging unit.

In another aspect, the present invention provides a method of manufacturing a diagnostic kit having an integrated dehumidifying part for manufacturing a diagnostic kit using a diagnostic kit manufacturing facility having an integrated dehumidifying part.

In another aspect, the present invention provides a diagnostic kit manufactured using a diagnostic kit manufacturing facility having an integrated dehumidifying portion.

The present invention has an effect that a dehumidifying part is molded integrally with a body of a diagnostic kit and a dehumidifying agent is injected into a dehumidifying part in a molding process.

In addition, the present invention has the effect of being able to form the liquid suction and discharge means for measurement to be detachable from the diagnostic kit body during the process of molding the diagnostic kit.

The present invention also provides a diagnostic kit comprising: a space for a dehumidifying part formed integrally with a body of a diagnostic kit; and a dehumidifying agent set in accordance with the space of the dehumidifying part, It is possible to remove the amount of the foreign substance by the amount of the foreign substance.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of an apparatus for manufacturing a diagnostic kit having an integrated dehumidifying part of the present invention. FIG.
2 is a view showing an example of an object insertion part according to the present invention.
FIG. 3 is a perspective view showing an upper side of the upper and lower diagnosis kit bodies according to the present invention before cementing. FIG.
FIG. 4 is a perspective view showing an assembled diagnostic kit according to the present invention. FIG.
FIG. 5 is another perspective view showing a state before the upper and lower diagnosis kit bodies according to the present invention are bonded together. FIG.
Figure 6 is another perspective view showing a cemented diagnostic kit in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus and method for manufacturing a diagnostic kit having an integrated dehumidifying part of the present invention and a diagnostic kit manufactured thereby will be described with reference to the accompanying drawings.

FIG. 1 is a view showing a configuration of an apparatus for manufacturing a diagnostic kit having an integrated dehumidifying part of the present invention, FIG. 2 is a view showing an example of an object input part according to the present invention, FIG. 4 is a perspective view showing the assembled diagnostic kit according to the present invention. FIG. 4 is a perspective view showing the assembled diagnostic kit according to the present invention.

1, an apparatus for manufacturing a diagnostic kit having an integrated dehumidifying part according to the present invention comprises a upper forming member supplying part 100, a lower forming member supplying part 200, an upper forming part 110, a lower forming part 210, an object insertion unit 300, a joint unit 400, and a cut unit 500.

The upper forming member feeding part 100 and the lower forming member feeding part 200,

The upper forming member supply part 100 includes an upper roller for winding the upper molded member 1 and an upper driver (not shown) for rotating the upper roller to supply the upper molded member 1 along the first moving path a .

The lower forming member supply unit 200 includes a lower roller for winding the lower molded member 2 and a lower driver for rotating the lower roller to supply the lower molded member 2 along the second moving path b ).

Here, the first movement path (a) and the second movement path (b) form independent paths.

The upper molded member 1 and the lower molded member 2 are formed of a sheet or a film.

The upper and lower molded members 1 and 2 may be made of one or more of PA, APET, COPET, PET, PE, ABS, PS, PP, CPR, EG, PVC, PC, EVA, LDPE, And may be formed of a material.

Further, the upper and lower molded members 1 and 2 may be formed of a PET layer formed on the CPP layer. In the diagnostic kit, the CPP layer may be formed on the outer surface, and the PET layer may be formed on the inner surface.

The upper shaping unit 110 and the lower shaping unit 210,

The upper forming unit 110 is disposed on the first moving path a.

The upper forming unit 110 includes an upper mold 111 and a lower mold 112 and a first moving path a is formed between the upper mold 111 and the lower mold 112.

The upper mold 111 and the lower mold 112 are mutually interlocked with each other by the external force so that a predetermined shape can be press-formed on the upper molded member 1 moved along the first movement path a.

The upper mold 111 and the lower mold 112 may be preheated at a constant temperature, for example, 140 degrees Celsius.

3, the upper mold 111 and the lower mold 112 are provided with an upper dehumidifying portion 71, an upper diagnosing portion 61 and an upper diagnosing liquid sucking and discharging means 81 for press- A forming punch is formed.

Therefore, the upper molded member 1 moved along the first moving path (a) is deformed due to the engagement of the upper mold 111 and the lower mold 112, the upper dehumidifying portion 71, the upper diagnosing portion 61, The upper diagnostic liquid suction and discharge means 81 is formed.

The upper shaping unit 110 includes an upper diagnostic kit body 51 in which an upper dehumidifying unit 71 and an upper diagnosing unit 61 are formed in the upper molded member 1 and an upper diagnostic kit body 51 in which the upper diagnostic liquid sucking and discharging unit 81 ).

Here, the upper dehumidifying part 71 is formed so as to protrude upward from the upper side diagnostic kit body 51.

The upper diagnosis unit 61 is formed to form one or a plurality of grooves so that a visible window 61b and one or more diagnosis liquid injection holes 61a are formed.

The upper diagnostic liquid sucking and discharging means 81 is integrally formed on the side or front end of the upper diagnostic kit body 51.

The upper diagnostic liquid sucking and discharging means 81 is formed to be connected through the upper connecting line 91 at the side or the front end of the upper diagnostic kit body 51.

Meanwhile, the upper shaping unit 110 includes a perforation 130 disposed on the first movement path a.

The perforation 130 is formed by inserting through holes 71a, a visible window 61b, and a diagnostic liquid injection hole 61a into the upper diagnostic kit body 51, which is moved through the upper and lower molds 111 and 112, do.

A plurality of through holes 71a are drilled in a portion protruding upward from the upper dehumidifying portion 71. The visible window 61b and the diagnostic liquid inlet hole 61a are formed in the upper portion of the upper diagnosing portion 61 And is formed by perforating the bottom of the groove portion.

The upper diagnostic liquid sucking and discharging means 81 is connected to the upper diagnostic kit body 51 through a connection line 91 and is formed to be convex upward. For example, a shape corresponding to half the shape of the eyedropper.

1 to 3, the lower molding part 210 according to the present invention press-molds the lower side diagnostic kit body 52. As shown in FIG.

The lower forming part 210 may also include an upper mold 211 and a lower mold 212 disposed on the second movement path b.

The second movement path (b) is formed between the upper mold (211) and the lower mold (212).

The lower molded member 2 moved along the second movement path b is moved in a direction perpendicular to the direction in which the diagnostic strip 20 is seated because the upper and lower molds 211 and 212 are interlocked with each other, (62a) is formed.

The lower dehumidifying part 72 is formed so as to be integrally formed on the side of the lower diagnosis part 62 and to form a downwardly concave dehumidifying agent storage groove 72a.

The lower diagnostic liquid suction and discharge means 82 is connected to the side of the lower diagnostic kit body 52 through a lower connection line 92. [

The upper and lower molds 211 and 212 of the lower molding part 210 may be substantially the same as the upper and lower molds 111 and 112 of the upper molding part 110.

On the other hand, the above-described upper and lower diagnostic liquid sucking and discharging means 81 and 82 are formed of a flexible material which is formed to have the same hardness as that of the upper and lower diagnostic kit bodies 51 and 52.

In this case, the upper and lower molded members 1 and 2 are each supplied with one film having the same hardness.

Alternatively, the upper and lower molded members 1 and 2 may be provided with separate flexible material regions for forming the upper and lower diagnostic liquid suction and discharge units 81 and 82, respectively.

That is, the hardness of the region where the upper and lower diagnostic liquid suction and discharge means 81 and 82 are molded may be made of a flexible material having lower hardness than the upper and lower diagnostic kit bodies 51 and 52 other than the above region. The region may be formed of a transparent material.

The object-

Referring to Figs. 1 to 3, the object insertion part 130 according to the present invention is disposed on the second movement path b.

The object injection unit 300 includes a dehumidifying agent injection unit 310 and a strip injection unit 320.

The dehumidifying agent injecting unit 310 sequentially injects the dehumidifying agent 10 into the dehumidifying agent storage groove 72a formed in the lower diagnostic kit body 52, which is sequentially formed and moved.

The dehumidifying agent may be silica gel. The silica gel is preferably injected in the form of granules.

The dehumidifying agent input unit 310 includes a dehumidifying agent reservoir 312, a dehumidifying agent injection nozzle 311, and a valve 313.

A dehumidifying agent (10) in a granular form is stored in the dehumidifying agent reservoir (312).

The dehumidifying agent injecting nozzle 311 is arranged to inject the dehumidifying agent 10 from the dehumidifying agent reservoir 312 into the dehumidifying agent storage groove 72a of the lower diagnostic kit body 2.

Preferably, the desiccant injection nozzle 311 is installed obliquely at the upper portion of the desiccant storage groove 72a along the moving direction of the lower diagnostic kit body 52.

The valve 313 receives a control signal from the controller 314 and is installed in the dehumidifying agent supply nozzle 311 to open and close the dehumidifying agent discharge passage.

The opening / closing time of the valve 313, that is, the amount of dehumidifying agent input per second is preset in the controller 314.

In addition, the dehumidifying agent input unit 310 further includes a measurement unit 315.

The measuring unit 315 acquires an image of the formed dehumidifying agent storage groove 72a on the second moving path b and transmits the image to the controller 314. [

The control unit 314 processes the image to calculate the size of the desiccant storage groove 72a.

In this case, the amount of dehumidifying agent introduced into the controller 314 is determined according to the size of the desiccant storage groove 72a.

Accordingly, the controller 314 opens and closes the valve 313 so that the amount of dehumidifying agent charged according to the calculated size of the dehumidifying agent storage groove 72a is inputted to the dehumidifying agent storage groove 72a.

The dehumidifying agent input unit 310 according to the present invention includes a sensor 316 for sensing the input amount of the desiccant 10 to be introduced and a dehumidifying agent 10 introduced into the desiccant storage groove 72a using a vacuum And an ejector 317 for forced ejection.

The sensor 316 may be a sensor for measuring the opening / closing time of the valve 313.

The discharger 317 has a discharge tube 317a directed toward the desiccant storage groove 72a and a discharge tube 317a provided on the discharge tube 317a to receive a vacuum suction force from the discharge tube 317a in response to a control signal from the controller 314. [ And a vacuum pump 317b for forcibly discharging the desiccant 10.

The control unit 314 may further include the dehumidifying agent 10 by using the dehumidifying agent input unit 310 so that the input amount of the dehumidified agent 10 is equal to the predetermined amount, So that the desiccant 10 is forcedly discharged.

That is, due to the difference between the valve opening time sensed by the sensor 316 and the valve opening time indicated by the valve 313 in the control unit 314, it is possible to calculate the over- have.

In this case, the controller 314 performs an error process, forcibly discharges the desiccant 10 charged into the desiccant storage groove 72a through the discharger 317, and discharges the desiccant 10 to the predetermined amount again. .

The strip insertion part 320 according to the present invention is disposed on the second movement path b and includes the strip seating groove 62a formed in the lower diagnosis kit body 52 which is sequentially formed and moved, The diagnostic strip 20 is sequentially injected into the test strip 20.

[0042]

The sticky part 400 according to the present invention is arranged on the third movement path c in which the first movement path a and the second movement path b form a path, The upper diagnostic liquid sucking and discharging means 81 and the lower diagnostic liquid sucking and discharging means 82 are attached to each other.

The joining part 400 uses ultrasonic welding, high frequency welding, or heat welding.

The diagnostic kit body 50 in which the upper molded member 1 and the lower molded member 2 are attached to each other to form the dehumidifying portion 70 and the diagnostic portion 60 in the joint portion 400, The diagnostic liquid suction and discharge means 80 connected to the diagnostic kit body 50 via the connection line 90 is formed.

The cut-

The cut portion 500 according to the present invention is disposed on the third movement path c of the rear end of the sticking portion 400 and includes a first cut portion 510 cut along the rim of the diagnostic liquid suction and discharge means 80 And a second cut portion 520 cutting along the rim of the body 50 of the diagnostic kit.

Each of the first cut portion 510 and the second cut portion 520 has a cutting edge that is interlocked with each other to cut the object.

Therefore, the first cut portion 510 cuts along the rim of the diagnostic liquid suction and discharge means 80 such as a syringe.

In addition, the second cut portion 520 cuts the rim to form the shape of the diagnostic kit body 50.

After passing through the first and second cuts 510 and 520, the diagnostic kit body 50 to which the diagnostic liquid sucking and discharging means 80 is connected can be cut off and separated from the attached molded members 1,2.

Although not shown in the drawing, the diagnostic kit body 50 to which a plurality of diagnostic liquid suction and discharge means 80, which are cut and separated as described above, is connected is conveyed to the stacking position along the conveying conveyor.

In addition, the residual molded member from which the diagnostic kit body 50 is detached may be wound around the other collecting roller and discarded, or may be cut to a predetermined size or smaller by using a cutting blade (not shown) .

In addition, although not shown in the drawing, in the present invention, a test section for inspecting diagnostic products sucking and discharging means can be disposed between the joint portion and the cut portion.

As shown in Figs. 3 and 4, the inspection unit includes a pair of pressure members which are lifted and lowered in the directions opposite to each other above and below the diagnostic liquid suction and discharge means such as a syringe, and a side image of the diagnostic liquid suction and discharge means Have a camera to shoot.

The pair of pressing members deforms the shape by pressing the upper and lower ends of the diagnostic liquid suction and discharge means and returns to the home position.

Then, the camera acquires the side image of the deformed diagnostic liquid suction and discharge means after the set measurement time, and transmits it to the control unit.

The control unit judges whether or not the edges of the diagnostic liquid suction and discharge means coincide with each other in the reference frame range that forms a normal image.

Then, the control unit makes the diagnostic kit body (hereinafter, referred to as a defective portion) having the diagnostic liquid suction and discharge means determined to be defective not to be cut by not driving the cut portion in the subsequent process, The defective portion may be cut off and recovered.

Accordingly, in the present invention, inspection of good quality of the diagnostic liquid sucking and discharging means such as a syringe is performed in a molding process, thereby shortening the processing time, thereby increasing the productivity and improving the quality of the product.

5 and 6, the diagnostic liquid suction / dispensing means 80 'according to the present invention has a hole in its end other than the syringe shown in Figs. 3 and 4, It is needless to say that they can be formed into other shapes in which a space that can be temporarily stored is formed.

In this case, it is preferable that the diagnostic liquid suction / dispensing means 80 'is formed by attaching the upper-side diagnostic liquid suction / dispensing means 83 and the lower-side diagnostic liquid suction / dispensing means 84 to each other.

As described above, the embodiment according to the present invention has the advantages that the dehumidifying part is integrally formed together with the body of the diagnostic kit, and the dehumidifying agent is injected into the dehumidifying part in the process of molding, .

In addition, the embodiment of the present invention has an advantage that the measurement object liquid suction and discharge means can be formed so as to be detachable from the diagnostic kit body during the process of molding the diagnostic kit.

In addition, in the embodiment of the present invention, the space of the dehumidifying part formed integrally with the body of the diagnostic kit is confirmed, and a set amount of dehumidifying agent is charged according to the space of the dehumidifying part, , And can be removed by an amount that is inserted or not inserted.

Although specific embodiments of the diagnostic kit manufacturing facility having the integrated dehumidifying part of the present invention have been described above, it is apparent that various modifications can be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

It is to be understood that the foregoing embodiments are illustrative and not restrictive in all respects and that the scope of the present invention is indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

1: upper molding member
2: Lower molded member
50: Diagnostic kit body
51: Upper diagnostic kit body
52: Lower Diagnostic Kit Body
60:
61:
62: lower side diagnosis part
70: Dehumidification part
71: Upper dehumidifier
72: Lower dehumidifying part
80: diagnosis liquid sucking and discharging means
81: upper side diagnostic liquid sucking and discharging means
82: Lower side diagnostic liquid sucking and discharging means
90: connection line
100: Upper forming member supply part
110: upper molding part
130: Thousand studies
200: lower forming member supply part
210: Lower molding part
300: object input unit
310: Desiccant input unit
320:
400:
500; Cutting section
510: 1st well end
520: second cut section

Claims (11)

An upper molding member supply unit for supplying the upper molding member along the first moving path;
A lower molding member supply unit for supplying the lower molding member along the second movement path;
An upper diagnostic kit body disposed on the first movement path and having an upper dehumidifying unit and an upper diagnostic unit formed integrally with the upper molded member to be supplied, and an upper diagnostic liquid suction and discharge unit connected to the upper diagnostic kit body, An upper molding section for molding simultaneously;
A lower diagnosis kit body disposed on the second movement path and constituted by a lower dehumidification part and a lower diagnosis part integrally formed in the lower molded member to be supplied, and a lower diagnosis liquid suction and discharge unit connected to the lower diagnosis kit body, A lower molding unit for molding sequentially;
An object dispenser disposed on the second moving path for dispensing a dehumidifying agent to the lower dehumidifying part and dispensing a diagnostic strip to the lower diagnosis part;
Wherein the first moving path and the second moving path are disposed on a third moving path forming a path, and the body of the upper diagnostic kit, the body of the lower diagnostic kit, and the lower side of the upper diagnostic liquid sucking- A sticking portion for sticking the diagnostic liquid sucking and discharging means together;
And a cutting unit which is disposed on the third movement path and cuts the upper side diagnostic kit body and the lower side of the lower side of the diagnosis kit body together with the upper side diagnostic liquid suction and discharge means and the lower side diagnostic liquid suction and discharge means, Wherein the dehumidifying part is provided with an integrated dehumidifying part.
The method according to claim 1,
The upper shaping unit may include:
The upper diagnostic kit body is press-molded,
The upper diagnosis unit may be formed so as to form a visible window and one or more diagnosis liquid injection holes,
Wherein the upper dehumidifying part is integrally formed on the side of the upper diagnosis part and is formed so as to protrude upward and to form a plurality of through holes,
Wherein the upper diagnostic liquid sucking and discharging means is formed so as to be connected to a side of the upper diagnostic kit body through an upper connecting line.
3. The method of claim 2,
The lower-
The lower diagnostic kit body is press-molded,
The lower diagnosis part is formed so as to form a strip seating groove on which the diagnostic strip is seated,
The lower dehumidifying part is integrally formed on the side of the lower diagnosis part and is formed so as to form a depressed dehumidifying agent storage groove downward,
And the lower diagnosis liquid sucking and discharging means is formed to be connected to the lower side of the lower diagnostic kit body through a lower connection line.
The method of claim 3,
Wherein the upper and lower diagnostic kit bodies are attached to each other so as to form a diagnostic kit body using ultrasonic welding, high frequency welding, or thermal welding,
The upper diagnosis unit and the lower diagnosis unit are joined together to form a diagnosis unit,
Wherein the upper dehumidifying part and the lower dehumidifying part are joined together to form a dehumidifying part,
Wherein the upper diagnostic liquid suction and discharge means and the lower diagnostic liquid suction and discharge means are joined together to form a diagnostic liquid suction and discharge means,
The upper and lower connection lines are joined together to form a connection line,
Wherein the diagnostic liquid sucking and discharging means has suction and discharge holes formed at one end thereof, a space connected to the suction and discharge holes is formed therein,
Wherein the connection line is broken when a predetermined external force is applied to the connection line.
5. The method of claim 4,
Wherein the diagnostic liquid sucking and discharging means is formed of a flexible and transparent material having a hardness equal to or lower than that of the diagnostic kit body.
5. The method of claim 4,
The cut-
A first cut section for cutting along the rim of the diagnostic liquid suction and discharge means,
And a second cut portion for cutting along a rim of the body of the diagnostic kit,
In the second cut portion,
Wherein a hole is drilled in the connection line at a predetermined interval or a part of the hole is cut at a predetermined interval.
The method of claim 3,
The object-
A strip injecting unit disposed on the second moving path and sequentially injecting the diagnostic strip into the strip receiving grooves formed in the lower diagnostic kit body which is sequentially formed and moved;
And a dehumidifying agent introducing portion disposed on the second moving path for sequentially introducing dehumidifying agent into the dehumidifying agent storage groove formed in the lower diagnosis kit body, Diagnostic kit manufacturing facility having parts.
8. The method of claim 7,
The dehumidifying agent-
A measuring unit for measuring a groove size of the dehumidifying agent storage groove through image capturing,
And a control unit for controlling the driving of the dehumidifying agent input unit so as to input the dehumidifying agent into the predetermined amount of input depending on the measured groove size.
9. The method of claim 8,
The dehumidifying agent-
A sensor for detecting an input amount of the dehumidifying agent to be introduced,
And a discharger for forcibly discharging the dehumidifying agent charged into the dehumidifying agent storage groove by using a vacuum,
Wherein,
Wherein the control unit controls the addition of the dehumidifying agent by using the dehumidifying agent input unit so that the input amount of the detected dehumidifying agent is equal to the predetermined amount or the forced dehumidifying agent is discharged by using the exhausting unit. equipment.
A method for manufacturing a diagnostic kit having an integral type dehumidifying part, characterized by manufacturing a diagnostic kit using a diagnostic kit manufacturing facility having an integrated dehumidifying part according to any one of claims 1 to 9.
A diagnostic kit comprising: a diagnostic kit manufacturing facility having an integrated dehumidifying unit according to any one of claims 1 to 9.

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