JP2016033019A - Processing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a processing system capable of performing predetermined processing at a normal position while restraining a cycle time for manufacturing a product from becoming long.SOLUTION: A processing system 1 comprises: a container position detection part 101 for detecting positional deviation in a conveyance direction of a laminated sheet 6 at a position before the laminated sheet 6 is conveyed to a blanking part 70; a container position detection part 102 for detecting positional deviation in the conveyance direction of the laminated sheet 6 at a position corresponding to the blanking part 70; a first correction part for moving the laminated sheet 6 in the conveyance direction so as to eliminate the positional deviation of the laminated sheet 6 on the basis of a detection result in the container position detection part 101; and a second correction part for moving the blanking part 70 in the conveyance direction so as to eliminate the positional deviation of the laminated sheet 6 on the basis of a detection result in the container position detection part 102.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a processing system suitable for application to, for example, a molding and filling system having a position correction function corresponding to thermal strain caused by heating a sheet-shaped resin material.

Conventionally, in various fields such as foods, beverages, cosmetics, and pharmaceuticals, a container comprising a container body having a cup-shaped housing recess for containing contents and a lid (or seal) for sealing the opening of the container body. Products containing are used.
A product including this container for containing contents can be produced, for example, as follows (Patent Document 1).
Deep drawing that dents the heated part into the same shape as the container body while heating while conveying a sheet made of thermoplastic resin for molding the container body (hereinafter referred to as cup material sheet) Perform molding. The cup material sheet is conveyed intermittently, that is, repeatedly conveyed and stopped. Assuming that the supply side of the cup material sheet is upstream, heating is performed at a predetermined position on the upstream side (referred to as P1) and a predetermined position on the downstream side (referred to as P2) during the interval in which the conveyance is stopped. Deep drawing is performed in step (b). Next, when the cup material sheet is conveyed toward the downstream side until the region heated at the position P1 reaches the position P2, the conveyance is stopped, and heating is performed at the position P1 as a subsequent process. Deep drawing is performed at the downstream position P2. As described above, intermittent conveyance, heating, and molding are repeated. However, in one cup material sheet that is continuously continuous, molding corresponding to a plurality of containers is performed in both the conveyance direction and the width direction. Some products are applied.

When the deep-drawn part is conveyed to a predetermined position (referred to as P3) on the downstream side of the position P2, the lid is prepared separately after filling the cup portion forming the container body with the contents. For example, a resin sheet (hereinafter referred to as a sealing material sheet) is attached to the cup material sheet after being aligned.
Thereafter, when the laminated sheet on which the cup material and the sealing material sheet are adhered is conveyed to a predetermined position (referred to as P4) on the downstream side, the laminated sheet is punched out in order to divide a plurality of containers into individual containers. Cut with.

In the series of steps described above, when the sealing material sheet is attached, it is necessary that the sealing material sheet is aligned at a normal position with respect to the cup material sheet. In other words, character information and graphic information including the product name are described on the sealing material sheet, but when the sealing material sheet is displaced and pasted on the cup material sheet, the character information Etc. cause a positional shift with respect to the container.
Further, in the punching process, if the laminated sheet is displaced from the normal position with respect to the punching tool, the punched product will be different from the desired shape, for example, the flange portion connected to the housing recess. .
Usually, a product whose character information or the like is misaligned or a product whose punching position is misaligned is discarded as a defective product.

  As described above, since the cup sheet is heated for deep drawing, thermal strain, typically shrinkage, can occur. Therefore, even if the cup material sheet is intermittently conveyed by the conveyance device by a certain amount, if thermal distortion occurs, there is a possibility that the seal position and the punching position are displaced.

  Patent Document 2 detects the positioning marking formed on the cup material sheet at the time of deep drawing by using, for example, a marking detection means provided at the punching position, and this detection result is obtained. Based on the above, it is proposed to adjust the punching position. According to the proposal of Patent Document 2, even if the sheet itself is stretched or contracted due to thermal stress, it is possible to perform punching at an appropriate position.

Japanese Patent Publication No. 61-9164 JP 2001-277191 A

Patent Document 2 uses a drive mechanism including a ball screw and a ball nut to perform position correction. However, when the cup material sheet is made of a thermoplastic resin having a large thermal strain, for example, polypropylene, this drive is performed. If the position is corrected by the mechanism, a considerable amount of time is consumed, and the cycle time for producing the product becomes long.
Therefore, an object of the present invention is to provide a processing system capable of performing predetermined processing at a regular position while suppressing an increase in cycle time for producing a product.

For this purpose, the processing system of the present invention specifies the first sheet made of a continuous thermoplastic resin relative to the first sheet that is stopped while being conveyed intermittently on the conveying path. A predetermined process is performed at the part.
The processing system of the present invention is provided at a specific part on the conveyance path, and performs processing for performing a predetermined process on the first sheet, and positional deviation in the conveyance direction of the first sheet before being conveyed to the processing unit. A first detection unit to detect, a second detection unit to detect a displacement in the conveyance direction of the first sheet at a position corresponding to the processing unit, and the position of the first sheet based on a detection result in the first detection unit Based on the first correction unit that moves the first sheet in the conveyance direction so as to eliminate the deviation, and the detection result in the second detection unit, the processing unit is arranged in the conveyance direction so as to eliminate the positional deviation of the first sheet. And a second correction unit to be moved.

  Since the processing system of the present invention includes a pair of the second detection unit and the second correction unit in addition to the pair of the first detection unit and the first correction unit, for example, the thermal contraction amount of the first sheet is large and unstable. During the period, the first correction unit that can increase the correction allowance corrects the positional deviation of the laminated sheet 6, and during the period when the thermal contraction amount of the first sheet is stable, the second correction unit is used to perform positioning with high accuracy. It can be carried out.

  In the processing system of the present invention, the preliminary production operation for conveying the first sheet without performing the predetermined process in the processing unit, and the main production operation for conveying the first sheet while performing the predetermined process in the processing unit, In the preliminary production operation, it is preferable to eliminate the positional deviation using the first correction unit, and to eliminate the positional deviation using the second correction unit in the main production operation. .

  Further, the processing system of the present invention preferably includes a limit detection unit that detects a limit by which the second correction unit moves the processing unit, and when the limit detection unit detects that the limit has been reached in the production operation. The second correction unit returns to the initial position where the main production operation is started, and the first correction unit eliminates the positional deviation of the first sheet based on the detection result by the first detection unit. Thereafter, based on the detection result by the second detection unit, it is preferable to shift to a correction operation in which the second correction unit eliminates the positional deviation of the first sheet.

  As a 1st correction | amendment part in the processing system of this invention, it is preferable to provide the dancing roll which touches a 1st sheet | seat. By changing the height, it is possible to eliminate the positional deviation.

  The processing system of the present invention is typically applied to a system called a molding and filling machine. The processing system includes: a molding unit that molds a storage recess having a predetermined shape on a first sheet softened by heating; a filling unit that fills the storage recess with a predetermined content; and a first sheet having a storage recess. By sticking a 2nd sheet | seat, the sealing part which seals an accommodation recessed part with a 2nd sheet | seat, and the punching part punched in a predetermined number of units so that an accommodation recessed part and its peripheral part may be included are provided. It is preferable to apply the processing unit of the present invention to the punching unit in this processing system.

  According to the processing system of the present invention, since the second detection unit and the second correction unit are provided in addition to the first detection unit and the first correction unit, for example, the thermal contraction amount of the first sheet is large and During the unstable period, the first correction unit that can increase the correction allowance corrects the positional deviation of the laminated sheet 6, and during the period when the thermal contraction amount of the first sheet is stable, the second correction unit is used with high accuracy. Positioning can be performed.

It is a block diagram which shows the component of the shaping | molding filling system which concerns on this Embodiment. It is a figure which shows schematic structure after the cooling part of the shaping | molding filling system of FIG. It is a figure which shows how to obtain | require the position of the accommodation recessed part in the shaping | molding filling system of FIG. It is a figure which shows the intermittent operation | movement of the shaping | molding filling system of FIG. It is a timing chart which shows operation | movement of the shaping | molding filling system of FIG.

Hereinafter, the present invention will be described by taking a molding and filling system 1 shown in the accompanying drawings as an example.
The molding filling system (hereinafter simply referred to as system) 1 according to the present embodiment, after filling the plurality of cup-shaped receiving recesses 7 formed in the cup material sheet by deep drawing, affixing the sealing material sheet, Thereafter, a series of steps of producing the product P by dividing into individual containers by punching is performed.

[Configuration of system 1]
As shown in FIGS. 1 and 2, the system 1 includes a preheating portion 10, a forming portion 20, a filling portion 30, a sealing portion 40, a cooling portion 50, a tack portion 60, and a punching portion 70 (from the upstream side toward the downstream side). Dispensing sections 80) are arranged in a line to form a conveyance path. The system 1 can produce the product P in an aseptic state by accommodating the preheating unit 10, the molding unit 20, the filling unit 30, the sealing unit 40, and the cooling unit 50 in the aseptic chamber R. The system 1 includes a clip chain transport unit 8 inside the sterile room R.

In the system 1, an original fabric roll 3 in which a cup material sheet 2 prepared as a long sheet is wound in a roll shape is disposed upstream of the preheating unit 10. When producing the product P, the system 1 produces the product P by unwinding the cup material sheet 2 from the raw roll 3 and sequentially passing through the preheating unit 10 to the punching unit 70. The cup material sheet 2 may be made of a resin having a material suitable for the application, and is made of, for example, a thermoplastic resin such as polystyrene or polypropylene. This embodiment is suitable for producing a product P with a relatively long cycle time using a material having a large thermal strain such as polypropylene.
In addition, the upstream and downstream in the molding filling system 1 shall be determined based on the direction in which the cup material sheet 2 and the sealing material sheet 4 are conveyed. This transport direction is indicated by a white arrow d in FIGS.

The system 1 includes an original fabric roll 5 in which a sealing material sheet 4 prepared as a long sheet is wound in a roll shape. When producing the product P, the system 1 unwinds the sealing material sheet 4 from the raw roll 5 and supplies it toward the cup material sheet 2 after the contents are filled by the filling unit 30.
The sealing material sheet 4 may be made of a resin having a material suitable for the application, and is made of a thermoplastic resin such as polystyrene or polypropylene. Moreover, the sealing material sheet 4 can also use metal foil, for example, aluminum foil.

  The system 1 includes a collection roll 9 for collecting the laminated sheet 6 after the product P is punched on the most downstream side. When the collection roll 9 rotates, the laminated sheet 6 is conveyed while applying tension to the laminated sheet 6.

  In the system 1, the cup material sheet 2 unwound from the raw roll 3 and the sealing material sheet 4 bonded to the cup material sheet 2 from the middle are intermittently conveyed downstream by the clip chain conveying unit 8. However, necessary processing is performed. In other words, while the cup material sheet 2 is stopped for t1 seconds, the cup material sheet 2 is placed within a time period of t2 seconds after necessary processing is performed in each part such as the preheating unit 10 and the molding unit 20. Transport only a fixed amount. Next, the product P is produced by repeating the procedure of stopping for t1 seconds and performing necessary processing in each part such as the preheating unit 10 and the molding unit 20 during this period.

In the clip chain transport unit 8, a chain forming an endless track includes a clip (or a gripper), and the chain is bonded to both ends in the width direction of the cup material sheet 2 and the cup material sheet 2 and the seal material sheet 4 are bonded together. After that, the laminated sheet 6 is provided at both ends in the width direction. The chain intermittently conveys the cup material sheet 2 by the chain traveling intermittently on the endless track while the clip holds the edge of the cup material sheet 2.
The reason why the system 1 uses the clip chain transport unit 8 as a transport means is because it is assumed that the cup material sheet 2 is made of a thermoplastic resin having a large heat shrinkage, for example, polypropylene. In other words, the cup material sheet 2 is gripped and conveyed by the clip chain conveying unit 8 before being heated by the preheating unit 10, thereby restraining the shrinkage of the heated cup material sheet 2.
Although the heat shrinkage of the cup material sheet 2 and the like can be limited to some extent by using the clip chain conveying unit 8 as the conveying means, the heat shrinkage is applied to the cup material sheet 2 and the like after the restraint by the clip chain conveying unit 8 is released. Arise.

The preheating unit 10 heats and softens the cup material sheet 2 so that deep drawing can be performed in the molding unit 20. The form of the preheating unit 10 is arbitrary. For example, a planar heater that can uniformly heat a predetermined region can be used, or a heater heater that includes a heating region corresponding to only a portion that needs heating can be used. Can do. These heaters can be provided on both the front and back sides of the cup material sheet 2 so as to sandwich the conveyed cup material sheet 2 from the front and back sides.
The temperature at which the cup material sheet 2 is heated by the preheating unit 10 is determined according to the resin that constitutes the cup material sheet 2.

The molding unit 20 employs a plug molding method including a plug that is a molding tool pressed against the cup material sheet 2 heated to a predetermined temperature, and a drive source that moves the plug up and down. As many plugs as the number of accommodating recesses 7 formed by one molding are prepared.
However, as the molding unit 20, for example, other molding methods such as heating / pressure forming, drum vacuum forming, pin forming, preheater pressure forming, preheater plug assist pressure forming can be applied.

The filling unit 30 is disposed along the conveyance path of the cup material sheet 2 on the downstream side of the forming unit 20 and automatically fills the receiving recess 7 formed by the forming unit 20 with the predetermined content C. If the content C is a liquid, the filling part 30 can drop the content C by making the nozzle for filling confront the accommodation recessed part 7 in the interval period in the conveyance process of the cup material sheet 2. Further, the filling unit 30 may use a mechanism for gripping the content C as long as the content C is solid.
The content C to be filled is not limited in any way, and can be applied regardless of liquid or solid, and may be a liquid or a paste.

The seal portion 40 is disposed downstream of the filling portion 30 and bonds the seal material sheet 4 unwound from the raw fabric roll 5 to the cup material sheet 2 filled with the contents C. Bonding can be performed by heat sealing.
The seal unit 40 includes a heating source 41, a support 45 that supports each of the four corners of the heating source 41, a moving carriage 47 to which the lower end of the supporting pillar 45 is fixed, and a driving source that reciprocates the moving carriage 47 in the transport direction. 48 and a pair of rails 49 that restrict the movement of the movable carriage 47 only in the transport direction.
The seal unit 40 controls the position of the heating source 41 by operating the drive source 48 based on a command from the controller 100. The drive source 48 is composed of, for example, a servo motor. The contents of this control will be described later.

The cooling unit 50 cools the laminated sheet 6 formed by bonding the cup material sheet 2 and the sealing material sheet 4, and suppresses thermal contraction of the laminated sheet 6.
The cooling unit 50 may be in any form as long as the laminated sheet 6 can be cooled. For example, the cooling unit 50 is configured to circulate cooling water inside a flat cooling jacket made of a metal material having good thermal conductivity, for example, a copper alloy. Or the form etc. which the air for cooling blows out toward the lamination sheet 6 are employable.

The tack unit 60 is disposed downstream of the cooling unit 50 and between the cooling unit 50 and the punching unit 70, and adjusts the position of the laminated sheet 6 relative to the punching unit 70 on the downstream side of the tack unit 60.
The tack unit 60 includes a dancing roll 61 in contact with the laminated sheet 6, a pair of support arms 63 and 63 that rotatably support the dancing roll 61, and a lifting cylinder 65 that supports the pair of support arms 63 and 63 so as to be movable up and down. , 65. The tack unit 60 moves up and down the dancing roll 61 according to an instruction from the controller 100 and adjusts the length of the pass line of the laminated sheet 6. For example, when the dancing roll 61 is displaced downward (down), the laminated sheet 6 is drawn upstream on the downstream side of the tack part 60, so that the position of the laminated sheet 6 with respect to the punching part 70 is moved upstream. Can do. On the contrary, when the dancing roll 61 is displaced upward (raised), the laminated sheet 6 is pulled out to the downstream side, so that the position of the laminated sheet 6 with respect to the punching portion 70 can be moved to the downstream side.
The tack portion 60 can correct the position of the laminated sheet 6 with respect to the punched portion 70 as described above. However, since the amount of correction of the laminated sheet 6 can be corrected particularly quickly, The misalignment of the laminated sheet 6 is corrected using the tack portion 60 in the take-out operation.
Hereinafter, the tack unit 60 may be referred to as a first correction unit.

The punching portion 70 is disposed on the downstream side of the tack portion 60 and has a function of punching in units of a predetermined number of products P so as to include the accommodating recess 7 of the laminated sheet 6 and its peripheral portion.
The punching unit 70 includes, for example, a punching tool that uses a die as a lower die 71 and a punch as an upper die (not shown), and a drive source (not shown) that moves the lower die 71 or the upper die up and down. can do.
The punching unit 70 includes a column 75 for supporting the lower mold 71 at each of its four corners, a movable carriage 77 to which the lower end of the pillar 75 is fixed, a drive source 78 for reciprocating the movable carriage 77 in the conveying direction, and a movable carriage. And a pair of rails 79 for restricting the movement of 77 only in the transport direction. Hereinafter, the combination of the moving carriage 77, the drive source 78, the moving carriage 77, and the pair of rails 79 may be referred to as a second correction unit.
The punching unit 70 controls the positions of the lower mold 71 and the upper mold in the conveyance direction by operating the drive source 78 based on a command from the controller 100. The drive source 78 is composed of a servo motor, for example. The contents of this control will be described later.

  The laminated sheet 6 after the product P has been punched in the punching portion 70 is taken up by the collection roll 9 disposed downstream of the punching portion 70.

  The payout part 80 is disposed above the punching part 70, punched in the punching part 70, receives the product P by suction, and conveys it toward the next process. The paying-out part 80 can be comprised including the belt conveyor arrange | positioned so that it may orthogonally cross in the conveyance direction of the cup material sheet 2, for example.

The system 1 includes two container position detection units 101 and 102 attached to the punching unit 70. The container position detection units 101 and 102 detect the displacement of the laminated sheet 6 at each position when performing a cueing operation to be described later and in the main production operation. As will be described in detail later, the cueing operation is a process in which each of the seal portion 40 and the punching portion 70 is positioned at an appropriate position with respect to the laminated sheet 6 in the initial stage of continuously producing the product P. . Moreover, this production operation is a process of continuously producing products after cueing.
The container position detection unit 101 is disposed upstream of the punching unit 70, that is, in front of the punching unit 70, and a pair of light emitting units 101A and 101a disposed at a predetermined interval in the transport direction, and the light emitting unit 101A, And light receiving elements 101B and 101b for receiving the inspection light emitted from 101a. Although the light receiving elements 101B and 101b are not shown in the drawing, the reference numerals are given to distinguish them from each other. The same applies to light receiving elements 102B and 102b described later. The light emitting means 101A and 101a are composed of optical fibers, for example, and emit light supplied from a light source (not shown) as inspection light LA and La from the side of the laminated sheet 6 during the interval. The light receiving elements 101B and 101b receive the inspection lights LA and La emitted from the light emitting means 101A and 101a and passing through the width direction of the laminated sheet 6. However, if the laminated sheet 6 is misaligned, the inspection light LA, La is blocked by the housing recess 7, so that the light receiving elements 101B, 101b can receive either the inspection light LA, La. Disappear.

FIG. 3 shows three forms in which the light receiving elements 101B and 101b receive the inspection lights LA and La.
FIG. 3A shows a state in which the light receiving elements 101B and 101b receive the inspection lights LA and La, respectively, without both of the inspection lights LA and La being blocked by the housing recess 7. When this light receiving mode is obtained, the controller 100 determines that the laminated sheet 6 is in an appropriate position and no positional deviation has occurred.
Next, FIG. 3B shows that the upstream inspection light LA is blocked by the accommodation recess 7, and FIG. 3C shows the state where the downstream inspection light La is blocked by the accommodation recess 7. Show. In both cases of FIG. 3B and FIG. 3C, the laminated sheet 6 is displaced, but FIG. 3B shows that the housing recess 7 is located upstream from the proper position. In FIG. 3C, the housing recess 7 is displaced downstream from the proper position.
The light reception results in the light receiving elements 101B and 101b are sent to the controller 100, and the controller 100 operates the drive source 48 based on the light reception results to eliminate the positional deviation of the seal portion 40.

  The container position detection unit 102 is disposed corresponding to the punching unit 70, and is emitted from a pair of light emitting units 102A and 102a and a light emitting unit 102A and 102a arranged at a predetermined interval in the transport direction. Light receiving elements 102B and 102b for receiving the inspection light. The container position detection unit 102 is displaced from the container position detection unit 101, and the drive source 78 is operated based on the light reception results of the light receiving elements 102B and 102b, thereby causing the position shift of the punching unit 70. Except for eliminating the above, since it performs the same function as the container position detection unit 101, the following description is omitted.

  Further, the system 1 includes a container position detection unit 103 corresponding to the seal unit 40. The container position detection unit 103 includes a pair of light emitting units 103A and 103a disposed at a predetermined interval in the transport direction, and light receiving elements 103B and 103b that receive inspection light emitted from the light emitting units 103A and 103a. It is equipped with. The container position detection unit 103 differs from the container position detection units 101 and 102 in that the position of the seal unit 40 is changed, and the drive source 48 is operated based on the light reception results of the light receiving elements 103B and 103b. Except for eliminating the misalignment, the same function as that of the container position detection units 101 and 102 is achieved, and hence the following description is omitted.

Next, the system 1 includes a movement limit detection unit 105.
The movement limit detection unit 105 is provided in association with the moving carriage 77 of the punching section 70 and detects whether or not the movement carriage 77 has reached the movement limit.

  The movement limit detection unit 105 includes a pair of proximity switches 105A and 105a arranged so as to be spaced apart from each other in the transport direction and fixed in position, while the moving carriage 77 includes a contact piece 105c. The distance between the proximity switches 105A and 105a is set in a range in which the movement of the movable carriage 77 is allowed, and the contact piece 105c is fixed to the movable carriage 77 so as to be disposed between the proximity switch 105A and the proximity switch 105a. The When the moving carriage 77 moves upstream and the contact piece 105c contacts the proximity switch 105A, the proximity switch 105A notifies the controller 100 that the moving carriage 77 has reached the upstream movement limit. When the moving carriage 77 moves downstream and the contact piece 105c contacts the proximity switch 105a, the proximity switch 105a notifies the controller 100 that the moving carriage 77 has reached the downstream movement limit.

[Operation of system 1]
The operation of the system 1 having the above configuration will be described.
The system 1 sequentially performs a cueing operation (preliminary production operation) at the beginning of the production of the product P and a main production operation performed following the cueing operation. In the cueing operation, the cup material sheet 2 and the sealing material sheet 4 are newly attached to the original fabric roll 3 and the original fabric roll 5 to start production by a new batch. It is also performed when production is resumed after production is interrupted. Hereinafter, the cue operation and the production operation will be described in this order. In the cueing operation, the cup material sheet 2 unwound from the original fabric roll 3 and the sealing material sheet 4 unwound from the original fabric roll 5 are predetermined positions where the procedure of the cueing step described below is performed. It starts from the state that has been reached. This transfer can also be performed manually by an operator.

<Cueing operation>
The cueing operation is performed with respect to the punching unit 70, but in the initial stage of production in which the cueing operation is performed, a so-called empty container that is not yet filled with the contents C is conveyed to the punching unit 70. At the initial stage of production, since the amount of heat shrinkage of the cup material sheet 2 and the like is large, the displacement in the punched portion 70 is large. Therefore, in the cueing operation, the misalignment is corrected using the tack unit 60 that can quickly correct a large amount. Hereinafter, a specific procedure for correcting misalignment will be described.

In the cueing operation, the container position detection unit 101 emits the inspection lights LA and La from the pair of light emitting units 101A and 101a, and transmits the detection results of the inspection lights LA and La by the light receiving elements 101B and 101b to the controller 100. To do.
The controller 100 drives the tack unit 60 to raise and lower the dancing roll 61 according to the detection result. That is, when both the inspection lights LA and La are detected (FIG. 3A), the controller 100 determines that the position of the seal portion 40 with respect to the cup material sheet 2 (and the seal material sheet 4) is appropriate, and tacks. No drive command is issued to the unit 60.
Further, when only the inspection light La is detected (FIG. 3B), the controller 100 determines that the punched portion 70 is displaced downstream with respect to the laminated sheet 6, and the displacement is eliminated. Until it is done, a drive command is issued to the lifting cylinders 65, 65 so as to lower the dancing roll 61.
When only the inspection light LA is detected (FIG. 3C), the controller 100 determines that the punched portion 70 is displaced upstream with respect to the laminated sheet 6, and the displacement is eliminated. Until it is done, a drive command is issued to the lifting cylinders 65, 65 so as to raise the dancing roll 61.

  When the controller 100 detects only the inspection light La and only the inspection light LA, the controller 100 detects the inspection lights LA and La by the light receiving elements 101B and 101b after the dancing roll 61 has moved by a predetermined distance. Get the result. If only one of the inspection lights LA and La is detected, the dancing roll 61 is raised and lowered in the same manner as described above, and thereafter, the above procedure is repeated until both the inspection lights LA and La are detected.

<Position correction in production operation>
When the cueing operation ends, the production operation starts. In this production operation, the laminated sheet 6 including the product P in which the contents C are filled in the housing recess 7 is repeatedly conveyed to the punching unit 70, so that the variation in the amount of heat shrinkage for each conveyance is small and stable. To do.
In the following, after describing a series of operations in the production operation, a position correction procedure in the punching unit 70 and the seal unit 40 will be described.

  This production operation is a processing period in which the operation of attaching the sealing material sheet 4 to the cup material sheet 2 in the sealing portion 40 and the operation of punching out the portion corresponding to the product P of the laminated sheet 6 in the punching portion 70 are performed in parallel. t1 is provided. Before the processing is started, a correction period t3 is provided in which correction is performed after detecting a positional deviation. When the processing period t1 subsequent to the correction period t3 ends, a conveyance period t2 for conveying the laminated sheet 6 is executed, and thereafter, an operation in which the correction period t3, the processing period t1, and the conveyance period t2 are performed as one cycle is repeatedly performed. Is called. The laminated sheet 6 remains stationary between the processing period t1 and the correction period t3 and is subjected to predetermined processing.

  For example, it is assumed that the first process (first shot) in the cueing operation shown in FIG. At this time, the N1th processing region 6A of the laminated sheet 6 corresponds to the punched portion 70, and the N5th processing region 6A corresponds to the seal portion 40. In FIG. 4, the positions of the seal portion 40, the punched portion 70, and the laminated sheet 6 are drawn so as to be understood so that the relative positional relationship between the seal portion 40 and the punched portion 70 and the laminated sheet 6 can be understood.

When the processing of the first shot (correction period t3 + processing period t1) is completed, the laminated sheet 6 is conveyed by the tack unit 60, and as shown in FIG. 70, the N6th processing region 6A corresponds to the seal portion 40. This conveyance is performed during the conveyance period t2. Further, an N6th processing region 6A exists in front of the seal portion 40, and an N2th processing region 6A exists in front of the punching portion 70.
When the conveyance is completed, after correcting the positional deviation within the correction period t3, the N2th processing region 6A is punched by the punching unit 70, and the N6th processing region 6A is cut by the sealing unit 40 and the cup material sheet 2 and the sealing material sheet. 4 is pasted. This second shot process is also performed during the processing period t1. In addition, it transfers to this production process from the 2nd shot.
When the processing of the second shot is completed, the laminated sheet 6 is conveyed by the tack unit 60, so that the N3th processing region 6A corresponds to the punching unit 70 and the N7th processing region 6A corresponds to the seal unit 40. . This conveyance is performed during the conveyance period t2.
Thereafter, the product P is continuously produced by repeating the same procedure.

Also in the production operation, in each of the seal part 40 and the punching part 70, the detection process for detecting the positional deviation amount of the laminated sheet 6 and the seal part 40 and the punching 70 are moved in order to eliminate the detected positional deviation. Move processing. The system 1 performs detection processing and movement processing during the transport period t2.
Although both the seal part 40 and the punching part 70 perform the process of correcting the positional deviation, since the specific processing procedure is the same, the punching part 70 will be described below. Only the differences from 70 will be mentioned.

<Detection process>
The detection process is performed by the container position detection unit 102.
The container position detector 102 emits the inspection lights LA and La from the light emitting means 102A and 102a, and detects the light receiving state in the light receiving elements 102B and 102b. The light receiving state is as described above, and is divided into three (a), (b), and (c) in FIG.

<Move process>
The controller 100 issues an operation command to the drive source 78 in accordance with the result of the light receiving state. This command includes orientation and distance, but the distance is quantitative. The drive source 78 moves the movable carriage 77 by a fixed amount based on a command from the controller 100. After the moving carriage 77 has moved, the detection process is performed again, and the controller 100 issues an operation command to the drive source 78 according to the detection result, and moves the moving carriage 77 by a fixed amount.
Thereafter, until both of the inspection lights LA and La are received by the light receiving elements 102B and 102b, that is, from the light receiving state of FIG. 3B to the light receiving state of FIG. The above procedure is repeated from the light receiving state to the light receiving state of FIG.

<Explanation of operation timing>
The series of operation timings of the production operation will be described with reference to the timing chart shown in FIG.
FIG. 5 shows an operation in which cueing is performed in the first shot and shifting to the main production from the second shot, and the vertical axis indicates the processing contents in each shot.
<First shot>
In the first shot, the punched portion 70 conveys the product P of the laminated sheet 6 to a predetermined position (conveyance period t2). When transported so far, the cup material sheet 2 and the seal material sheet 4 are transported to a predetermined position where the cup material sheet 2 and the seal material sheet 4 can be attached in the seal portion 40. This conveyance is performed by the clip chain conveyance unit 8.

When the conveyance to the predetermined position is performed, the operation of the clip chain conveyance unit 8 is stopped and the positional deviation in the cueing is corrected (correction period t3). The procedure for correcting misalignment in cueing is as described above, but differs from the misalignment correction in the production operation in that the tacking unit 60 is used.
When the correction of the positional deviation is completed, the cup material sheet 2 and the sealing material sheet 4 are attached in the seal portion 40, and at the same time, the product P is punched in the punch portion 70 (processing period t1).
When the sealing process and punching process for the first shot (cueing) are completed, the second shot (the main production process) is started.

<Second shot>
It is assumed that the production operation starts from the second shot.
The second shot is started by conveying the laminated sheet 6 and the like by a predetermined distance during the conveyance period t2.
When the conveyance is performed to the predetermined position, the positional deviation is corrected during the correction period t3. If the correction of the positional deviation is completed, then, the sticking is performed in the seal portion 40 and the punching is performed in the punching portion 70 during the processing period t1.
When the sealing process and the punching process for the second shot are completed, the third and subsequent shots are performed in the same procedure as the second shot.

  Here, if correction is performed to continuously move the mobile carriage 77 in the same direction, for example, upstream, the upstream movement limit may be reached, and then further correction in the same direction is performed. I can't do that. On the other hand, it is difficult to move the movable carriage 77 without limitation in order to maintain the positional relationship with the dispensing unit 80 that collects the punched product P. Therefore, while the movement carriage 77 is provided with a movement limit, when the movement limit is reached, the positional relationship between the laminated sheet 6 and the movement carriage 77 is returned to the initial state after cueing as described below.

  The movement limit detection unit 105 continues the detection operation while correcting the positional deviation in the production operation. When the movement limit detection unit 105 detects that the movement carriage 77 has reached the movement limit, the detection result is detected. Send to controller 100. The detection result is either that the mobile carriage 77 reaches the upstream movement limit or the mobile carriage 77 reaches the downstream movement limit.

When the controller 100 acquires the detection result indicating that the movement limit has been reached, the controller 100 drives the drive source 78 to return the moving carriage 77 to the initial position of the production operation.
Next, the controller 100 corrects the positional deviation of the laminated sheet 6 with respect to the movable carriage 77 using the tack unit 60. Similar to the cueing operation, this correction acquires information (FIGS. 3A, 3B, and 3C) on the positional deviation detected by using the container position detection unit 101, and from the container position detection unit 101. Based on the information to be acquired, the dancing roll 61 of the tack unit 60 is moved up and down.

  When the origin is returned as described above, the movable carriage 77 is moved based on the information (FIGS. 3A, 3B, and 3C) regarding the positional deviation detected using the container position detection unit 102. As a result, the control can be switched to the control for correcting the positional deviation.

  The position correction of the seal portion 40 is performed in the same manner. However, there is no mechanism for the movement limit.

<Effect of system 1>
Next, the effect regarding the system 1 demonstrated above is demonstrated.
First, the system 1 includes a first correction unit including a tack unit 60 and a second correction unit including a moving carriage 77 and a drive source 78 as means for performing correction in the punching unit 70. Then, during a period in which the amount of heat shrinkage of the sheet is large and unstable and the content is not filled, the first correction unit that can increase the correction allowance corrects the positional deviation of the laminated sheet 6. On the other hand, since punching is performed during the period when the contents are filled, positioning is performed with high accuracy by correction using the second correction unit. Since the second correction unit determines the positional deviation in the punching unit 70 where the punching is performed and can achieve positioning with high accuracy, the occurrence rate of defective products due to the positional deviation can be suppressed. As described above, the system 1 contributes to the improvement of the production yield of the product P while ensuring smooth operation by properly using the correction unit according to the state of operation.

  In addition, when the correction by the second correction unit reaches the limit, the system 1 uses the tack unit 60 that is the first correction unit in addition to returning the second correction unit to the initial position. The positional deviation of the laminated sheet 6 is eliminated. Therefore, thereafter, positioning with high accuracy can be performed by the second correction unit.

As described above, the present invention has been described based on the embodiments. However, the configuration described in the above embodiments may be selected or changed to other configurations as appropriate without departing from the gist of the present invention. is there.
Specific elements constituting the system 1 are arbitrary. For example, a mechanism for moving the heat source 41 in the seal portion 40 to correct the heating source 41 is arbitrary, a linear motor can be used, and the punching portion 70 can be punched. The mechanism is also arbitrary and can be cut by irradiating laser light instead of using a tool.

1 Mold filling system (system)
2 Cup material sheet 3 Original fabric roll 4 Seal material sheet 5 Original fabric roll 6 Laminated sheet 6A Processing area 7 Containing recess 8 Clip chain transport unit 9 Collection roll 10 Preheating unit 20 Molding unit 30 Filling unit 40 Sealing unit 41 Heating source 45 Column 47 Moving carriage 48 Driving source 49 Rail 50 Cooling section 60 Tack section 61 Dancing roll 63 Support arm 65 Lifting cylinder 70 Punching section 71 Lower mold 75 Post 77 Moving carriage 78 Driving source 79 Rail 80 Dispensing section 100 Controller 101, 102, 103 Container Position detecting unit 101A, 101a Light emitting unit 102A, 102a Light emitting unit 103A, 103a Light emitting unit 105 Movement limit detecting unit 105A, 105a Proximity switch 105c Contact piece LA, La Inspection light P Product R Aseptic chamber t1 Processing period t2 Transport period t3 Correction period

Claims (5)

The first sheet made of a thermoplastic resin that is continuously continuous is intermittently conveyed on the conveyance path, and the predetermined processing on the specific part on the conveyance path is performed on the sheet on which the conveyance is stopped. A processing system for applying
A processing unit that is provided at a specific portion on the conveyance path and that performs a predetermined process on the first sheet;
A first detection unit that detects a displacement in the conveyance direction of the first sheet before being conveyed to the processing unit;
A second detection unit that detects a displacement in the conveyance direction of the first sheet at a position corresponding to the processing unit;
A first correction unit configured to move the first sheet in the transport direction so as to eliminate the positional deviation of the first sheet based on a detection result in the first detection unit;
A second correction unit configured to move the processing unit in the transport direction so as to eliminate the positional deviation of the first sheet based on a detection result in the second detection unit;
A processing system comprising: The processing system includes:
A preliminary production operation for conveying the first sheet without performing a predetermined process in the processing unit;
A main production operation for conveying the first sheet while performing a predetermined process in the processing unit is selectively performed,
In the preliminary production operation, the first misalignment is eliminated using the first correction unit,
In the main production operation, the misalignment is eliminated using the second correction unit.
The processing system according to claim 1. The second correction unit includes a limit detection unit that detects a limit for moving the processing unit,
In the production operation,
When the limit detection unit detects that the limit has been reached,
The second correction unit returns to the initial position where the main production operation is started, and the first correction unit shifts the position of the first sheet based on the detection result by the first detection unit. Solved,
Thereafter, based on the detection result by the second detection unit, the second correction unit shifts to a correction operation to eliminate the positional deviation of the first sheet.
The processing system according to claim 2. The first correction unit includes:
Comprising a dancing roll in contact with the first sheet, and changing the length of the pass line of the first sheet by the dancing roll to eliminate the positional deviation;
The processing system as described in any one of Claims 1-3. The processing system includes:
A molding part that molds a housing recess having a predetermined shape in the first sheet softened by heating;
A filling portion for filling the receiving recess with a predetermined content;
A seal portion that seals the housing recess with the second sheet by attaching a second sheet to the first sheet in which the housing recess is formed;
A punched portion that is punched in a predetermined number of units so as to include the accommodating concave portion and the peripheral portion thereof, and
The punched portion constitutes the processing unit,
The processing system as described in any one of Claims 1-4.

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