KR20230122518A - Apparatus for cutting strip of assembly facility for rapid diagnostic test - Google Patents

Abstract

The present invention relates to a strip cutting device for an assembly facility of a rapid diagnostic device for cutting a strip sheet of an assembly facility of a rapid diagnostic device into a plurality of strips, comprising: a frame unit installed on the floor, and a first transfer unit that slides in the left and right directions; , It is characterized in that it includes a second transfer unit that moves up and down in the vertical direction, at least one cutting drive unit that provides a cutting driving force of ultrasonic vibration, and a cutting unit that cuts the strip by ultrasonic vibration. Therefore, the present invention includes a cutting drive unit for providing ultrasonic vibration to the up-down, left-right direction transfer unit and the cutting unit, so that the strip sheet is cut into a plurality of strips by the ultrasonic vibration, thereby improving the cutting performance of the cutting unit and at the same time improving the lifespan of the cutting unit. and provides the effect of facilitating maintenance.

Description

Strip cutting device of rapid diagnostic machine assembly facility {APPARATUS FOR CUTTING STRIP OF ASSEMBLY FACILITY FOR RAPID DIAGNOSTIC TEST}

The present invention relates to a strip cutting device for an assembly facility of a rapid diagnostic device, and more particularly, to a strip cutting device for an assembly facility of a rapid diagnostic device that cuts a strip sheet of the rapid diagnostic device assembly facility into a plurality of strips.

Recently, kits capable of easily diagnosing diseases such as hepatitis, AIDS, corona, etc., or pregnancy using urine, blood, or saliva have been widely used. These diagnostic kits have a strip shape in which a membrane made of a material capable of absorbing liquids such as urine, blood, saliva, etc. is attached to an upper surface of a long and thin rod-shaped substrate, and a diagnostic reagent is smeared on one side of the membrane.

In this diagnostic kit, when urine, blood, or saliva is applied to the other side of the membrane, the urine or blood is absorbed to one side of the membrane and reacts with the reagent, and when a specific component in urine, blood, or saliva reacts with the reagent, the color of the reagent Pregnancy or disease can be confirmed by this change.

However, since the diagnostic kit strip has a long and thin rod shape, it is easily bent or damaged by an external force, so care is required when transporting or using the strip. For this reason, diagnostic kits in which strips are accommodated in cassettes made of a hard material, mainly synthetic resin, have recently been widely used. The cassette mainly consists of an upper case and a lower case, and is assembled by accommodating a strip in the lower case and then snap-joining the upper case and the lower case.

However, until now, there is no device for automatically accommodating strips in cassettes, and thus, diagnostic kits are assembled by manually accommodating strips in cassettes.

In particular, rapid diagnostic kits represented by immunochromatographic analysis are used to identify diseases or identify changes in the health and medical field, and qualitatively and quantitatively test trace amounts of analytes in various fields such as food and biological processing fields and environmental fields. developed in a simple way. In the field of health care, the application range is expanding to pregnancy, ovulation, infectious diseases, drug abuse, acute myocardial infarction, and cancer.

In general, such a diagnostic kit is composed of a case having a diagnostic strip according to a purpose to be diagnosed. Here, the case of the diagnostic kit is manufactured by molding to have a certain thickness.

In general, a diagnostic kit is used to diagnose infectious diseases such as blood sugar, hepatitis, pregnancy, and corona by using urine, blood, or saliva. It is manufactured in the form of a strip to which the diagnostic reagent of this absorbing material is attached.

In this way, in the conventional method of manufacturing a diagnostic kit, first, a reagent kit having each diagnostic reagent attached to a plate-shaped sheet in a row is manufactured, and then the reagent kit is cut at regular intervals with a conventional cutting machine, thereby forming a strip. It was possible to manufacture a diagnostic kit of the form.

However, in the method of manufacturing the conventional diagnostic kit described above, it is common that the reagent kit is supplied manually to the cutting machine, and productivity is remarkably high as transport or packaging is performed in a separate work process even after cutting. There was a problem with it falling off.

In order to solve these problems, automation equipment has been manufactured and used in the past, but the structure of the equipment is not only complicated, but also has a problem that productivity is low and maintenance is difficult due to problems with poor interconnection.

Korean Patent Registration No. 10-1220279 (February 08, 2013) Republic of Korea Patent No. 10-0441621 (July 23, 2004) Republic of Korea Patent No. 10-1439790 (September 12, 2014)

The present invention has been devised to solve the above conventional problems, by including a cutting drive unit for providing ultrasonic vibration to a cutting unit and a transfer unit in up, down, left and right directions, so that a strip sheet is formed into a plurality of strips by ultrasonic vibration. It is an object of the present invention to provide a strip cutting device of an assembly facility of a rapid diagnostic device capable of improving the cutting performance of the cutting part by cutting, extending the life of the cutting part, and easily handling maintenance.

In addition, the present invention reduces the cutting temperature when cutting a strip of the cutting drive unit and the cutting unit by providing a cooling unit by means of a cooling fan or blowing air to the cutting drive unit and the cutting unit, thereby prolonging the replacement cycle of the cutter and preventing damage to the cutter during cutting. Another object is to provide a strip cutting device of an assembly facility of a rapid diagnostic device that can prevent and reduce cutting defects.

In addition, the present invention has a branch removal unit at the lower part of the cutting unit, thereby reducing dust generated during cutting and reducing malfunction due to the attachment of dust or foreign substances to the sensor or operating equipment of the cutting unit, thereby preventing defective cutting. Another object is to provide a strip cutting device for assembly equipment.

In addition, the present invention reduces the maintenance cost of the cutter part by applying ultrasonic waves to the cutting part and facilitating the attachment and detachment of the cutter, and at the same time, replacing the cutter in the cutter socket without separate alignment work improves the workability of replacing the cutter. Another object is to provide a strip cutting device of an assembly facility of a rapid diagnostic device capable of improving and shortening the replacement time.

In addition, the present invention is an assembly facility of a rapid diagnostic device capable of providing excellent accessibility, workability and intimacy of repair personnel when repairing a cutter failure by providing a vertical transfer unit and a left and right transfer unit in the upper frame portion of the cutter unit. It is another object to provide a strip cutting device.

The present invention for achieving the above object is a strip cutting device for a rapid diagnostic device assembly facility for cutting a strip sheet of a rapid diagnostic device assembly facility into a plurality of strips, comprising: a frame unit 10 installed on the floor; a first transfer unit 20 installed on the upper portion of the frame unit 10 and sliding in the left and right directions; A second transfer unit 30 installed on the upper portion of the frame unit 10 and installed at one end of the first transfer unit 20 to move up and down in the vertical direction; One or more cutting drive units 40 installed at one end of the lower portion of the second transfer unit 30 to provide a cutting driving force of ultrasonic vibration; It is characterized in that it includes; a cutting unit 50 installed below the cutting drive unit 40 to cut the strip by ultrasonic vibration.

In addition, the present invention is characterized in that it further includes a first cooling unit 60 installed on one side of the cutting drive unit 40 to cool the cutting drive unit 40. The first cooling unit 60 of the present invention is characterized in that it consists of a cooling fan that blows air to the cutting drive unit 40 .

In addition, the present invention is characterized in that it further comprises; a second cooling unit 70 installed on one side of the cutting unit 50 to cool the cutting unit 50. The second cooling unit 70 of the present invention includes support blocks installed at both ends of the lower portion of the second transfer unit 30; a rotation bracket installed to adjust the inclination angle of the support block; a cooling pipe installed to communicate between the rotating brackets in a longitudinal direction and supplying air; and a plurality of cooling holes spaced apart from each other in the longitudinal direction of the cooling pipe.

In addition, the present invention is installed on the other side of the cutting unit 50, it is characterized in that it further comprises a; dust removal unit 80 for removing by suctioning the dust generated when the cutting unit 50 is cut.

The frame unit 10 of the present invention includes a first frame installed on the floor; a second frame placed on one end of the first frame; a third frame placed on the other end of the first frame; and a fourth frame installed between the upper ends of the second frame and the third frame.

The first transfer unit 20 of the present invention includes a first transfer guide installed in the left and right longitudinal directions on the top of the frame unit 10; a first transfer drive piece installed at one end of the first transfer guide and providing sliding driving force in the left and right directions; and a first transfer piece installed on the first transfer guide and sliding in the left and right directions.

The second transfer unit 30 of the present invention includes a second transfer guide installed in the vertical direction on one side of the first transfer unit 20; a second transfer drive piece installed at one end of the second transfer guide and providing a lift driving force in the vertical direction; and a second transfer piece installed on the second transfer guide and moved up and down in the vertical direction.

The cutting driving unit 40 of the present invention is characterized in that it consists of an ultrasonic module that provides ultrasonic vibration to the cutting unit 50.

The cutting unit 50 of the present invention includes a cutter socket coupled to a lower portion of the cutting driving unit 40; and a cutter installed to be detachably attached to the lower portion of the cutter socket.

As described above, the present invention improves the cutting performance of the cutting unit by providing a transfer unit in up, down, left and right directions and a cutting drive unit for providing ultrasonic vibration to the cutting unit, so that the strip sheet is cut into a plurality of strips by ultrasonic vibration. At the same time, it provides the effect of extending the life of the cutting part and easily handling maintenance.

In addition, the cutting drive unit and the cutting unit are provided with a cooling fan or a cooling unit for each cutting unit, thereby lowering the cutting temperature when cutting the strip between the cutting drive unit and the cutting unit, thereby prolonging the cutter replacement cycle and preventing damage to the cutter during cutting. Provides an effect capable of reducing defects.

In addition, by providing a branch removal unit at the lower part of the cutting unit, dust generated during cutting is reduced, and malfunction due to attachment of dust or foreign substances to the sensor or operating equipment of the cutting unit is reduced, thereby providing an effect of preventing defective cutting.

In addition, by applying ultrasonic waves to the cutting part and facilitating attachment and detachment of the cutter, the maintenance cost of the cutter part is reduced, and at the same time, the cutter is replaced in the cutter socket without separate alignment work, improving the cutter replacement workability and replacement It provides an effect that can shorten the time.

In addition, by providing a vertical transfer unit and a left and right transfer unit in the upper frame portion of the cutter unit, the accessibility, workability, and intimacy of repair personnel can be improved when repairing a breakdown of the cutter unit.

1 is a configuration diagram showing an assembly facility for a rapid diagnostic device according to an embodiment of the present invention.
2 is a plan view showing an assembly facility for a rapid diagnostic device according to an embodiment of the present invention.
3 is a detailed view showing an assembly facility of a rapid diagnostic device according to an embodiment of the present invention.
4 is a configuration diagram showing a strip cutting device of an assembly facility of a rapid diagnostic device according to an embodiment of the present invention.
5 is a configuration diagram showing a cutting drive unit and a cutting unit of a strip cutting device of an assembly facility for a quick diagnostic device according to an embodiment of the present invention.
6 is a detailed view showing a cutting part of a strip cutting device of an assembly facility of a rapid diagnostic device according to an embodiment of the present invention.
7 is a detailed view showing a first cooling unit of a strip cutting device of an assembly facility of a rapid diagnostic device according to an embodiment of the present invention.
8 is a detailed view showing a second cooling unit of a strip cutting device of an assembly facility of a rapid diagnostic device according to an embodiment of the present invention.
9 is a state diagram showing an operating state of a second transfer unit of a strip cutting device of an assembly facility of a rapid diagnostic device according to an embodiment of the present invention.
10 is a state diagram showing a state during operation of a first transfer unit of a strip cutting device of an assembly facility of a rapid diagnostic device according to an embodiment of the present invention.
11 is a state diagram showing an operation completion state of a first transfer unit of a strip cutting device of an assembly facility of a rapid diagnostic device according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a configuration diagram showing an assembly facility for a rapid diagnosis device according to an embodiment of the present invention, FIG. 2 is a plan view showing an assembly facility for a rapid diagnosis device according to an embodiment of the present invention, and FIG. 3 is an example of the present invention. It is a detailed view showing an assembly facility of a rapid diagnostic device according to an embodiment, and FIG. 4 is a configuration diagram showing a strip cutting device of an assembly facility of a rapid diagnostic device according to an embodiment of the present invention. FIG. 5 is an embodiment of the present invention. Figure 6 is a detailed view showing the cutting part of the strip cutting device of the assembly facility of the rapid diagnostic device according to an embodiment of the present invention, 7 is a detailed view showing the first cooling part of the strip cutting device of the rapid diagnostic device assembly facility according to an embodiment of the present invention, and FIG. 8 is the strip cutting device of the rapid diagnostic device assembly facility according to an embodiment of the present invention. Figure 9 is a detailed view showing the second cooling unit of the present invention, Figure 9 is a state diagram showing the operating state of the second transfer unit of the strip cutting device of the assembly equipment of the rapid diagnostic device according to an embodiment of the present invention, Figure 10 is an embodiment of the present invention 11 is a state diagram showing a state during operation of the first transfer unit of the strip cutting device of the assembly facility of the rapid diagnostic device according to an example, and FIG. It is a state diagram showing the operation completion state.

As shown in FIGS. 1 to 4, the strip cutting device of the assembly facility of the rapid diagnostic device according to the present embodiment includes a frame part 10, a first conveying part 20, a second conveying part 30, and a cutting drive part 40. ), the cutting unit 50, the first cooling unit 60, the second cooling unit 70, and the dust removal unit 80 are included, and the strip sheet of the quick diagnostic device assembly facility is cut into a plurality of strips. It is a strip cutting device of an assembly facility of a rapid diagnostic device.

The assembly equipment of the rapid diagnostic device of the present invention includes an input unit 100, a division unit 200, a spacing adjustment unit 300, a first coupling unit 400, a second coupling unit 500, and a line transfer unit 600. . It is an assembly facility of a rapid diagnosis device that includes an assembly completion unit 700, a defect processing unit 800, and a package transfer unit 900, and assembles the rapid diagnosis device strip into the case.

The input unit 100 is installed on one side upstream of the base unit 1000 and inserts the stacked sheets of the plurality of strips, respectively, and cuts them into a plurality of strips. It consists of an input transfer means 130.

The dividing unit 200 is installed at both ends downstream of the input unit 100 to clamp and divide the cut plurality of strips, and the spacing adjusting unit 300 is installed downstream of the dividing unit 200 to cut It consists of a lamination conveying means 310, a conveying means 320, a gap adjusting means 330, and a replenishing means 340 so as to collectively adjust the spacing between the lamination of a plurality of strips.

The first coupling unit 400 is a coupling member that is installed downstream of the spacing adjusting unit 300 and collectively couples the lamination of a plurality of strips with the spacing adjusted to each lower case, and the lower case installed on one side is loaded. The lower case is discharged from the facility, and a plurality of strips are coupled to the upper portion of the lower case, respectively.

The second coupling unit 500 is a second coupling member installed downstream of the first coupling unit 400 to collectively couple the upper case to the lower case. By dispensing, the upper case is coupled to the upper portion of the lower case, respectively.

The line transfer unit 600 is. A line transfer member installed between the first coupler 400 and the second coupler 500 to individually transfer the lower case and the upper case in-line, and the line transfer unit 600 separates the lower case and the upper case. It is preferable that a plurality of fixed conveying means is arranged in a straight line so as to individually convey in-line.

The assembly completion unit 700 is installed downstream of the second coupling unit 500 and presses the upper case collectively to the lower case to complete the assembly of the rapid diagnostic device. In the temporarily assembled state, the upper case is finally fully assembled into the lower case by pressing from the top and bottom using compression equipment such as a press or roller.

The defect processing unit 800 is installed downstream of the assembly completion unit 700 and is a defect processing member that inspects the assembled rapid diagnostic device and processes defective products, and selects and removes defective products through vision inspection using a camera.

The packaging transfer unit 900 is a packaging transfer member installed downstream of the assembly unit 700 to transfer finished products to be packaged, and is composed of a linear transfer facility such as a conveyor facility that linearly moves the finished products.

The input unit 100, the division unit 200, the spacing adjustment unit 300, the first coupling unit 400, the second coupling unit 500, the line transfer unit 600 and The assembled parts 700 are arranged symmetrically so as to correspond to each other in the left and right directions, but it is also possible that they are arranged in a straight line.

Therefore, the first inlet unit 100a, the first division unit 200a, the first spacing adjustment unit 300a, the 1-1 coupling unit 400a, the 2-1 coupling unit 500a, and the first line The sending unit 600a and the first assembly unit 700a are arranged in a straight line, and the second inlet unit 100b, the second division unit 200b, the second spacing unit 300b, The 1-2 coupler 400b, the 2-2 coupler 500b, the second line transfer unit 600b, and the second assembled unit 700b are arranged in a straight second line.

The frame unit 10 is a frame member installed on the floor formed on the upper surface of the base unit 1000, and as shown in FIGS. 4 and 9 to 11, the first frame 11, the second frame 12, It consists of a third frame 13 and a fourth frame 14 .

The first frame 11 is a frame installed on the floor formed on the upper surface of the base part 1000, and consists of a flat plate-shaped support frame installed horizontally on the floor formed on the upper surface of the base part 1000.

The second frame 12 is a frame installed on one end of the first frame 11, and is composed of a square frame installed vertically upward on one end of the first frame 11 and having a substantially rectangular cross section.

The third frame 13 is a frame installed on the other end of the first frame 11, and is composed of a square frame installed vertically upward on the other end of the first frame 11 and having a substantially rectangular cross section.

The fourth frame 14 is a frame installed between the upper ends of the second frame 12 and the third frame 13, and is placed between the second frame 12 and the third frame 13 in the horizontal direction. It consists of a rectangular frame with a cross section of an approximately rectangular shape.

The first transfer unit 20 is a transfer member installed on the upper portion of the frame unit 10 and slidingly moved so as to reciprocate in the left and right directions when the cutting unit 50 moves. It consists of one transfer guide 22, a first transfer piece 23 and a first transfer plate 24.

The first transfer drive piece 21 is a drive member installed at one end of the first transfer guide 22 to provide sliding driving force in the left and right directions, and includes a second transfer unit 30, a cutting drive unit 40, and a cutting unit ( 50), the first cooling unit 60, and the second cooling unit 70 can be made up of various driving means such as an electric motor, a servo motor, a linear motor, a hydraulic cylinder, etc. to slide and move in the left and right directions together. Of course.

The first transfer guide 22 is a guide member installed in the left and right longitudinal directions on the top of the frame unit 10, and includes a second transfer unit 30, a cutting drive unit 40, a cutting unit 50, and a first cooling unit ( 60) and the second cooling unit 70 are composed of various linear guides such as LM (Liner Motion) guides and ball screws to guide the reciprocating movement of sliding movement in the left and right directions together.

The first transfer piece 23 is installed to slide on the first transfer guide 22 and slides in the left and right directions, and is reciprocally sliding along the first transfer guide 22 in the left and right directions. It consists of moving blocks.

The first transfer plate 24 is a transfer member installed on one side of the first transfer piece 23 and slidably transferred together with the first transfer piece 23, and includes a second transfer unit 30 and a cutting drive unit 40. ) and the cutting unit 50 are coupled to provide reciprocating sliding movement in the left and right directions for the second transfer unit 30, the cutting drive unit 40, and the cutting unit 50.

The second transfer unit 30 is a transfer member installed on one end of the first transfer unit 20 and moved up and down in the upper and lower portions of the frame unit 10, and includes a second transfer guide 31 and a second transfer unit. It consists of a drive piece 32, a second transfer piece 33 and a second transfer plate 34.

The second transfer guide 31 is a guide member installed in the vertical direction on one side of the first transfer unit 20, and includes a cutting drive unit 40, a cutting unit 50, a first cooling unit 60, and a second cooling unit. It consists of various linear guides such as LM (Liner Motion) guides, ball screws, etc. to guide the lifting and moving of the unit 70 together in the vertical direction.

The second transfer drive piece 32 is a drive member installed at one end of the second transfer guide 31 to provide a lifting and lowering driving force in the vertical direction, and includes the cutting drive unit 40, the cutting unit 50, and the first cooling unit. Of course, it is possible to be composed of various driving means such as an electric motor, a servo motor, a linear motor, a hydraulic cylinder, etc. so as to move the 60 and the second cooling unit 70 up and down together.

The second transfer piece 33 is a transfer member that is installed on the second transfer guide 31 to move up and down in the vertical direction and moves up and down, and moves up and down along the second transfer guide 31. It consists of moving blocks that become

The second transfer plate 34 is a transfer member installed on one side of the second transfer piece 33 and moved up and down together with the second transfer piece 33, wherein the cutting drive unit 40 and the cutting unit 50 is coupled to provide sliding movement in the left and right directions and lifting movement in the up and down direction for the cutting drive unit 40 and the cutting unit 50.

The cutting drive unit 40 is one or more cutting drive members installed at one end of the lower portion of the second transfer unit 30 to provide cutting driving force of ultrasonic vibration, and provides ultrasonic vibration to the plurality of cutting units 50, respectively. It consists of an ultrasonic module such as an element.

As shown in FIGS. 5 to 7, such an ultrasonic module provides first to fourth ultrasonic vibrations to the plurality of cutting parts 50 or the first to fourth cutting pieces 51, 52, 53, and 54 thereof, respectively. Of course, it is also possible to consist of 4 ultrasound modules (41, 42, 43, 44).

The cutting unit 50 is installed below the cutting drive unit 40, and the ultrasonic vibration of the cutting drive unit 40 and the left and right reciprocating transfer of the first transfer unit 20 and the forward and backward reciprocating transfer of the input transfer unit 130 A knife-shaped cutting member that cuts a strip sheet into a plurality of strips by means of one or more carbide materials that are ultrasonically vibrated by the ultrasonic module of the cutting drive unit 40 and reciprocally transported in the left and right directions by the first transfer unit 20. It consists of a cut piece of

These cutting pieces are also composed of first to fourth cutting pieces 51, 52, 53, 54 that are respectively supplied with ultrasonic vibration from the plurality of cutting drive units 40 and reciprocally transported by the first transfer unit 20. Of course it is possible.

In addition, the first to fourth cutting pieces 51, 52, 53, and 54 include first to fourth cutting sockets 51a, 52a, 53a, and 54a coupled to the lower portion of the cutting drive unit 40, respectively. Of course, it is also possible that the first to fourth cutters 51b, 52b, 53b, and 54b are detachably installed below the first to fourth cutting sockets 51a, 52a, 53a, and 54a.

The first cooling unit 60 is a cooling member installed on one side of the cutting drive unit 40 to cool the cutting drive unit 40, and it is possible to consist of a cooling fan that blows air to the cutting drive unit 40.

As such a cooling fan, the first to fourth blowing fans 61, 62, and 63 blow air to and cool the plurality of cutting drive units 40 or their first to fourth ultrasonic modules 41, 42, 43, 44, respectively. , 64), of course.

The second cooling unit 70 is a cooling member installed on one side of the cutting unit 50 to cool the cutting unit 50, and as shown in FIGS. 6 and 8, the support block 71 and the rotation bracket 72 ), a cooling pipe 73 and a cooling hole 74.

The support block 71 is a support block member installed at both ends of the lower portion of the second transfer unit 30, is installed downward at both ends of the lower portion of the second transfer plate 34, and rotates the rotation bracket 72 in the rotation slot groove. It is coupled and supported so as to adjust the inclination angle of the rotation bracket 72.

The rotation bracket 72 is a bracket member installed to adjust the inclination angle of the support block 71, and is rotatably coupled and supported to the rotation slot groove formed at the lower end of the support block 71 to adjust the inclination angle of the rotation bracket 72. will do

The cooling pipe 73 is a piping member installed to communicate in the longitudinal direction between the rotating brackets 72 and to which air is supplied, and one or both ends of the cooling pipe 73, such as a header, which is a pipe branch facility, has an air supply facility and A communicating hole is formed, and an air hose is connected thereto to supply and diverge high-pressure air such as compressed air.

A plurality of cooling holes 74 are spaced apart in the longitudinal direction of the cooling pipe 73, and air is blown to each cutter of the cutting part 50 made of a plurality of cutters to cool them or remove foreign substances. It consists of a plurality of inclined holes or inclined nozzles obliquely penetrated corresponding to the plurality of cutters so as to correspond to each other.

The dust removal unit 80 is a dust removal member installed on the other side of the cutting unit 50 and communicated with a suction device such as a suction pump or vacuum pump to suction and remove dust generated during cutting of the cutting unit 50. , It is formed with a plurality of suction holes or suction nozzles to suck in dust corresponding to each cutter of the cutting part 50 made of a plurality of cutters.

As described above, according to the present invention, by providing a transfer unit in the vertical and horizontal directions and a cutting drive unit for providing ultrasonic vibration to the cutting unit, the strip sheet is cut into a plurality of strips by ultrasonic vibration to improve the cutting performance of the cutting unit. At the same time, it provides the effect of extending the life of the cutting part and easily handling maintenance.

In addition, the cutting drive unit and the cutting unit are provided with a cooling fan or a cooling unit for each cutting unit, thereby lowering the cutting temperature when cutting the strip between the cutting drive unit and the cutting unit, thereby prolonging the cutter replacement cycle and preventing damage to the cutter during cutting. Provides an effect capable of reducing defects.

In addition, by providing a branch removal unit at the lower part of the cutting unit, dust generated during cutting is reduced, and malfunction due to attachment of dust or foreign substances to the sensor or operating equipment of the cutting unit is reduced, thereby providing an effect of preventing defective cutting.

In addition, by applying ultrasonic waves to the cutting part and facilitating attachment and detachment of the cutter, the maintenance cost of the cutter part is reduced, and at the same time, the cutter is replaced in the cutter socket without separate alignment work, improving the cutter replacement workability and replacement It provides an effect that can shorten the time.

In addition, by providing a vertical transfer unit and a left and right transfer unit in the upper frame portion of the cutter unit, the accessibility, workability, and intimacy of repair personnel can be improved when repairing a breakdown of the cutter unit.

The present invention described above can be implemented in various other forms without departing from its technical spirit or main characteristics. Therefore, the above embodiments are mere examples in all respects and should not be construed in a limited manner.

10: frame part 20: first transfer part
30: second transfer unit 40: cutting drive unit
50: cutting unit 60: first cooling unit
70: second cooling unit 80: dust removal unit

Claims (11)

As a strip cutting device of the assembly facility of the rapid diagnosis device for cutting the strip sheet of the assembly facility of the rapid diagnosis device into a plurality of strips,
A frame unit 10 standing on the floor;
a first transfer unit 20 installed on the upper portion of the frame unit 10 and sliding in the left and right directions;
A second transfer unit 30 installed on the upper portion of the frame unit 10 and installed at one end of the first transfer unit 20 to move up and down in the vertical direction;
One or more cutting drive units 40 installed at one end of the lower portion of the second transfer unit 30 to provide a cutting driving force of ultrasonic vibration;
A strip cutting device of an assembly facility for a rapid diagnostic device comprising a; cutting unit 50 installed under the cutting drive unit 40 to cut the strip by ultrasonic vibration. According to claim 1,
The strip cutting device of the assembly facility of the rapid diagnostic machine, characterized in that it further comprises; a first cooling unit (60) installed on one side of the cutting drive unit (40) to cool the cutting drive unit (40). According to claim 2,
The first cooling unit (60) is composed of a cooling fan that blows air to the cutting drive unit (40). According to claim 1,
The strip cutting device of the assembly equipment of the rapid diagnostic device, characterized in that it further comprises; a second cooling unit (70) installed on one side of the cutting unit (50) to cool the cutting unit (50). According to claim 4,
The second cooling unit 70,
Support blocks installed at both ends of the lower portion of the second transfer unit 30;
a rotation bracket installed to adjust the inclination angle of the support block;
a cooling pipe installed to communicate between the rotating brackets in a longitudinal direction and supplying air; and
A strip cutting device of an assembly facility for a rapid diagnostic device comprising a plurality of cooling holes spaced apart in the longitudinal direction of the cooling pipe. According to claim 1,
A dust removal unit 80 installed on the other side of the cutting unit 50 to suck in and remove dust generated during cutting of the cutting unit 50; strip cutting device. According to claim 1,
The frame part 10,
A first frame installed on the floor;
a second frame placed on one end of the first frame;
a third frame placed on the other end of the first frame; and
A strip cutting device of an assembly facility for a rapid diagnostic device comprising a; fourth frame installed between upper ends of the second frame and the third frame. According to claim 1,
The first transfer part 20,
First transfer guides installed in the left and right longitudinal directions on the top of the frame unit 10;
a first transfer drive piece installed at one end of the first transfer guide and providing sliding driving force in the left and right directions; and
A strip cutting device of an assembly facility for a rapid diagnostic device comprising a first conveying piece installed on the first conveying guide and sliding in the left and right directions. According to claim 1,
The second transfer part 30,
a second transfer guide installed in the vertical direction on one side of the first transfer unit 20;
a second transfer drive piece installed at one end of the second transfer guide and providing a lift driving force in the vertical direction; and
A strip cutting device of an assembly facility for a rapid diagnostic device comprising a second conveying piece installed on the second conveying guide and moving up and down in the vertical direction. According to claim 1,
The cutting drive unit (40) is a strip cutting device of an assembly facility for a rapid diagnostic device, characterized in that consisting of an ultrasonic module that provides ultrasonic vibration to the cutting unit (50). According to claim 1,
The cutting part 50,
a cutter socket coupled to the lower portion of the cutting drive unit 40; and
A strip cutting device of an assembly facility for a rapid diagnostic device comprising a; cutter installed to be detachably attached to the lower part of the cutter socket.

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