JP5232522B2 - Seal inspection device and seal inspection method - Google Patents

Description

  The present invention relates to a seal inspection device and a seal inspection method for inspecting whether or not a box is sealed.

For example, a packaging box for storing an article to be packaged such as a pharmaceutical product closes the opening of the box with a lid after the article to be packaged is stored in the box. Apply a melt-type adhesive and adhere this insertion flap to the inner surface of the opening of the box, or attach a sealing label between the lid and the box to seal the box. Yes.
For this reason, it is necessary to inspect whether or not the box is reliably sealed after the article to be packaged is stored.

Therefore, conventionally, as a seal inspection device for performing a seal inspection of a box, an adsorber that is adsorbed to the sealed portion of the box, an inspection arm that holds the adsorber, a rotating shaft that is coupled to the inspection arm, and A drive device that rotates the drive shaft and a torque sensor that detects the torque generated in the drive device. After the suction tool is adsorbed to the sealed portion of the box, the inspection arm is moved backward from the box by driving the drive device. Thus, when the inspection arm is at a predetermined angular position, a torque value generated in the drive device is detected, and if this torque value does not exceed the predetermined value, it is determined that the sealing is defective. (See Patent Document 1).
However, in the above conventional sealing inspection apparatus, it is necessary to temporarily stop the box transported by the transport apparatus when inspecting the seal, so it takes time for the sealing inspection of the box, and therefore, a large number of boxes can be sealed quickly. There was a problem that it was difficult to inspect.

Further, for example, a transport device that transports the box, a suction body moving device that moves following the transport of the box by the transport device, and a plurality of suction bodies mounted on the suction body moving device are transported. There has also been proposed a sealing inspection device in which a sealing part of a box is sucked by one of the suction bodies, and a lifting of the sealing part of the box due to a sealing failure is detected by a detection sensor.
However, in the latter conventional sealing inspection device, the sealing inspection can be performed while the box is being transported by the transport device, but a plurality of suction bodies are assembled in the suction body moving device, and these suction bodies are circulated. Since it is moving, the structure of the suction passage connecting each suction body that circulates and the vacuum pump becomes complicated, and there is a problem that the manufacturing cost increases, and when inspecting a large number of boxes, There is also a problem that the box conveyance control is complicated because it is necessary to sequentially feed the boxes to the conveyance device at regular intervals.
JP 2008-24357 A

  The present invention solves the problems of such a conventional sealing inspection apparatus, and an object of the present invention is to carry out continuous conveyance with a simple configuration and without temporarily stopping the conveyance of the inspected box. It is another object of the present invention to provide a sealing inspection apparatus and a sealing inspection method capable of reliably performing a sealing inspection.

In order to achieve the above object, the present invention according to claim 1 provides:
A transport device for transporting the inspection box having the sealed part;
A box guide device having a guide belt that moves at substantially the same speed as the transport speed of the transport device;
A suction body for sucking a sealed portion of the inspection box;
A deformation detecting device for detecting deformation of the sealed portion of the inspected box;
A sealing inspection apparatus comprising:
The guide belt of the box guide device is provided with a vent hole, and the guide belt shifts from a contact state in contact with the sealed portion of the inspection box to a non-contact state in the middle of movement,
The suction body is disposed at a boundary portion between the contact state and the non-contact state in the guide belt and on the opposite surface side of the contact surface of the guide belt with the inspection box, and the guide in the suction body. Provide a suction port at the part that contacts the belt,
Further, the suction body is provided with an upstream guide wall surface for guiding the contacted portion of the guide belt and a downstream guide wall surface for guiding the non-contact portion of the guide belt. The suction port of the suction body opens in the guide wall surface, or the suction port of the suction body opens in both the upstream guide wall surface and the downstream guide wall surface,
The deformation detection device is configured to detect deformation of a sealed portion of the inspection box caused by suction of the suction body.

The present invention according to claim 2 is the sealing inspection apparatus according to claim 1 of the present invention,
A plurality of rows of vent holes along the direction of movement are provided in a plurality of rows in the width direction of the guide belt, and a plurality of rows of slit-like suction ports are provided so as to face the plurality of rows of vent holes of the guide belt. It is provided in the suction body .

The present invention according to claim 3 is a sealing inspection method for performing a sealing inspection while transporting an inspection box having a sealing portion,
While moving the guide belt provided with the vent hole at a speed substantially the same as the transport speed of the inspected box to be transported, the contact belt is shifted from the contact state in contact with the sealed portion of the inspected box to the non-contact state, and
A suction body is disposed at a boundary portion between the contact state and the non-contact state and on the opposite side of the contact surface of the guide belt with the inspection box, and the suction body includes the contact state of the guide belt. An upstream guide wall surface that guides the portion and a downstream guide wall surface that guides the non-contact portion of the guide belt, and the suction port of the suction body opens on the upstream guide wall surface, or The suction port of the suction body is opened on both the upstream guide wall surface and the downstream guide wall surface, and the suction member sucks the sealed portion of the inspection box through the vent hole of the guide belt. And
By detecting the deformation of the sealed portion of the inspection box caused by the suction of the suction body, the inspection inspection of the inspection box is performed.

According to the first aspect of the present invention, the suction belt is brought into contact with the sealed portion of the inspected box that is transported by the transport device, and the suction body moves at a speed substantially equal to the transport speed of the transport device. The suction portion of the inspection box is sucked through the vent hole, and deformation of the sealing portion of the inspection box caused by the suction of the suction body can be detected by the deformation detection device. Of course, it is possible to carry out sealing inspection without carrying out a plurality of inspection boxes at regular intervals while carrying out the continuous inspection by the transfer device without suspending the inspection box. Therefore, it is possible to smoothly inspect and seal a large number of inspected boxes, and the suction body and the like can also have a simple configuration.
Further, the suction port of the suction body is opened on the upstream guide wall surface of the suction body, or the suction port of the suction body is opened on both the upstream guide wall surface and the downstream guide wall surface. The sealed portion of the inspected box can be reliably sucked, and the sealed inspection can be performed more reliably and smoothly.

According to the second aspect of the present invention, in addition to the effect of the first aspect of the present invention, a plurality of vent holes are provided along the movement direction in a plurality of rows in the width direction of the guide belt. Since a plurality of rows of slit-like suction ports are provided in the suction body so as to face a large number of vent holes in a plurality of rows, suction of the sealed portion of the inspected box can be performed more reliably.

According to the third aspect of the present invention, the guide belt that moves at the same speed as the conveyance speed of the inspected box is brought into contact with the sealed portion of the inspected box to be conveyed, and the suction body Since the sealing part of the inspection box is sucked through the air hole and the deformation of the sealing part of the inspection box caused by the suction of the suction body can be detected, a plurality of inspection boxes are temporarily stopped. Of course, it is possible to carry out sealing inspections sequentially while transporting them continuously, as well as to perform sealing inspections without transporting a plurality of these inspection boxes at regular intervals, and to quickly and quickly seal the sealing state of a large number of inspection boxes. It can be inspected smoothly.
Further, the suction port of the suction body is opened on the upstream guide wall surface of the suction body, or the suction port of the suction body is opened on both the upstream guide wall surface and the downstream guide wall surface. The sealed portion of the inspected box can be reliably sucked, and the sealed inspection can be performed more reliably and smoothly.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 shows an embodiment of the present invention, a schematic side view with a part cut away, FIG. 2 is a perspective view of FIG. 1, FIG. 3 is a front view of FIG. 1, and FIG. FIG. 5 is an explanatory side view showing the positional relationship between the suction port of the suction body according to an embodiment of the present invention and the vent holes provided in the first guide belt, and FIG. 6 is the present invention. FIG. 7 is a schematic perspective view of an inspected box according to an embodiment of the present invention.

First, the inspection box A to be inspected by the sealing inspection apparatus 1 is made of carton paper, and after storing the packaged item inside, the insertion flap portion C of the lid B provided on one side of the box. A hot melt type adhesive is applied to this, and the insertion flap portion C is adhered to the inner surface of the opening of the inspected box A, thereby sealing one side of the box.
In addition, this to-be-inspected box A may be formed from corrugated paper, or may be formed from a synthetic resin sheet.

  Next, the sealing inspection apparatus 1 is for performing a sealing inspection of the inspection box A of the type shown in FIG. 7 in which one side of the box is sealed, and for transporting the inspection box A. Conveying device 2, box guide device 3, suction device 4 provided with suction body 40 for sucking the sealed part of inspected box A, deformation detecting device 5 for detecting the sealed part of inspected box A, and poor sealing And an excluding device 6 for excluding the inspected box A from the conveying device 2.

The conveying device 2 includes a driving roller 21 that is rotationally driven by a driving device 20, an idle roller 22, and a conveying belt 23 that is looped between the rollers 21 and 22.
The transport device 2 rotates the drive roller 21 as the drive device 20 rotates to circulate the transport belt 23 between the rollers 21 and 22, and the inspection box A placed on the transport belt 23 is moved. In FIG. 1, the sheet is conveyed in the arrow X direction.

  The conveyor belt 23, the first guide belt 30a described later, and the second guide belt 30b described later are made of synthetic rubber.

The box guide device 3 includes a first guide belt 30a and a second guide belt 30b that move at substantially the same speed as the transport speed of the transport device 2, that is, the circulation movement speed of the transport belt 23, and the first guide belt 30a includes As shown in FIG. 2, a large number of small circular ventilation holes 31 are formed in the width direction in three rows along the movement direction .
The box guide device 3 is disposed above the transport device 2, and the first guide belt 30a is looped between the first drive roller 32a and the first idler roller 33a. Yes.

The second guide belt 30b is looped between the second drive roller 32b and the second idler roller 33b.
The first drive roller 32a and the second drive roller 32b are assembled to the drive shaft 35 driven by the drive device 34 so as to rotate, and the first idle roller 33a and the second idle roller 33b are coupled to the interlocking shaft 36. It is designed to be idle and assembled.

In the box guide device 3 described above, the first guide belt 30a and the second guide belt 30b are moved in the direction of the arrow Y in FIG. 1 by the rotation of the first drive roller 32a and the second drive roller 32b accompanying the drive of the drive device 34, respectively. The first guide belt 30 a and the second guide belt 30 b circulate and move at a speed substantially the same as the circulation movement speed of the conveyance belt 23 of the conveyance device 2.
Further, the box guide device 3 includes a first guide body 37a for moving the first guide belt 30a that circulates from a contact state that contacts the inspected box A to a non-contact state that does not contact the first guide belt 37a. 2 The 2nd guide body 37b for changing the guide belt 30b from the contact state which contacts the to-be-inspected box A to the non-contact state which does not contact is provided.
The first guide body 37a is disposed in the loop of the first guide belt 30a and on the opposite side of the contact surface of the first guide belt 30a with the inspected box A, and the circulation path of the first guide belt 30a. Is switched from a horizontal motion to an obliquely upward motion on the upstream side of the first drive roller 32a.
The second guide body 37b is arranged in the loop of the second guide belt 30b and on the opposite side of the contact surface of the second guide belt 30b with the inspected box A, and the circulation movement path of the second guide belt 30b. Is switched from a horizontal motion to an obliquely upward motion on the upstream side of the second drive roller 32b.

  On the lower surface side of the first guide body 37a and the second guide body 37b, upstream ends for guiding the end portions of the range L1 in contact with the inspection box A in the first guide belt 30a and the second guide belt 30b, respectively. Side guide wall surfaces 38a and 38b, and downstream guide wall surfaces 39a that respectively extend from one end of these upstream guide wall surfaces 38a and 38b obliquely upward to guide the start end portion of the range L2 that is in a non-contact state with the inspected box A. -39b is provided.

As shown in FIG. 1, during the period from the first idle roller 33a to the upstream guide wall surface 38a of the first guide body 37a and from the second idle roller 33b to the upstream guide wall surface 38b of the second guide body 37b. The horizontal movement during this time is a range L1 in which the first guide belt 30a and the second guide belt 30b are in contact with the inspection box A, respectively.
In addition, as shown in FIG. 1, during the period from the downstream guide wall surface 39a of the first guide body 37a to the first drive roller 32a and from the downstream guide wall surface 39b of the second guide body 37b to the second drive roller 32b. Are in a range L2 in which they are not in contact with the inspected box A.
The inclination angle θ in the moving direction of the non-contact range L2 in the first guide belt 30a and the second guide belt 30b is preferably in the range of 10 degrees to 50 degrees, more preferably in the range of 15 degrees to 45 degrees. In the embodiment, the angle is 30 degrees.

  Here, as a configuration in which the first guide belt 30a and the second guide belt 30b circulate and move at substantially the same speed as the circulatory movement speed of the conveyor belt 23, for example, the drive device 20 and the drive device 34 are servoed. By driving with a motor and synchronously operating these two servo motors, the drive device 20 and the drive device 34 are controlled simultaneously, or a single electric motor is provided in the drive device 20 to transmit power such as belts and gears. Appropriate means may be employed such as transmitting power to the drive device 34 by a mechanism.

  The substantially same speed excludes a speed difference in which a slip mark that causes a practical problem in the inspection box A due to slip between the inspection box A and the first guide belt 30a and the second guide belt 30b is excluded. This means that a slight speed difference that does not cause slip marks is allowed.

The deformation detection device 5 detects the deformation of the sealed part of the inspection box A caused by the suction of the suction body 40 of the suction device 4.
The deformation detection device 5 includes a transmissive photoelectric sensor 52 including a light emitting element 51a and a light receiving element 51b, and a control device 53 that determines a sealing failure of the inspected box A based on a detection signal from the photoelectric sensor 52. And a display device 54 for displaying the determination result of the control device 53.

As shown in FIGS. 2 and 3, the light emitting element 51a and the light receiving element 51b constituting the photoelectric sensor 52 are close to the start position of the first guide belt 30a and the second guide belt 30b in the non-contact state with the inspected box A. In addition, it is disposed slightly above the upper outer surface of the inspection box A on the conveyor belt 23.
As shown in FIG. 6, the control device 53 also controls the drive of the drive device 20 of the transport device 2, the drive device 34 of the box guide device 3, the vacuum pump 43 of the suction device 4, and the exclusion device 6. .

The suction device 4 uses the first guide body 37a of the box guide device 3 as the suction body 40. Specifically, the first guide body 37a is formed in a hollow shape, and the inside thereof is connected to the suction chamber 41 and In addition, a suction port 42 communicating with the suction chamber 41 is opened to the upstream guide wall surface 38a and the downstream guide wall surface 39a of the first guide body 37a.
As shown in FIG. 5, three suction ports 42 are provided so as to correspond to the vent holes 31 provided in the three rows of the first guide belt 30a. The suction ports 42 are connected to the upstream guide wall surface 38a. It is formed in a slit shape extending across the downstream guide wall surface 39a.

  Further, a suction pipe 44 extending from the vacuum pump 43 is connected to the suction chamber 41, and the suction chamber 41 is made negative pressure by driving the vacuum pump 43, so that the suction port 42 and the vent holes of the first guide belt 30a. The outside air is sucked through 31.

The exclusion device 6 automatically excludes the poorly sealed inspection box A detected by the deformation detection device 5 from the transport device 2.
In the above embodiment, if necessary, a guide member (not shown) extending in the transport direction of the transport device 2 on both sides in the width direction or on one side in the width direction and at a position higher than the transport belt 23. The guide member regulates the transport posture of the test box A so that the sealed portion of the test box A transported by the transport device 2 is guided by the first guide belt 30a. The sealing part A may pass between the transport belt 23 of the transport device 2 and the first guide belt 30a of the box guide device 3.

Next, a method for performing a sealing inspection of the inspection box A by the sealing inspection apparatus 1 having the above configuration will be described.
First, when the sealed inspection box A is transported by the transport device 2, the transport box 2 holds the inspection box A so that the sealed portion of the inspection box A is guided by the first guide belt 30 a of the box guide device 3. 23.

When the inspected box A transported by the transport belt 23 is transported to the box guide device 3, as shown in FIG. 3, the sealed portion of the inspected box A becomes the first guide belt 30a and the inspected box. A portion opposite to the sealing portion A contacts the second guide belt 30b, and is further conveyed while being guided by both the guide belts 33a and 33b.
The inspected box A is transported to the position where the first guide body 37a and the second guide body 37b are disposed, and is located at a position facing the upstream guide wall surfaces 38a and 38b of the first guide body 37a and the second guide body 37b. When coming, the upper outer surface of the sealed part of the inspected box A is sucked to the first guide body 37a side through the suction port 42 and the vent hole 31 of the first guide belt 30a.

  And when sealing of the to-be-inspected box A is performed reliably, the to-be-inspected box A becomes the non-contact state from the range L1 which will be in the contact state with the to-be-inspected box A in the 1st guide belt 30a. Even if it transfers to L2, it will be conveyed in the state in which the upper outer surface of the sealing part kept horizontal, and the sealing part of the to-be-inspected box A will not be lifted.

On the other hand, when the sealing of the inspected box A is defective, that is, for example, when the adhesion between the insertion flap portion C of the lid B and the inner surface of the opening of the inspected box A is defective, Due to the suction force acting on the upper outer surface, as shown by the arrow Z in FIG. 4, the sealed portion of the inspected box A moves upward near the starting end position of the first guide belt 30a in the non-contact state with the inspected box A. It is deformed by being raised in a curved shape.
Accordingly, when the light from the light emitting element 51a is blocked by the sealing portion lifted in a curved shape, and the light receiving element 51b cannot receive the light from the light emitting element 51a, the control device 53 is not sealed properly. The determination result is displayed on the display device 54, and the inspected box A with poor sealing is automatically excluded from the transport device 2 by the exclusion device 6.

  As described above, in the sealing inspection apparatus 1 described above, the plurality of inspection boxes A can be sequentially subjected to the sealing inspection while being continuously transported by the transport apparatus 2 without being temporarily stopped. Since the sealing inspection can be performed without transporting the inspection box A at regular intervals, it is suitable for sealing inspection of a large number of inspection boxes A.

In addition, the sealing inspection apparatus 1 of this invention is not limited to the said embodiment, The various design change etc. in the range which does not deviate from the summary of invention are possible.
That is, in the above embodiment, the inspection of the inspected box A in which sealing is performed only on one side is performed, but the second guide belt 30b and the second guide body 37b are also connected to the first guide belt 30a and By adopting the same configuration as that of the first guide body 37a, for example, the left and right sealed portions of the inspected box A where sealing is performed at two places on both the left and right sides may be simultaneously inspected.
In this case, the sealing inspection of each of the left and right sealing portions may be performed by appropriately selecting from various methods of the detection unit of the deformation detecting device exemplified below.

Further, in the above embodiment, the transport device 2 is configured by a so-called belt conveyor in which the transport belt 23 is looped between the driving roller 21 and the idle roller 22, but the present invention is not limited to this. It is good also as a conveyance apparatus which consists of a roller conveyor.
Further, in the above embodiment, the transmission type photoelectric sensor 52 including the light emitting element 51a and the light receiving element 51b is used as the detection unit of the deformation detection device 5. However, the present invention is not limited to this. Alternatively, a photoelectric sensor, a laser sensor, or a CCD camera may be used.

In the above embodiment, a large number of small circular vent holes 31 are provided in the first guide belt 30a. However, the present invention is not limited to this. For example, a slit-shaped vent hole may be used. It may be a mesh-like air hole.
Further, in the above embodiment, the ventilation holes 31 of the first guide belt 30a are provided in three rows and the three suction ports 42 are provided so as to correspond to the ventilation holes 31, but the present invention is not limited to this. Instead, the vent holes 31 of the first guide belt 30a are, for example, one row, two examples, or four rows, and the suction ports 42 are provided so as to correspond to the vent holes 31, one, two, or four. Also good.

In the above embodiment, the suction port 42 is opened across the upstream guide wall surface 38a and the downstream guide wall surface 39a of the first guide body 37a. However, the present invention is not limited to this. You may open only to the guide wall surface 38a.
In this case, when the upper outer surface of the sealed part of the inspected box A with poor sealing is sucked to the first guide body 37a side through the suction port 42 and the vent hole 31 of the first guide belt 30a, the sealed part Due to the inertia of the suction force acting on the upper outer surface of the test piece, the sealed portion of the test box A is lifted upwardly in the vicinity of the start position of the first guide belt 30a in the non-contact state with the test box A. Deform.

Moreover, in the above embodiment, the sealing inspection of the inspection box A in which the insertion flap portion C of the lid B is bonded to the inner surface of the opening with a hot melt type adhesive is performed. A sealing inspection of the inspection box A sealed with a sealing label between them, or a sealing inspection of the inspection box A in which both the adhesive bonding and the sealing label are attached. You can also.
In the above embodiment, the vacuum pump 43 is used as the suction source of the suction body 40. However, the present invention is not limited to this. For example, an ejector, a blower pump, or the like may be used.

Further, in the above embodiment, the box guide device 3 is disposed above the transport device 2, but the present invention is not limited to this. For example, the upper outer surface of the sealed portion of the inspection box A is the transport device 2. When the transport belt 23 is transported in a state orthogonal to the transport surface of the transport belt 23, in other words, in a state where the lid B of the inspection box A faces upward, the transport device 2 moves the first guide belt 30 a of the box guide device 3. The first guide belt 30a may be brought into contact with the upper outer surface of the sealed portion of the inspected box transported by the transport device 2.
In this case, it is preferable that the second guide belt 30b of the box guide device 3 is disposed below the first guide belt 30a, and the second guide belt 30b assists the conveyance of the inspection box.
Furthermore, it is preferable to regulate the conveyance posture of the inspected box A by extending a guide member or a guide belt that guides the opposite surface of the surface to be inspected A in the conveying direction of the conveying device 2.

  The present invention is not limited to a box containing a medicine, and can be used for sealing inspection of a box containing food, stationery or the like.

The schematic side view which notches and shows a part of one Embodiment of this invention. The perspective view of FIG. The front view of FIG. FIG. 2 is an enlarged side view showing a main part of FIG. Explanatory drawing which shows the positional relationship of the suction opening of the suction body which concerns on one Embodiment of this invention, and the vent hole provided in the 1st guide belt. The block diagram of the control system which concerns on one Embodiment of this invention. The schematic perspective view of the to-be-inspected box which concerns on one Embodiment of this invention.

DESCRIPTION OF SYMBOLS 1 Seal inspection apparatus 2 Conveyance apparatus 23 Conveyance belt 3 Box guide apparatus 30a 1st guide belt 30b 2nd guide belt 31 Ventilation hole 38a, 38b Upstream guide wall surface 39a, 39b Downstream guide wall surface 40 Suction body 42 Suction port 5 Deformation detection Equipment A Inspected box

Claims (3)

A transport device for transporting the inspection box having the sealed part;
A box guide device having a guide belt that moves at substantially the same speed as the transport speed of the transport device;
A suction body for sucking a sealed portion of the inspection box;
A deformation detecting device for detecting deformation of the sealed portion of the inspected box;
A sealing inspection apparatus comprising:
The guide belt of the box guide device is provided with a vent hole, and the guide belt shifts from a contact state in contact with the sealed portion of the inspection box to a non-contact state in the middle of movement,
The suction body is disposed at a boundary portion between the contact state and the non-contact state in the guide belt and on the opposite surface side of the contact surface of the guide belt with the inspection box, and the guide in the suction body. Provide a suction port at the part that contacts the belt,
Further, the suction body is provided with an upstream guide wall surface for guiding the contacted portion of the guide belt and a downstream guide wall surface for guiding the non-contact portion of the guide belt. The suction port of the suction body opens in the guide wall surface, or the suction port of the suction body opens in both the upstream guide wall surface and the downstream guide wall surface,
The deformation detection apparatus detects a deformation of a sealed part of the inspection box caused by suction of the suction body. A plurality of rows of vent holes along the direction of movement are provided in a plurality of rows in the width direction of the guide belt, and a plurality of rows of slit-like suction ports are provided so as to face the plurality of rows of vent holes of the guide belt. The sealing inspection apparatus according to claim 1, wherein the sealing inspection apparatus is provided on a suction body . A sealing inspection method for performing a sealing inspection while conveying an inspection box having a sealing portion,
While moving the guide belt provided with the vent hole at a speed substantially the same as the transport speed of the inspected box to be transported, the contact belt is shifted from the contact state in contact with the sealed portion of the inspected box to the non-contact state, and
A suction body is disposed at a boundary portion between the contact state and the non-contact state and on the opposite side of the contact surface of the guide belt with the inspection box, and the suction body includes the contact state of the guide belt. An upstream guide wall surface that guides the portion and a downstream guide wall surface that guides the non-contact portion of the guide belt, and the suction port of the suction body opens on the upstream guide wall surface, or The suction port of the suction body is opened on both the upstream guide wall surface and the downstream guide wall surface, and the suction member sucks the sealed portion of the inspection box through the vent hole of the guide belt. And
A sealing inspection method comprising: detecting a deformation of a sealed portion of the inspection box caused by suction of the suction body, and performing a sealing inspection of the inspection box.

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