KR20040016007A - Automatic packing apparatus for sensor strip can - Google Patents

Abstract

PURPOSE: An automatic assembling and packing device of a sensor strip can is provided to automatically perform a serial process for supplying, assembling, and packing a particulate dehumidifying agent, a paper filter, a filter fixing ring, a sensor strip, and a container sealing cap in a cylindrical container. CONSTITUTION: An automatic assembling and packing device of a sensor strip can(10) includes plural protruded lines at the inside, penetrates a dehumidifying agent into containers(12) having an annular projection formed at a regular interval at the upper part of the protruded line, inserts paper filters(20) and rings(22) for fixing the paper filter, penetrates the sensor strip needing to be dehumidified, and automatically packs and assembles the can closed by caps(24). In addition, the automatic assembling and packing device is composed of a container feeding unit(28) for successively feeding containers to a turn table(26) including a plurality of container grooves(44) at the periphery; a unit for feeding the fixed quantity of a dehumidifying agent(30) to supply the fixed quantity of the dehumidifying agent to the container during a process for supplying the container to the turn table; a ring feeding unit(34) for feeding rings to the container; a sensor strip feeding unit(36); a cap feeding unit(38) for feeding caps to be sealed; and a can discharging unit(40) for discharging the completed can formed by completely combining the cap to the container.

Description

AUTOMATIC PACKING APPARATUS FOR SENSOR STRIP CAN}

The present invention relates to an automatic assembly and packaging device for a sensor strip can, and in particular, a filter made of paper, which allows the passage of moisture while limiting the storage space of the dehumidifying agent in the cylindrical container and the dehumidifying agent in the container. In the automatic assembly and packaging device of the sensor strip cans, which can be automatically assembled and packaged with a product such as a ring for fixing, a sensor strip housed in the container, and a cap that is finally attached to the container. It is about.

In general, the sensor strip used in the digital blood glucose meter is sensitive to moisture, and therefore, it is required to be kept closed in a dehumidifying environment.

Conventionally, in order to package such a sensor strip in a can, a dedicated container thereof, a ring for quantitatively injecting a dehumidifying agent such as silica gel into a container, inserting a paper filter on the dehumidifying agent, and then fixing it in the container on the paper filter Insert the product into the product, such as a sensor strip that requires airtight packaging, and seal it with a cap. However, there is a drawback that the conventional work is not automated and is made almost manually so that productivity is lowered.

In the present invention, invented in view of such a point, a series of processes in which a granular dehumidifier, a paper filter, a filter fixing ring, a sensor strip, and a container sealing cap are supplied, assembled and packaged in a cylindrical container automatically. It is an object of the present invention to provide an automatic assembly and packaging device for a sensor strip can.

Another object of the present invention is to increase productivity by allowing a series of automated processes to be performed continuously.

1 is an exploded perspective view of a sensor strip can and assembled according to the present invention.

Figure 2 is a cross-sectional view of the sensor strip cans assembled and assembled according to the present invention.

3 is an explanatory view showing an assembly and packaging step of the sensor strip can.

4 is an overall schematic plan view of the apparatus of the present invention.

5 is a partial perspective view showing the filter loading system.

6 is a partial perspective view showing a ring loading system.

7 is a partial perspective view of the cap loading system.

Figure 8 is a cross-sectional view showing a cross section of the gasket adsorption plate of the filter loading system.

Figure 9 is a cross-sectional view showing a cross section of the gasket adsorption plate of the ring loading system.

10 to 12 are partial side cross-sectional views showing an operating state of the filter loading system.

13 is a partial side cross-sectional view of the ring loading system.

14 is a partial side cross-sectional view of the cap loading system.

Figure 15 shows the filter and ring for securing them in the can after the filters and rings have been loaded.

Partial side cross-sectional view showing a pressing structure for pressing a ring.

16 shows that the cap is pressed to secure it to the can after it is loaded.

Partial side view showing the pressure structure.

FIG. 17 is a partial cross-sectional view showing an ejector for ejecting a prepackaged can from the device. FIG.

18 is a partial plan view of the same;

Explanation of Signs of Major Parts of Drawings

10 cans 12 containers

18 Dehumidifier 20 Paper filter

22 ... Ring 24 ... Cap

26 ... turntable 28 ... container feeder

30. Dehumidifier supply stage 32 ... Filter supply stage

34 ... Ring supply end 36 ... Sensor strip supply end

38.Cap supply end 40 ... Cap discharge end

To this end, in the present invention, a sensor strip in which several protrusions are formed therein and a dehumidifying agent is introduced into a container having an annular protrusion at a predetermined distance thereon, a paper filter and a ring for fixing the same are inserted, and a dehumidification is required. Provides a device for automatically packaging and assembling the can sealed by cap after injecting. The apparatus of the present invention is a container supply stage for sequentially supplying a container to a turntable formed with a plurality of container grooves on the periphery, a dehumidifying quantitative supply stage for supplying a dehumidifying agent to the container in the process of supplying the container to the turntable, the transfer of the container A filter supply stage for supplying a paper filter to a vessel disposed downstream from the direction, a ring supply stage for supplying a ring to the vessel, a paper filter and a ring supplied to the vessel, to insert the paper filter and ring between the protrusion and the annular projection of the vessel. A ring press device for pressurizing the filter and the ring, a cap supply end arranged at a downstream side of the sensor strip supply end and a sensor strip supply end to supply a cap to be sealed to the container, and a downstream side of the cap supply end Cap pressurizing device for pressurizing the cap so that the cap is completely inserted into the upper part of the container, and the can discharge end for discharging the completed can by the cap is fully coupled to the container The.

Referring to the present invention in more detail based on the accompanying drawings as follows.

1 and 2 show the components of a sensor strip can 10 assembled and packaged by the device of the invention. The can 10 is made of a disposable plastic material, and is formed of a cylindrical container 12 having a closed bottom and an open top. In the interior of the container 12, several protrusions 14 extending in the axial direction of the container 12 are formed on the inner wall of the lower part, and the upper end of the protrusions 14 is loaded with a paper filter described later. Form the jaw. The annular protrusion 16 is formed in the upper side of the protrusion line 14 formed in the inner wall of the container 12 at a predetermined distance from these upper ends. In the container 12, particulate dehumidifier 18, such as silica gel, is infiltrated in the amount up to the height of the projection line 14. Thereafter, the paper filter 20 is inserted into the container 12, and then a ring 22 for fixing the paper filter 20 is inserted. The periphery of the paper filter 20 and the ring 22 is inserted between the upper end of the protruding line 14 and the annular protrusion 16 in the container 12 so that the ring 22 fixes the paper filter 20. So that the dehumidifying agent 18 contained in the container 12 at the lower side of the paper filter 20 can be accommodated in the limited space while absorbing moisture in the other space of the container 12 through the paper filter 20. do. Finally, the cap 24 is coupled to the container 12. Of course, products which require dehumidification in a conventional manner before the cap 24 is engaged, for example products such as sensor strips, are stored in the upper space of the paper filter 20 in the container 12.

3 shows that the dehumidifying agent 18 is limited by supplying the dehumidifying agent 18, the paper filter 20, the ring 22, and the cap 24 to the container 12 to fix the paper filter 20 and the ring 22. It shows a series of processes that are accommodated in the space and the cap 24 is sealed. Here, the sensor strip is supplied in a step before the cap 24 is coupled and received in the upper space of the paper filter 20. Steps (a-f) of Figure 3 take place automatically in accordance with the present invention.

4 shows an overall schematic plan view of the device of the present invention. This is presented to describe the apparatus of the present invention divided into functional aspects.

In Fig. 4, the apparatus of the present invention is provided with a container supply stage 28 and a dehumidifying agent 18 for supplying the container 12, starting from the clockwise 9 o'clock direction around the circular turntable 26. A dehumidifying determinant supply stage 30 for supplying a fixed amount is disposed. And the filter supply stage 32 for supplying the paper filter 20 sequentially in the clockwise direction, the ring supply end 34 for supplying the ring 22, the sensor strip supply end 36 for supplying the sensor strip, cap ( A cap supply end 38 for supplying 24 and a can discharge end 40 for discharging the assembled can 10 are disposed.

Turntable (26)

The turntable 26 has a structure that is rotatably disposed on the support 42, a plurality of container grooves 44 to be supplied in a state in which the container 12 is standing on the periphery to be moved to each functional end Formed. And, the container guide for preventing the container 12 from being separated from the container groove 44 on the peripheral side of the turntable 26 from the position past the container supply end 28 to just before the can discharge end 40 ( 46 is mounted on the support 42. Such turntable 26 is a conventional form and will be readily understood by those skilled in the art.

Container Supply Stage (28)

The container supply stage 28 supplies a plurality of containers 12 in a disordered manner so that they can be sequentially supplied in a state in which the open top is aligned upward by using vibration and a suitable ramp. ) And a container supply path 50 extending therefrom to the turntable 26. Such a container sorter 48 and its surroundings are well known in the art and will not be described in further detail. The tip of the container supply passage 50 sequentially supplies the container 12 to the container groove 44 of the turntable 26 which is located correspondingly. The container 12 supplied to the container groove 44 is transferred to the next stage according to the clockwise rotation of the turntable 26.

Dehumidification Determination Supply Stage (30)

The dehumidifying quantitative supply stage 30 is disposed in the middle of the vessel supply passage 50 extending from the vessel alignment supply 48 to the turntable 26 side. The dehumidifier quantitative supply stage 30 has a structure for supplying a predetermined amount of the dehumidifying agent 18 to the container 12 through the dehumidifying agent supply port 52, and the dehumidifying agent 18 is, for example, supplied to a fixed quantity supply device using an air cylinder. Can be supplied in a fixed quantity. This dehumidifying quantitative supply stage 30 is also well known in the art.

Filter Supply Stage (32)

The filter feed stage 32 is described in detail in FIG. 5 in conjunction with FIG. 4. The filter feed stage 32 consists of a known filter sort feeder 54 having an operation function similar to the vessel sort feeder 48. An inverse " Y " shaped filter supply passage 56 extends from the filter alignment supply 54. As shown in FIG. This filter feed passage 56 is divided into two feed passages 58 and 58 'adjacent to the turntable 26. Through this, the paper filter 20 can be supplied to each of the two containers 12 which are supplied to the container grooves 44 of the turntable 26 corresponding thereto.

In FIG. 5, a filter loading system 60 is disposed adjacent to and adjacent to the filter supply path 56. In FIG. This filter loading system 60 is constructed on the basis of a horizontal frame 62 whose position is fixed to a frame (not shown) of the device. The vertical fixing plate 64 is installed at the tip of the horizontal frame 62 and the air cylinder 68 in which the piston 66 extends forward is installed horizontally, and the guide rods 70 are provided on both sides of the air cylinder 68. 70 'is operatively extended. The piston 66 of this air cylinder 68 operates in the X-axis direction.

At the tip of the piston 66 and the guide rods 70 and 70 'of the air cylinder 68, an "L" shaped movable frame 76 composed of a vertical portion 72 and a horizontal portion 74 is vertical. It is coupled via the part 72. An air cylinder 78 is mounted vertically on the horizontal portion 74 of the movable frame 76, and the piston 80 extends downward of the horizontal portion 74 together with the guide rods 82, 82 ′ on both sides. It is. Extension plates 84 are installed at the ends of the piston 80 and the two guide rods 82 and 82 'of the air cylinder 78, and the two supply ports 58 and 58' of the filter supply passage 56 are installed. A suction port 88, 88 'having a suction plate 86, 86' at the lower end is installed in a portion placed above the end. By the operation of the air cylinder 78, the suction holes 88 and 88 'of the extension plate 84 operate in the Y-axis direction.

The detailed structure of the suction holes 88 and 88 'is described in FIG. In FIG. 8, the suction hole 88 is fixed to the extension plate 84, and an elastic suction plate 86 is disposed at a lower end thereof, and a vacuum supply path 90 is provided from the suction hole 88 to the suction plate 86. Is formed and is connected to an external vacuum source (not shown).

Ring Supply Stage (34)

The ring feed end 34 is described in detail in FIG. 6 in conjunction with FIG. 4. The ring feed stage 34 is composed of a ring alignment feeder 92 similar to the filter alignment feeder 54. Inverse "Y" shaped ring supply path 94 extends from the ring alignment supply 92. This ring supply path 94 is divided into two supply paths 96 and 96 'adjacent to the turntable 26. Through this, the container 22 is transferred to the container 12 inserted into the container groove 44 of the turntable 26 corresponding thereto, and the two containers of the paper filter 12 supplied from the filter supply end 32 ( 12, the ring 22 for fixing the paper filter 12 to each can be supplied.

In FIG. 6, a ring loading system 98 is disposed above and adjacent to the ring supply path 94. As shown in FIG. Since the ring loading system 98 is basically the same as the filter supply stage 32, the suffix “a” is indicated in the drawings for each corresponding element, and a detailed description of the structure is omitted.

However, in the structure of the adsorption holes 88a and 88a ', as shown in FIG. 9, the end of the vacuum supply passage 90a is the adsorption plate 86a and 86a' because the ring 22 must be adsorbed and transported. Only those distributed on the main edge side of are different.

The paper filter 20 and the ring which are supplied in a natural dropping manner under the action of gravity inside the container 12 on the downstream side in the advancing direction of the container 12 adjacent to the ring loading system 98 as described in detail later. (22) is elastically coupled between the upper end of the projection line 14 formed on the inner wall of the container 12 and the annular projection (16) to the container 12 to secure the paper filter 20 with the ring 22 A ring pressing device 100 is arranged to press the supplied paper filter 20 and the ring 22 to be inserted between the upper end of the protruding line 14 and the annular projection 16. The ring pressing device 100 is a pressing plate that can be installed in the air cylinder 104, 104 'perpendicular to the fixed frame 102 and press the ring 22 to the lower end of the piston 106, 106' A structure in which the 108 and 108 'are mounted and the positions of the pressure plates 108 and 108' coincide with the positions immediately above the vessel 12 that are conveyed to the vessel groove 44 of the turntable 26.

Sensor Strip Supply Stages (36)

This sensor strip supply end 36 is disposed downstream of the ring loading system 98 in the direction of travel of the vessel 12. This is for supplying a sensor strip (not shown) on the paper filter 20, which is supplied to the container 12 and fixed to the ring 22, to the sensor strip feeder 110 and therefrom to the container 12. It consists of a sensor strip supply port 112 for supplying the sensor strip, which may be a well known structure that can be easily configured by those skilled in the art.

Cap feed stage (38)

It is disposed downstream of the sensor strip supply end 36 in the advancing direction of the container 12. The cap feed end 38 is described in detail in FIG. 7 in conjunction with FIG. 4. The cap feed stage 38 consists of a cap alignment feeder 114 similar to the filter alignment feeder 54. Inverse "Y" shaped cap feed passage 116 extends from the ring alignment feeder 114. This cap feed passage 116 is divided into two feed passages 118 and 118 'adjacent to the turntable 26. Through this, the cap 24 is supplied to the container groove 44 side of the turntable 26 corresponding thereto, and the cap 24 for sealing it to the two containers 12 to which the sensor strip is supplied at the sensor strip supply end 36 is respectively provided. Make it available.

In FIG. 7, a cap loading system 120 is disposed above and adjacent to the cap supply path 116. Since the cap loading system 120 is basically the same as the filter supply stage 32, the suffix “b” is indicated in the drawings for each element corresponding thereto, and a detailed description thereof will be omitted.

On the other hand, in the advancing direction of the container 12 adjacent to the cap loading system 120, the cap 24 supplied in a natural dropping manner under the action of gravity to the upper portion of the container 12, as will be described later in detail. The cap pressurizing device 122 is arranged to pressurize and be completely coupled to the upper portion of the container 12. This cap presser 122 is of the same structure as the ring presser 100 mentioned above. Therefore, the components of the cap pressurizing device 122 are denoted by the suffix "s" in the symbols representing the components of the ring pressurizing device 100 and will not be described in detail.

Can discharge stage (40)

It is arranged downstream from the advancing direction of the container 12 adjacent to the cap feed end 38 and is the final functional end of the device of the present invention. It consists of a can discharge path 124 whose tip is arranged to correspond to one of the container grooves 44 of the turntable 26, and this can discharge path 124 extends toward the can collecting container 126 side. In front of the tip side of the can discharge path 124, a plate-shaped ejector 128 for discharging the can 10 having completed assembly packaging from the container groove 44 of the turntable 26 to the can discharge path 124 is disposed. do. One side of the ejector 128 is installed on the rotating shaft 132 mounted on the bracket 130 extending from the outer frame (not shown) of the apparatus so as not to affect the rotation operation of the turntable 26. Power is transmitted from the outside to the 132 to intermittently and partially rotate the ejector 128 to discharge the can 10 from the container groove 44 of the turntable 26 toward the can discharge path 124 ( 17 and 18). Ejector 128 may be coupled to a counter (not shown) that can count the number of cans 10 in which the assembled packaging is completed.

This operation of the present invention is as follows.

As mentioned at the outset describing the construction of the present invention, the sensor strip can 10 assembled and packaged by the apparatus of the present invention comprises a cylindrical container 12 with a closed bottom and an open top. 12, several protrusions 14 extending in the axial direction of the container 12 are formed on the inner wall of the lower portion, and the upper end of the protrusions 14 forms a jaw on which the paper filter 20 is placed. The annular projection 16 is formed at a predetermined distance above the protruding line 14 formed on the inner wall of the container 12. In the container 12, a particulate dehumidifying agent 18 such as silica gel is introduced up to the height of the projection line 14, and then a paper filter 20 and a ring 22 for fixing it are inserted. The paper filter 20 and the periphery of the ring 22 are inserted between the upper end of the protruding line 14 and the annular projection 16 so that the paper filter 20 in the state in which the ring 22 fixes the paper filter 20. The dehumidifier 18 contained in the container 12 at the lower side of the) is accommodated in the limited space. The sensor strip requiring dehumidification is stored in the upper space of the paper filter 20 in the container 12 and finally the cap 24 is coupled.

In the container feeding step, the disordered supply of the plurality of containers 12 from the container sorting feeder 48 of the container feeding end 28 is made to align with the opened upper part upward by using vibration and a suitable ramp. In the state, the container 12 is sequentially supplied to the container supply path 50, and is then supplied to the turntable 26. The tip of the container supply passage 50 sequentially supplies the container 12 to the container groove 44 of the turntable 26 which is located correspondingly. The container 12 supplied to the container groove 44 of the turntable 26 is transferred to the next stage according to the clockwise rotation of the turntable 26.

Before the container 12 is supplied to the container groove 44 of the turntable 26, the dehumidifying agent 18 is quantitatively supplied to the container 12 in the container supply path 50 by the dehumidifying quantitative supply stage 30.

The container 12 which is supplied with the dehumidifying agent 18 and quantitatively supplied by the container groove 44 of the turntable 26 reaches the filter supply end 32, where the paper filter 20 is supplied to the container 12. .

In the filter supply stage 32, the paper filter 20 is supplied to two feed ports 58, 58 ′ through an inverted " Y " shaped filter supply path 56 extending from the filter alignment feeder 54. . The filter loading system 60 disposed adjacent to the filter supply passage 56 has a movable frame 76 connected thereto by the operation of the air cylinder 68 disposed horizontally on the horizontal frame 62 so that the piston 66 retreats. The vertically arranged air cylinder 78 and the extension plate 84 coupled to the piston 80 of the air cylinder 78 are retracted together and the suction holes 88 and 88 'installed on the extension plate 84. The suction plates 86 and 86 'of the < RTI ID = 0.0 >) are retracted and placed on the paper filter 20 located at the tip of the feed passages 58, 58' (FIG. 10). At this time, when the vertically arranged air cylinder 78 of the movable frame 76 is operated and the piston 80 is extended, the adsorption plate 86 of the adsorption ports 88 and 88 'installed on the extension plate 84 ( 86 'contacts the paper filter 20 positioned at the tip of the feeders 58 and 58' and vacuum sucks them (FIG. 11).

Thereafter, the adsorption plates 86 and 86 ′ on which the paper filter 20 is adsorbed are raised by the operation of the vertically arranged air cylinder 78 of the movable frame 76 and at the same time the air cylinder 68 of the horizontal frame 62. The paper filter 20 is supplied to the container groove 44 of the turntable 26 to reach the upper portion of the container 12 transferred (FIG. 12). Then, the vacuum action is released from the suction plates 86 and 86 'so that the paper filter 20 is supplied into the container 12. At this time, the paper filter 12 is placed on the annular projection (16) in the container.

Next, the container 12 to which the paper filter 20 is supplied is transferred to the next ring supply end 34 by the continuous rotation of the turntable 26.

In the ring supply stage 34, the ring 20 is supplied to two feed stations 96 and 96 ′ through an inverted " Y " ring supply path 94 extending from the ring alignment feeder 92. The ring loading system 98 disposed adjacent to the ring supply path 94 has a movable frame 76a connected to the horizontal cylinder 62a by actuating the air cylinder 68a arranged horizontally so that the piston 66a retreats. ), The vertically arranged air cylinder 78a and the extension plate 84a coupled to the piston 80a of the air cylinder 78a are retracted together and the suction holes 88a and 88a 'installed on the extension plate 84a. The suction plates 86a and 86a 'of the () are retracted and placed on the ring 22 located at the tip of the feeder 96 (96') (FIG. 13). At this time, when the vertically arranged air cylinder 78a of the movable frame 76a is operated and the piston 80a is extended, the adsorption plate 86a of the adsorption holes 88a and 88a 'installed on the extension plate 84a ( 86a ') contacts the ring 22 positioned at the tip of the feeder 96 and 96' to vacuum suction them. Thereafter, the adsorption plates 86a and 86a 'on which the ring 22 is adsorbed are raised by the operation of the vertically arranged air cylinder 78a of the movable frame 76a, and at the same time, the air cylinder 68a of the horizontal frame 62a is In operation, the ring 22 is supplied to the container groove 44 side of the turntable 26 to reach the upper portion of the container 12 transferred. Then, the vacuum action is released from the suction plates 86a and 86a 'so that the ring 22 is supplied into the vessel 12. At this time, the ring 22 is placed on the paper filter 20 in the container.

Subsequently, the container 12 supplied with the paper filter 20 and the ring 22 reaches the position of the ring pressing device 100 disposed adjacent to the ring supply end 34 by the continuous rotation of the turntable 26.

Here, the paper filter 20 and the ring 22 are elastically coupled between the upper end of the protruding line 14 formed on the inner wall of the container 12 and the annular protrusion 16, and the paper filter 20 as the ring 22. In order to fix the pressure, the paper filter 20 and the ring 22 supplied to the container 12 are pressed to be inserted between the upper end of the protruding line 14 and the annular protrusion 16. The air cylinders 104 and 104 'of the ring pressing device 100 provided for this operation are operated so that the pressure plates 108 and 108' of the pistons 106 and 106 'are provided with the paper filter 20 and the ring 22. Pressurized to be inserted between the upper end of the projection line 14 and the annular projection (16).

The paper filter 20 and the ring 22 are pressed and the container 12 inserted between the upper end of the protruding line 14 and the annular projection 16 is then continued by the turntable 26 to the next sensor strip supply stage ( 36).

Here, the sensor strip is fed from the sensor strip feeder 110 via the sensor strip feed port 112 onto the paper filter 20 of the container 12.

The container fed with the sensor strip is again conveyed by the turntable 26 to the next sensor cap feed end 38.

In this cap feed stage 38 the cap 24 is fed to the container in a manner similar to the feeding of the paper filter 20 or ring 22 mentioned above.

In the cap supply stage 38, the cap 24 is supplied to two feed passages 118 and 118 ′ through the inverted “Y” shaped cap supply passage 116 extending from the cap alignment feeder 114. The cap loading system 120 disposed adjacent to the cap supply path 116 has a movable frame 76b connected thereto by operating the air cylinder 68b horizontally disposed on the horizontal frame 62b so that the piston 66b retreats. ), The vertically arranged air cylinder 78b and the extension plate 84b coupled to the piston 80b of the air cylinder 78b are retracted together and the suction holes 88b and 88b 'installed on the extension plate 84b. The suction plates 86b and 86b 'of the s) are retracted and placed on the cap 24 positioned at the tip of the feeder 118 and 118' (FIG. 14). At this time, when the vertically arranged air cylinder 78b of the movable frame 74b is operated to extend the piston 80b, the adsorption plate 86b of the adsorption holes 88b and 88b 'installed on the extension plate 84b ( 86b ') comes in contact with the cap 24 positioned at the tip of the feeder 118 and 118' and vacuum sucks them. Thereafter, the suction plates 86b and 86b 'to which the cap 24 is adsorbed are raised by the operation of the vertically arranged air cylinder 78b of the movable frame 74b, and at the same time, the air cylinder 68b of the horizontal frame 62b is In operation, the cap 24 is supplied to the container groove 44 side of the turntable 26 to reach the upper portion of the container 12 transferred. Then, the vacuum action is released from the suction plates 86b and 86b ', and the cap 24 is supplied to be placed on the upper portion of the vessel 12.

In this way, the container 12 with the cap 24 placed thereon is continuously transferred to the next cap presser 122 side by the turntable 26.

Here, the cap 24 is completely inserted into the upper portion of the container 12 so that the container 12 can be sealed. For this purpose, the air cylinders 104s and 104s' of the can pressurizing device 122 are operated so that the pressure plates 108s and 108s' of the pistons 106s and 106s' pressurize the cap 24 so that the cap ( 24 is inserted completely on top of the container 12 so that the container 12 can be hermetically packed.

The container 12, ie the final product can 10, in which the cap 24 is hermetically coupled, is then transferred to the next can discharge end 40 by the turntable 26.

At the can discharge end 40, the ejector 128 rotates intermittently and partially on the rotating shaft 132 to discharge the can 10 from the container groove 44 of the turntable 26 toward the can discharge path 124. . The can 10 is discharged to the can collecting container 126 through the can discharge path 124 in which the tip thereof is arranged to correspond to one of the container grooves 44 of the turntable 26.

As such, the present invention provides a sensor strip can in which a cylindrical dehumidifier, a paper filter, a filter retaining ring, a sensor strip, and a container sealing cap are supplied and assembled and packaged automatically. Provides automatic assembly packaging device.

Claims (7)

A ring for injecting the dehumidifying agent 18 into the container 12 in which several protrusions 14 are formed therein and the annular protrusion 16 is formed at a predetermined distance thereon and the paper filter 20 is fixed thereto ( 22) A device for inserting and inserting a sensor strip requiring dehumidification and then automatically packaging and assembling a can 10 sealed with a cap 24, in which a plurality of container grooves 44 are formed at a periphery thereof. A container supply stage 28 for sequentially supplying the container 12 to the turntable 26, and for supplying a dehumidifying agent 18 to the container 12 in a process in which the container 12 is supplied to the turntable 26. To the filter supply stage 32 and the container 12 for supplying the paper filter 20 to the container 12 sequentially disposed downstream from the dehumidifying quantity supply stage 30 and the container 12 in the transport direction. Ring supply end 34 for supplying the ring 22, the paper filter 20 and the ring 22 supplied to the container 12, the projection line 14 and the annular projection 16 of the container 12 Cap feed end for supplying the paper filter 20 and the ring pressing device 100 for pressing the ring 22, the sensor strip supply end 36, the cap 24 to be sealed to the container 12 for insertion into the container ( 38), the cap pressurizing device 122 for pressing the cap 24 so that the cap 24 supplied to the container 12 is completely inserted into the upper part of the container 12, and the cap 24 is connected to the container 12. Automatic assembly and packaging device of the sensor strip can, characterized in that consisting of the can discharge end 40 for discharging the can 10 is completed and fully combined. 2. The filter supply passage according to claim 1, wherein the filter supply stage 32 includes a filter alignment feeder 54 for aligning and supplying the paper filter 20 to the filter supply passage 56 using vibration and a suitable ramp. Automatic assembly of the sensor strip can, characterized in that it comprises a filter loading system 60 for vacuum suctioning the paper filter 20 supplied to the 56 to supply to the container 12 conveyed by the turntable 26 Packing device. 3. The filter loading system (60) according to claim 2, wherein the filter loading system (60) has suction plates (86, 86 ') for vacuum suction of the paper filter (20), and the suction plates (86) (86') are horizontally arranged air cylinders ( 68) and an automatic assembly and packaging device for the sensor strip can, characterized in that the installation is installed on the extension plate 84 that moves in the horizontal and vertical direction by the vertically arranged air cylinder (78). The ring supply end (34) according to claim 1, wherein the ring supply end (34) comprises a ring alignment supply (92) for aligning the ring (22) and supplying it to the ring supply path (94) using vibration and a suitable ramp. 94. A device for automatically assembling and packaging a sensor strip can, comprising: a ring loading system 98 for vacuum suctioning the ring 22 supplied to 94 and feeding it to the container 12 conveyed by the turntable 26. . 5. The ring loading system (98) according to claim 4, wherein the ring loading system (98) has suction plates (86a) (86a ') for vacuum suction of the rings (22), and the suction plates (86a) (86a') are horizontally arranged air cylinders (68a). And an extension plate 84a moving horizontally and vertically by a vertically arranged air cylinder 78a. 2. The cap supply end (38) according to claim 1, wherein the cap supply end (38) includes a cap alignment supply (114) for aligning the cap (24) using the vibration and a suitable ramp to supply the cap supply path (116). Automatic assembly and packaging device for a sensor strip can, characterized in that it comprises a cap loading system 120 for vacuum sucking the cap 24 supplied to the 116 to the container 12 conveyed by the turntable 26 . 7. The caploading system (120) according to claim 6, wherein the cap loading system (120) has suction plates (86b) (86b ') for vacuum suction of the cap (24), and the suction plates (86b) (86b') are horizontally arranged air cylinders (68b). And an extension plate (84b) moving horizontally and vertically by a vertically arranged air cylinder (78b).