JP2014033797A - Apparatus and method for manufacturing connected article of individual package related to absorbent article - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily cope with a change in connection number of connected articles of individual packages.SOLUTION: In an apparatus, a connected article is manufactured by separating a connected article of individual packages formed by connecting a predetermined number of individual packages from a continuous body of individual packages formed by connecting a plurality of individual packages individually storing an absorbent article to each other in an alignment direction through a prick punch part. The apparatus includes: a specifying device for specifying a prick punch part as a cutting object corresponding to the predetermined number from the above prick punch part of the continuous body transported taking the alignment direction as a transport direction; and a separating device for separating the connected article formed by connecting the predetermined number of individual packages from the continuous body carried along the transport direction by cutting the prick punch specified by the specifying device.

Description

  The present invention relates to a manufacturing apparatus and a manufacturing method for a connected product of individually packaged articles related to absorbent articles such as disposable diapers.

  Conventionally, when a disposable diaper, a sanitary napkin or the like is purchased at a store, a pack in which a predetermined number of 10 sheets or the like is packed can be purchased as a minimum purchase unit. However, in recent years, sales forms similar to cut-off sales are sometimes taken. That is, at the storefront, for example, 10 individual packages of diapers are displayed in the state of a connected product formed by connecting in a row. In the connected product, the individual packaged products adjacent to each other are connected to each other through a perforated perforated portion. Therefore, the consumer purchases the necessary number of individually packaged products separately from the linked products at the perforated portion.

  An example of an apparatus for manufacturing such a linked product of individually packaged products is disclosed in Patent Document 1. A plurality of diapers are fed into the manufacturing apparatus along the same direction in a state of being aligned in the transport direction. First, when each diaper passes through the wrapping device, a continuous sheet for packaging is joined to each diaper, and each end in the width direction of the same sheet is bent to make the sheet into a cylindrical shape. Thus, each diaper is wrapped in the same sheet. Next, when each diaper wrapped with the cylindrical continuous sheet passes through the center seal device, a joining process is performed on each end in the width direction of the continuous sheet overlapping each other above each diaper. The shape of the continuous sheet is fixed to a cylindrical shape. When passing through the next end seal device, a sealing portion is formed for each part between the diapers in the cylindrical continuous sheet, whereby each diaper is individually accommodated in the continuous sheet. It becomes a state. And when passing through the last cutter apparatus, perforation-like perforations are formed at a ratio of two to three for each of the above-mentioned portions where the sealing portions are formed, and the remaining three In this way, a connected product of so-called three-piece individual packaged products in which three individual packaged products are connected via a perforated portion is manufactured.

  Here, this patent document 1 discloses the following as a specific configuration of the cutter device described above. That is, the cutter device has a rotating member that rotates in conjunction with the conveyance of the continuous sheet that wraps the diaper. And on the outer peripheral surface of this rotating member, three blade members are provided at an equal pitch of 120 ° in the rotation direction, and two of the blade members are a perforating blade that forms a perforated portion in a continuous sheet that wraps the diaper. Then, the remaining one blade member is a cutting blade that cuts a continuous sheet that wraps the diaper into three connected products.

Japanese Patent Laid-Open No. 4-200545

On the other hand, the number of connected items of the individual packaged goods displayed at the store is not limited to the above-described three items, that is, the preferable number of items may vary depending on the individual circumstances of each store. Therefore, if the manufacturing apparatus is configured to be able to change the number of stations, it is convenient to respond to the above-described number of stations.
About this point, in the case of the structure of the above-mentioned cutter apparatus, it is guessed that replacement of the number of stations can be dealt with by replacing the above-mentioned rotating member. That is, since the above-mentioned rotating member is a rotating member for a triple-series product, when a 10-series product is manufactured, it can be dealt with by replacing it with a rotating member for a 10-series product.
However, since the rotating member for the 10-unit product is a large-diameter member having nine perforations and one cutting blade on its outer peripheral surface, the cutter device is increased in size and for each station to be manufactured. Each must have its own rotating member, which increases the equipment cost. In addition, every time the number of stations is changed, the rotating member needs to be replaced, which causes a reduction in the operating rate of the production line. Therefore, the above-described cutter device cannot easily cope with the change of the station number.

  The present invention has been made in view of the above-described conventional problems, and an object thereof is to make it possible to easily cope with the renumbering of linked products of individual packaged products.

The main invention for achieving the above object is:
A predetermined number of the individual packaged products are connected from a continuous body of individual packaged products formed by connecting a plurality of individual packaged products in which absorbent articles are individually accommodated in a lined-up state through a perforated portion. An apparatus for manufacturing the connected product by separating the connected product of the individually packaged product,
From the perforations of the continuum that is conveyed with the alignment direction as the transport direction, a specifying device that identifies perforations to be cut corresponding to the predetermined number;
A disconnecting device for disconnecting the connected product in which the predetermined number of individually packaged products are connected from the continuous body transported along the transport direction by cutting the perforated portion specified by the specifying device; The manufacturing apparatus of the connection product of the individual package goods which concern on an absorbent article characterized by having.

Also,
A predetermined number of the individual packaged products are connected from a continuous body of individual packaged products formed by connecting a plurality of individual packaged products in which absorbent articles are individually accommodated in a lined-up state through a perforated portion. A method of manufacturing the connected product by separating the connected product of the individually packaged product,
Identifying the perforations to be cut corresponding to the predetermined number from the perforations of the continuum that is transported with the alignment direction as the transport direction;
Severing the identified perforated portion to separate the connected product in which the predetermined number of individually packaged products are connected from the continuous body transported along the transport direction. It is the manufacturing method of the connection goods of the individual package item which concerns on the characteristic absorbent article.

  Other features of the present invention will become apparent from the description of the present specification and the accompanying drawings.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to cope easily with the serial number change of the linked product of an individual package product.

1A is a schematic top view of the connection product 11a, FIG. 1B is a view taken along the line BB in FIG. 1A, and FIG. 1C is a view taken along the line CC in FIG. 1A. It is a schematic side view of a packaging line. 2 is a schematic side view of an end seal and perforation device 50. FIG. 3 is a schematic side view of an inspection conveyor 70. FIG. It is explanatory drawing of the 1st test | inspection apparatus 74. FIG. It is explanatory drawing of the 2nd test | inspection apparatus 84. FIG. 7A to 7C are schematic side views of other embodiments of the detaching device 60.

At least the following matters will become apparent from the description of the present specification and the accompanying drawings.
A predetermined number of the individual packaged products are connected from a continuous body of individual packaged products formed by connecting a plurality of individual packaged products in which absorbent articles are individually accommodated in a lined-up state through a perforated portion. An apparatus for manufacturing the connected product by separating the connected product of the individually packaged product,
From the perforations of the continuum that is conveyed with the alignment direction as the transport direction, a specifying device that identifies perforations to be cut corresponding to the predetermined number;
A disconnecting device for disconnecting the connected product in which the predetermined number of individually packaged products are connected from the continuous body transported along the transport direction by cutting the perforated portion specified by the specifying device; The manufacturing apparatus of the connection product of the individual package goods which concerns on an absorbent article characterized by having.

According to the manufacturing apparatus of the linked product of the individually packaged product related to such an absorbent article, by specifying and cutting the perforated portion corresponding to the predetermined number that is the number of the individually packaged product that the linked product should have, A connected product in which the predetermined number of individual packaged products are connected can be separated from a continuous body of individual packaged products. And it is possible to change the consecutive number by changing the predetermined number. Therefore, it becomes possible to easily cope with the station number change.
In addition, since the connected product is separated from the continuous body by cutting the perforated portion, it is not necessary to use a blade member as a separating device. Therefore, it is not necessary to perform maintenance work accompanying wear of the blade member, and labor can be reduced.

An apparatus for manufacturing a linked product of individually packaged products relating to such an absorbent article,
It is desirable that the separation device cuts the perforation portion by pulling the perforation portion in the transport direction when the identified perforation portion passes through the separation device.
According to the manufacturing apparatus of the connected product of the individual packaged goods which concerns on such an absorbent article, the cutting | disconnection apparatus cut | disconnects the perforation part specified as a perforation part to be cut | disconnected in a conveyance direction. Therefore, the perforated portion can be reliably cut.

An apparatus for manufacturing a linked product of individually packaged products relating to such an absorbent article,
The specific device includes an input unit that inputs information relating to the predetermined number, and a memory that updates and records the predetermined number based on the information input from the input unit,
It is preferable that the specifying device specifies the perforation portion to be cut corresponding to the predetermined number recorded in the memory, and causes the separation device to cut the identified perforation portion.
According to such an apparatus for manufacturing a linked product of individually packaged articles related to absorbent articles, the predetermined number can be easily changed by inputting information on the predetermined number from the input unit. Therefore, the number of stations can be changed easily.

An apparatus for manufacturing a linked product of individually packaged products relating to such an absorbent article,
The separating apparatus has a pair of nip roll mechanisms having a pair of rolls that rotate while sandwiching the continuous body from the thickness direction of the continuous body, aligned in the transport direction,
When the perforated portion to be cut passes between the pair of nip roll mechanisms, the conveyance speed value of the continuous body in the downstream nip roll mechanism of the pair of nip roll mechanisms, and the upstream nip roll mechanism It is preferable that the perforated portion is pulled and cut in the transport direction by increasing the difference from the transport speed value of the continuum.
According to the manufacturing apparatus of the connected product of the individually packaged product according to such an absorbent article, when the perforated portion to be cut passes between the pair of nip roll mechanisms, the continuous body of the downstream nip roll mechanism is The perforated portion to be cut is cut by increasing the difference between the conveyance speed value and the conveyance speed value of the continuous body in the upstream nip roll mechanism. Therefore, it is possible to reliably cut only the perforated portion to be cut among the plurality of perforated portions.

An apparatus for manufacturing a linked product of individually packaged products relating to such an absorbent article,
It is preferable that the distance between the pair of nip roll mechanisms is set so that the number of perforations existing between the pair of nip roll mechanisms is always one or less.
According to the manufacturing apparatus of the connected product of the individually packaged product relating to such an absorbent article, since the number of perforations existing between the pair of nip roll mechanisms is always one or less, the pair of nip roll mechanisms When the perforated portion to be cut passes between them, only the perforated portion can be reliably cut.

An apparatus for manufacturing a linked product of individually packaged products relating to such an absorbent article,
Except when cutting the perforated portion to be cut, when the transport speed value of the continuous body and the connected product transported by the cutting device is a first speed value,
On the downstream side in the transport direction with respect to the separation device, there is a downstream transport device that transports the continuous body and the connected product at a transport speed value faster than the first speed value,
It is desirable to have a first inspection device that inspects the overall length dimension of the connected product in the transport direction during or after the transport of the connected product by the downstream transport device.
According to the manufacturing apparatus of the connected product of the individually packaged product according to such an absorbent article, the continuous material and the connected product are the first while the continuous material and the connected product are transferred from the separating device to the downstream transport device. The speed is accelerated from the speed value to the transport speed value of the downstream transport device. In this case, the individual packages of the continuous body and the connected product are generally based on the difference between the transport speed value and the first speed value. Is pulled in the conveying direction to remove slack and wrinkles. Therefore, the inspection of the overall length of the connected product can be performed in a state in which the slackness of the connected product is removed, and the inspection can be accurately performed.

An apparatus for manufacturing a linked product of individually packaged products relating to such an absorbent article,
It is desirable to have a second inspection device for inspecting the presence or absence of a perforated portion cut out of the perforated portions to be included in the connected product during conveyance of the connected product.
According to such an apparatus for manufacturing a connected product of individually packaged products relating to absorbent articles, unintentional cutting of the perforated portion of the connected product can be reliably detected.

An apparatus for manufacturing a linked product of individually packaged products relating to such an absorbent article,
At a position upstream of the separating device in the transport direction,
A wrapping device for wrapping a plurality of the absorbent articles conveyed in the conveying direction in a state aligned in the conveying direction with a continuous sheet for packaging conveyed in the conveying direction;
A pair of sealing parts are formed in each part between the absorbent articles in the continuous sheet to individually accommodate the absorbent article, and at a position between the pair of sealing parts in each part. A continuous body generating device that generates a continuous body of the individually packaged product by forming the perforated portion;
The continuous body generating device has a pair of roll-shaped members that rotate in conjunction with the conveying operation of the continuous sheet while facing an outer peripheral surface of the continuous sheet.
On the outer peripheral surface of at least one of the pair of roll-shaped members, a pair of pressing portions that press the pair of sealing portions on the continuous sheet is provided,
A blade member that presses and forms the perforated portion on the continuous sheet is provided on the outer peripheral surface of at least one of the pair of roll-shaped members,
When processing the perforated portion, it is desirable that the blade member is located at a position between the pair of pressing portions.

According to the manufacturing apparatus of the connected product of the individually packaged product according to such an absorbent article, by passing through the roll gap between the pair of roll-shaped members included in the continuous body generating device, the pair of sealing portions and The perforated portion can be formed almost simultaneously. Therefore, the relative positional relationship between the formation position of the sealing portion and the formation position of the perforated portion in the continuous sheet can be maintained almost always constant. As a result, problems that tend to occur when the device that operates the pressing portion and the device that operates the blade member are separate devices, such as a problem of fluctuations in the relative positional relationship that may occur due to poor synchronization between these devices. Etc. can be avoided reliably.
Also,
A predetermined number of the individual packaged products are connected from a continuous body of individual packaged products formed by connecting a plurality of individual packaged products in which absorbent articles are individually accommodated in a lined-up state through a perforated portion. A method of manufacturing the connected product by separating the connected product of the individually packaged product,
Identifying the perforations to be cut corresponding to the predetermined number from the perforations of the continuum that is transported with the alignment direction as the transport direction;
Severing the identified perforated portion to separate the connected product in which the predetermined number of individually packaged products are connected from the continuous body transported along the transport direction. A method for producing a linked product of individually packaged products relating to an absorbent article.

According to the manufacturing method of the linked product of the individually packaged product relating to such an absorbent article, by specifying and cutting the perforated portion corresponding to the predetermined number that is the number of the individually packaged product that the linked product should have, A connected product in which the predetermined number of individual packaged products are connected can be separated from a continuous body of individual packaged products. And it is possible to change the consecutive number by changing the predetermined number. Therefore, it becomes possible to easily cope with the station number change.
In addition, since the connected product is separated from the continuous body by cutting the perforated portion, it is not necessary to use a blade member as a separating device. Therefore, it is not necessary to perform maintenance work accompanying wear of the blade member, and labor can be reduced.

=== This Embodiment ===
The manufacturing apparatus of this embodiment is an apparatus which manufactures the connection goods 11a of the individual package goods 11,11 ... which concern on the disposable diaper 1 as an example of an absorbent article. FIG. 1A shows a schematic top view of the connecting article 11a, FIG. 1B shows a view taken along the line BB in FIG. 1A, and FIG. 1C shows a view taken along the line CC in FIG. 1A. ing. In FIG. 1A, a partially enlarged view is also shown.

  As shown in FIG. 1A, the connected product 11a of the individually packaged products 11, 11... Is a plurality of individually packaged products 11, 11. Is. In the example of FIG. 1A, a so-called ten-line product in which ten individual packages 11, 11,... Are continuously arranged in a row is shown as an example.

  Specifically, the connected product 11a in FIG. 1A is long and flexible with a length corresponding to, for example, 10 diapers 1, 1... Corresponding to the number of stations, and a length corresponding to, for example, 10 stations. Packaging sheet 12a. On the packaging sheet 12a, ten diapers 1, 1,... Are placed in a line with the longitudinal direction of the packaging sheet 12a as the alignment direction in a state of being spaced apart from each other. Moreover, each edge part 12ae and 12ae of the width direction of the packaging sheet 12a are piled up on each diaper 1, and the packaging sheet 12a was made into the cylinder shape, and each these edge parts 12ae and 12ae heat By joining with a seal | sticker etc., the shape of the packaging sheet 12a is being fixed to the cylinder shape. Further, a bonding process such as heat sealing is also applied to each portion 12ab between the diapers 1 and 1 of the cylindrical packaging sheet 12a to form a pair of sealing portions 12as and 12as. And each diaper 1 is separately accommodated in the bag-shaped space divided by the said sealing part 12as, and, thereby, the connection goods 11a of the individual package goods 11,11 ... are substantially formed. In each portion 12ab where the pair of sealing portions 12as and 12as are formed, a perforated perforated portion 12ac is also formed at a position between the pair of sealing portions 12as and 12as. And it can be separated for each individual packaged article 11 at the perforated part 12ac. As the material of the packaging sheet 12a, a nonwoven fabric or a resin film mainly composed of resin fibers is used.

  Such a connected product 11a is manufactured in a packaging line. FIG. 2 shows a schematic side view of the packaging line. In the packaging line, a wrapping device 30, a center seal device 40, an end seal and perforation device 50, a separating device 60, and an inspection conveyor 70 are arranged side by side along the transport direction. A transport device such as a belt conveyor CV or a transport roller may be provided adjacent to the upstream side or the downstream side of these devices 30, 40, 50, 60, 70. In the example of FIG. 2, the belt conveyor CV is located immediately upstream of the wrapping device 30, between the center seal device 40 and the end seal and perforation device 50, and between the end seal and perforation device 50 and the separation device 60. These belt conveyors CV are provided for conveying the diaper 1 and the continuous body 12aa of the packaging sheet 12a.

  A plurality of diapers 1, 1... Are fed into the packaging line from the production line of the upper process diaper 1 in a state of being aligned in a line along the transport direction. Each diaper 1 is transported at a predetermined alignment pitch P in the same direction with a space between the diapers 1 and 1 adjacent in the transport direction.

  And when each said diaper 1 passes the predetermined position P1 of a conveyance direction, the continuous body 12aa (henceforth continuous sheet 12aa) of the packaging sheet 12a merges from the downward | lower direction, for example. Each of the diapers 1, 1... Is transported integrally with the continuous sheet 12aa along the transport direction while being placed on the continuous sheet 12aa.

  Then, each diaper 1 placed on the continuous sheet 12aa passes through the wrapping device 30. In this case, the device 30 causes the end portions 12aae and 12aae in the width direction of the continuous sheet 12aa to move upward. While the sheet 12aa is bent into a cylindrical shape, the end portions 12aae and 12aae are overlapped with each other, whereby each of the diapers 1, 1... Is wrapped in the cylindrical sheet 12aa.

  Next, each diaper 1, 1... Wrapped in the cylindrical continuous sheet 12aa passes through the center seal device 40. At that time, the device 40 causes the end portions 12aae and 12aae of the continuous sheet 12aa to be passed. Bonding processing is performed to each other, and thereby the shape of the continuous sheet 12aa is fixed to a cylindrical shape. In this example, heat sealing is applied as the joining process of the end portions 12aae and 12aae, but the present invention is not limited to this, and bonding with an adhesive may be used.

  Then, the end seal and perforation device 50 passes, and in that case, the device 50 causes a pair of sealing portions 12as, a pair of diapers 1 and 1 between the diapers 1 and 1 in the cylindrical continuous sheet 12aa to be formed. 12as is formed, and a perforated perforated portion 12ac is also formed at a portion between the pair of sealing portions 12as and 12as in each portion 12aab. Thereby, each diaper 1 will be in the state which can be cut | disconnected by the unit separately accommodated in continuous sheet | seat 12aa. That is, a continuous body 11aa of the individually packaged products 11, 11... Formed by connecting the individually packaged products 11, 11. In this example, heat sealing is applied as the forming process of the sealing portion 12as. However, the present invention is not limited to this, and bonding with an adhesive may be used.

  Next, the continuous body 11aa of the individually packaged products 11, 11... Passes through the separating device 60. In this case, the continuous body 11aa has a series of 10 parts from among the plurality of perforated portions 12ac, 12ac. The perforated part 12ac to be cut corresponding to the target station number (manufactured station number) to be manufactured is specified, and only the specified perforated part 12ac is selectively cut, thereby the target station number ( In this example, 10 linked individual packaged articles 11, 11,...

  If it does so, finally the said connection goods 11a will pass the test | inspection conveyor 70, However, The inspection of the full length dimension L11a is made | formed with respect to the connection goods 11a in that case. Then, according to the inspection result, the connected product 11a is distributed to the regular conveyance path Tg for non-defective products or the discharge path Tb for defective products. As a result, only the non-defective connected product 11a is sent to the shipping process in the lower process through the regular transport path Tg. Incidentally, the reason why the inspection of the overall length L11a is necessary is that the connected product 11a has perforations 12ac, 12ac,..., And is unintentionally cut by the perforations 12ac due to the transport tension acting during transport. This is because there is a risk of losing.

  Hereinafter, each apparatus 30,40,50,60,70 of the packaging line which is a manufacturing apparatus of this embodiment is demonstrated. In the following description, the conveyance direction of the continuous body 11aa of the individually packaged products 11, 11... And the connected product 11a of the individually packaged products 11, 11. The width direction is also called “CD direction”. Incidentally, the longitudinal direction of the connected product 11a, the width direction of the connected product 11a, and the thickness direction of the connected product 11a are orthogonal to each other. Therefore, the MD direction, the CD direction, and the thickness direction are also orthogonal to each other.

  In FIG. 2, the MD direction is an arbitrary direction parallel to the paper surface. That is, as shown in FIG. 2, when two directions orthogonal to each other in the plane of the page are defined as a vertical direction and a front-back direction, an arbitrary direction defined by these two directions is the MD direction. In addition, the up-down direction faces the vertical direction, and the front-back direction faces the horizontal direction. Further, the CD direction is the direction penetrating the paper surface of FIG. 2, and in this example, the CD direction is the horizontal direction.

  The wrapping device 30 is a known device 30. That is, as shown in FIG. 2, the continuous sheet 12aa on which the diaper 1 is placed is conveyed along the MD direction, and is arranged on both sides in the CD direction while facing the conveying surface of the belt conveyor 32. A pair of guide plates 34a and 34b. When the continuous sheet 12aa conveyed by the conveying surface of the belt conveyor 32 passes through the positions of the guide plates 34a and 34b, the respective guide plates 34a and 34b respectively correspond to the corresponding end portions 12aae and 12aae of the continuous sheet 12aa. 12aae is bent toward the center in the CD direction, and the respective end portions 12aae and 12aae are overlapped on the upper side of the diaper 1, whereby the continuous sheet 12aa is formed into a cylindrical shape so that the diaper 1 is wrapped. .

  The center seal device 40 has a heating unit 42 heated to a predetermined temperature. Then, when the continuous sheet 12aa in the state of wrapping the diaper 1 in a cylindrical shape passes through the position of the heating unit 42, the heating unit 42 is placed between the end portions 12aae and 12aae of the stacked continuous sheets 12aa. For example, the end portions 12aae and 12aae are brought into contact with each other from above and heated and melted to join the end portions 12aae and 12aae. And thereby, the shape of continuous sheet 12aa is fixed to a cylinder shape.

  FIG. 3 shows a schematic side view of the end seal and perforation device 50. As described above, the device 50 (corresponding to a continuous body generating device) is a device that forms a pair of sealing portions 12as and 12as and a perforated portion 12ac simultaneously on a cylindrical continuous sheet 12aa. A pair of upper and lower rolls 51u, 51d (corresponding to a roll-shaped member) having processing portions 52u, 52d for forming the sealing portions 12as, 12as and the perforated portion 12ac on the outer peripheral surface are used as the main body. That is, in the upper processing portion 52u of the upper roll 51u, a pair of sealing portion convex portions 53us, 53us (corresponding to a pressing portion) for forming the pair of sealing portions 12as, 12as on the continuous sheet 12aa, Both the perforation blade 53uc (corresponding to the blade member) for forming the perforation portion 12ac on the sheet 12aa are provided close to each other, and the lower processing portion 52d of the lower roll 51d is provided with the pair of sealing members. A pair of receiving portions 53ds, 53ds for receiving the stopper convex portions 53us, 53us and a receiving blade 53dc for receiving the perforating blade 53uc are provided close to each other. The upper and lower rolls 51u and 51d are driven and rotated in synchronization with the conveying operation of the continuous sheet 12aa by a servo motor (not shown) as a drive source. Therefore, when each portion 12aab between the diapers 1 and 1 in the continuous sheet 12aa passes through the gap G51 between the upper and lower rolls 51u and 51d, the upper processing portion 52u and the lower processing portion 52d face each other. A pair of sealing portions 12as and 12as and a perforated portion 12ac are formed in each portion 12aab. And thereby, each diaper 1 is made into the state which can be cut | disconnected by the said unit accommodated individually, accommodated in continuous sheet | seat 12aa. In other words, a continuous body 11aa of the individual packaged articles 11, 11,... Formed by connecting the individual packaged articles 11 in a state of being arranged in the MD direction is thus formed.

  The upper processing portion 52u and the lower processing portion 52d may be provided one by one for the upper roll 51u and the lower roll 51d, but in this example, four processings are provided as a plurality of examples, respectively, in order to increase the production speed. .., 52d, 52d,... Are provided. Therefore, in this example, each time the upper roll 51u and the lower roll 51d make one rotation, a pair of sealing portions 12as and 12as and a perforated portion 12ac are formed at four locations of the continuous sheet 12aa. That is, for each rotation of the upper and lower rolls 51u, 51d, four individual packages 11, 11,.

  Incidentally, the arc distance D52u on the orbit between the upper processing parts 52u and 52u adjacent in the rotation direction and the arc distance D52d on the orbit between the lower processing parts 52d and 52d adjacent in the rotation direction are: Each is set to be approximately equal to the alignment pitch P in the MD direction of the diapers 1 in the continuous sheet 12aa. Therefore, in this apparatus 50, the continuous sheet is rotated by rotating the upper and lower rolls 51u and 51d around the upper processing portion 52u and the lower processing portion 52d at a circumferential speed value V52 that is substantially the same as the conveyance speed value V12aa of the continuous sheet 12aa. The pair of sealing portions 12as and 12as and the perforated portion 12ac can be formed corresponding to each portion 12aab between the diapers 1 and 1 on the 12aa, and as a result, the conveyance speed value V12aa and the peripheral speed during processing. The formation of the pair of sealing portions 12as, 12as and the perforated portion 12ac due to a relative difference from the value V52 is effectively prevented from becoming unstable.

  Further, the upper and lower rolls 51u and 51d are rotated in synchronization with the conveying operation of the continuous sheet 12aa by a synchronization signal. That is, in this packaging line, a synchronization signal (for example, a rotation angle signal of 0 to 360 °) is generated with one cycle corresponding to the transport operation corresponding to one individual packaged product 11, and the belt is based on this synchronization signal. In general, all the devices 30, 40, 50, 60, and 70 including the conveyor device such as the conveyor CV are controlled to operate. This is not an exception for the upper and lower rolls 51u and 51d, and the position of the servo motors of the upper and lower rolls 51u and 51d is controlled based on the synchronization signal, thereby synchronizing with the conveying operation of the continuous sheet 12aa. Is realized. For example, as described above, in this example, the upper and lower rolls 51u, 51d have four processing portions 52u, 52u,..., 52d, 52d, respectively, so that one-quarter rotation per cycle of the synchronization signal. Thus, the position of each servomotor is controlled so that a pair of sealing portions 12as and 12as and a perforated portion 12ac are formed in each portion 12aab between the diapers 1 and 1 in the continuous sheet 12aa. ing.

  The separating device 60 corresponds to the target number of stations (the number of stations in the manufacturing specification of the connected product) to be manufactured, such as 10 stations, from among the plurality of perforated portions 12ac, 12ac... Then, only the perforated portion 12ac to be identified is cut, and the connected product 11a formed by connecting the individual packaged products 11, 11... As a device to manufacture as.

  In this example, the apparatus 60 includes a pair of nip roll mechanisms 62 and 64 arranged side by side in the MD direction. Each nip roll mechanism 62, 64 has a pair of upper and lower nip rolls 62u, 62d, 64u, 64d that are driven and rotated about rotation axes C62, C64 along the CD direction. In other words, the upstream nip roll mechanism 62 positioned on the upstream side sandwiches the continuum 11aa from the thickness direction on the outer peripheral surface, while driving and rotating the pair of nip rolls 62u so as to feed the continuum 11aa downstream in the MD direction. 62d, and the downstream nip roll mechanism 64 located downstream of the upstream nip roll mechanism 62 also holds the continuum 11aa in the MD direction while slightly sandwiching the continuum 11aa from the outer peripheral surface from the thickness direction. It has a pair of upper and lower nip rolls 64u and 64d that are driven and rotated so as to be sent downstream.

  The nip rolls 62u, 62d, 64u, and 64d of the upstream nip roll mechanism 62 and the downstream nip roll mechanism 64 are driven and rotated by a servo motor as a drive source, and the peripheral speed values V62 and V64 are substantially continuous. It is controlled so as to be aligned with the conveyance speed value V11aa of the body 11aa. For example, when the conveyance speed value of the continuous body 11aa is V1, the peripheral speed value V62 of the upstream nip roll mechanism 62 is set to V1 as a steady speed value, and the peripheral speed value V64 of the downstream nip roll mechanism 64 is The steady speed value (corresponding to the first speed value) is set to V1 to 1.06V1.

  However, when the controller 66 described later detects that the perforated portion 12ac has reached between the upstream nip roll mechanism 62 and the downstream nip roll mechanism 64, only the peripheral speed value V64 of the downstream nip roll mechanism 64 is detected. Is instantaneously increased from the steady speed value to return to the steady speed value. For example, the peripheral speed value V62 of the upstream nip roll mechanism 62 is maintained at the steady speed value V1, but the peripheral speed value V64 of the downstream nip roll mechanism 64 is increased to a speed value of 2.95V1, and the increase is made. After the speed, it is immediately returned to the above-mentioned steady speed value V1 to 1.06V1.

  As a result, the transport speed value V11aa of the continuum 11aa in the upstream nip roll mechanism 62 is maintained substantially at the steady speed value V1 of the peripheral speed value V62, but the transport speed value V11aa in the downstream nip roll mechanism 64 is The peripheral speed value V64 is instantaneously increased to 2.95V1 instantaneously. As a result, the perforated portion 12ac to be cut is pulled in the MD direction by the upstream nip roll mechanism 62 and the downstream nip roll mechanism 64. Only the perforated portion 12ac is selectively cut. As a result, the connected product 11a having the individual packaged products 11, 11,... Corresponding to the target number is separated from the continuous body 11aa and manufactured.

  The period during which the above-described peripheral speed value V64 is increased from the steady speed value is defined by the conveyance amount in the MD direction of the continuous body 11aa. For example, the conveyance amount during the above-described speed-up period is set to an arbitrary value that is equal to or less than the length in the MD direction of one individual packaged article 11 at the time of separation, and preferably the length of one individual packaged article 11 It is preferable to set the length to 10% to 30%.

  Further, the appropriate value of the peripheral speed value V64 at the time of acceleration can be changed according to the cutting strength of the perforated portion 12ac. Therefore, the peripheral speed value V64 at the time of acceleration is determined by repeating experiments and trial operations as appropriate in consideration of the specifications of the perforated portion 12ac and the like. Therefore, it is not limited to 2.95V that is the value of the exemplified peripheral speed value V64.

  Further, in this example, the distance D60 in the MD direction between the pair of nip roll mechanisms 62, 64 is such that the number of perforated portions 12ac existing in the distance D60 is always one or less. Is set. For example, it is set to a value smaller than the alignment pitch P of the diapers 1 that is the overall length dimension of the individual packaged product 11 in the alignment direction. Therefore, when the perforated portion 12ac to be cut passes between the pair of nip roll mechanisms 62 and 64, the perforated portions 12ac and 12ac adjacent to the upstream and downstream of the perforated portion 12ac are not cut. Only the perforated portion 12ac to be cut can be reliably selected and cut.

  By the way, the identification of the perforated portion 12ac to be cut corresponding to the target station number, that is, the detection that the perforated portion 12ac to be cut enters between the upstream nip roll mechanism 62 and the downstream nip roll mechanism 64 is separated. This is done by a controller 66 that controls the device 60.

  Here, the controller 66 (corresponding to a specific device) is a so-called computer or PLC (programmable logic controller), and has a processor and a memory. The controller 66 receives the above-described synchronization signal. The memory stores a counter-and-comparison program that counts the cycle of the synchronization signal and compares the count value with a predetermined value recorded in the memory. Further, a numerical value of the target station number is recorded as the predetermined value in the memory.

  Therefore, the processor reads the counter-and-comparison program from the memory and executes it to count the cycle of the synchronization signal, and each time the count value increases, the count value is the numerical value of the target station number recorded in the memory. Compare with When the count value matches the numerical value of the target station number, the controller 66 determines that the perforated portion 12ac to be cut has entered between the upstream nip roll mechanism 62 and the downstream nip roll mechanism 64. The controller 66 instantaneously increases the speed of the servo motor of the downstream nip roll mechanism 64 to cut the perforated portion 12ac. If the controller 66 controls the separation device 60 in this way, the separation processing is accelerated once and the separation processing is performed every time the number of individual packaged articles 11, 11. As a result, the connected product 11a in which the individually packaged products 11, 11... Are connected by the target number is separated from the continuous body 11aa and manufactured. Incidentally, at the same time when the count value reaches the numerical value of the target station number, the counter value is reset to zero, and the counter-and-comparison program is set up so as to prepare for the counting of the next station number.

  It should be noted that, instead of the synchronization signal, the rotation signal of the rotary encoder built in the servo motors of the upper and lower rolls 51u and 51d of the end seal and perforation device 50, or the rotary encoder additionally installed on the rolls 51u and 51d. The perforated portion 12ac to be cut may be specified by inputting the rotation signal to the controller 66 and counting as described above.

  Desirably, the controller 66 has an input unit (not shown) such as a keyboard and a mouse, and can update the predetermined value in the memory based on information on the target station number input from the input unit. It is good to be configured. For example, when a numerical value of the target station number is directly input as information related to the target station number from the input unit, the predetermined value in the memory may be updated to the input numerical value. And if it is comprised in this way, it will become possible to change a target station number easily, and it will become possible to cope with change of station number of the connection goods 11a of the individually packaged goods 11,11 ... still more easily. . However, the information related to the target station number is not limited to the numerical value of the target station number. For example, when the target station number is selected from an appropriate selection screen displayed on the monitor attached to the controller 66, the information input by the selection operation using the input unit is the above-described information. Corresponds to information related to the target number of stations. In this case, the controller 66 rewrites the predetermined value in the memory to the numerical value of the target station number corresponding to this information.

  More preferably, as shown in FIG. 3, a separation confirmation sensor for confirming whether or not the perforated portion 12ac to be cut is separated at a position between the upstream nip roll mechanism 62 and the downstream nip roll mechanism 64. 68 may be provided. In this example, the gaze point of the separation confirmation sensor 68, that is, the monitoring target position in the MD direction, is a position downstream in the MD direction from the position where the perforated portion 12ac to be cut is conveyed when the speed increase command is output. Is set. Therefore, from the time when the speed increase command is output from the controller 66 to the servo motor, the waveform of the signal output from the separation confirmation sensor 68 until the elapse of a predetermined time from there is cut off the perforated portion 12ac. If there is no change corresponding to the gap generated by the controller 66, the controller 66 determines that the perforated portion 12ac to be cut is not cut, and gives a “cutting failure” alarm to the monitor of the controller 66, etc. To an output unit (not shown). The predetermined time is appropriately set by experiment or the like. Further, as the separation confirmation sensor 68, for example, a phototube is used, but the present invention is not limited to this. For example, an appropriate sensor such as a laser sensor is also applicable.

  FIG. 4 shows a schematic side view of the inspection conveyor 70. In the inspection conveyor 70, it is inspected whether or not the total length L11a of the connected product 11a separated from the continuous body 11aa by the separating device 60 is within an assumed length range for the connected product 11a having the target number of stations. To do. When the inspection result of the overall length L11a is longer than the upper limit value Lmax of the assumed length range, it is cut off at any perforated portion 12ac included in the connected product 11a, or the connected product 11a is provided. Empty that has not been accommodated in the diaper 1 in any one of the individually packaged products 11, 11. There is a possibility of any one of these three states. Therefore, the connected product 11a is discharged from the discharge route Tb as a defective product. On the other hand, when the inspection result of the overall length L11a is shorter than the lower limit value Lmin of the assumed length range, there is a possibility that the connected product 11a does not have the individual packaged products 11, 11,. Thus, for example, when the target number of stations is 10, there is a possibility that the number of stations is insufficient such as a 9-series product or an 8-series product. Therefore, the connected product 11a is also discharged from the discharge path Tb as a defective product.

  By the way, when there is an empty individual package 11 in which the diaper 1 is not accommodated, the reason why the total length L11a of the connected product 11a is longer than the upper limit value Lmax of the above-mentioned assumed length range is the empty individual package This is because the product 11 is thinner than the individually packaged product 11 in which the diaper 1 is correctly accommodated, and the entire length is extended by the thickness of the product.

  The inspection conveyor 70 includes a belt conveyor 71 provided immediately downstream of the separation device 60, a first inspection device 74 that inspects the overall length L 11 a of the connected product 11 a that the belt conveyor 71 conveys, and a first inspection device 74. There is a distribution mechanism 75 that distributes the connected product 11a to the regular conveyance path Tg for the non-defective product or the discharge path Tb for the defective product based on the quality determination result that is the inspection result.

  The belt conveyor 71 (corresponding to the downstream transport device) has a pair of upper and lower endless belts 71u and 71d, and a transport path for the connected product 11a or the continuous body 11aa is formed between the endless belts 71u and 71d. Has been. Specifically, the upper endless belt 71u is wound around a pair of rollers 72u and 72u arranged in the MD direction, and the lower endless belt 71d is also hung around a pair of rollers 72d and 72d arranged in the MD direction. ing. Then, with the upper endless belt 71u and the lower endless belt 71d, the endless belts 71u and 71d drive and circulate in conjunction with each other in a state where the connected product 11a or the continuous body 11aa is sandwiched from above and below in the thickness direction. The connected product 11a or the continuous body 11aa is conveyed downstream in the MD direction. Note that the driving orbiting operation of the upper and lower endless belts 71u and 71d is performed by driving and rotating the rollers 72u and 72d by, for example, a servo motor (not shown) as a driving source.

  Here, the overall length L71 of the conveying path of the belt conveyor 71 is set sufficiently longer than the upper limit value Lmax of the assumed length range of the overall length L11a of the connected product 11a. Further, the circumferential speed value V71 of the endless belts 71u and 71d, that is, the transport speed values V11a and V11aa of the connected article 11a and the continuous body 11aa by the belt conveyor 71 are the peripheral speeds corresponding to the transport speed values V11a and V11aa in the separating device 60. It is set to a value larger than the steady speed value V1 of the value V62 and the steady speed values V1 to 1.06V1 of the peripheral speed value V64. In this example, for example, 1.65V1 is set as the steady speed value. Therefore, a predetermined gap G11a is formed between the connected product 11a and the adjacent connected product 11a upstream thereof while being transported along the transport path of the belt conveyor 71, and thereby the connected product 11a. Is a defective product, the time required for the defective product discharge processing from the discharge path Tb is secured.

  Further, when the individual packaged articles 11, 11... Are transferred from the downstream nip roll mechanism 64 to the belt conveyor 71 in the state of the continuous body 11aa, the peripheral speed value V64 of the downstream nip roll mechanism 64 is steady. Based on the difference between the speed values V1 to 1.06V1 and the steady speed value 1.65V1 of the circumferential speed value V71 of the belt conveyor 71, each individual package 11, 11,... Is almost removed. Therefore, the inspection of the overall length L11a of the connected product 11a can be accurately performed.

  As shown in the schematic side view of FIG. 5, the first inspection device 74 includes inspection sensors 74 s 1, 74 s 2, 74 s 3 and inspection sensors 74 s 1, 74 s 2, which are installed at predetermined positions on the conveyance path of the belt conveyor 71. 74s3 has a controller 74c for determining whether the overall length L11a of the connected product 11a of the individually packaged products 11, 11,...

  Three sensors are installed as the inspection sensors 74s1, 74s2, and 74s3. The first sensor 74s1 is provided with a predetermined position in the downstream portion of the conveyance path of the belt conveyor 71 as a monitoring target position P74s1 (hereinafter also referred to as a first monitoring target position P74s1). And when the downstream end 11aed of the connection article 11a passes through the first monitoring target position P74s1, the passage is detected.

  On the other hand, the second sensor 74s2 is a lower limit value charge sensor provided in correspondence with the lower limit value Lmin of the assumed length range described above. Therefore, the monitoring target position P74s2 of the second sensor 74s2 (hereinafter also referred to as the second monitoring target position P74s2) is basically the position where the downstream end 11aed of the non-defective connected product 11a is located at the first monitoring target position P74s1. In this case, the uppermost individual packaged product 11 of the connected product 11a is set at a theoretical position where it should theoretically be located. Here, the theoretical position has a range, and the range is, for example, from the position of the downstream end 11ed of the uppermost individual packaged product 11 to the position of the upstream end 11eu. In the example of FIG. 5, the second monitoring target position P74s2 is set to the lower limit value in the theoretical position, that is, the position of the downstream end 11ed of the most upstream individual packaged product 11.

  The third sensor 74s3 is an upper limit value sensor provided corresponding to the upper limit value Lmax of the assumed length range of the connected product 11a. Therefore, the monitoring target position P74s3 of the third sensor 74s3 (hereinafter also referred to as the third monitoring target position P74s3) is the same as that when the downstream end 11aed of the non-defective connected product 11a is located at the first monitoring target position P74s1. The upstream end 11aeu of the connected product 11a is set at a position upstream from the theoretical position that should theoretically be located by an assumed variation such as a dimensional tolerance. For example, in this example, the assumed variation is set to a predetermined value E selected from the range of 0.1 to 0.2 pieces of the individually packaged product 11, and thereby the third monitoring target position P74s3 is The position is set upstream by the predetermined value E from the theoretical position.

  On the belt conveyor 71, the connected product 11a is slightly extended in the MD direction by an action such as conveyance tension. Therefore, the theoretical position is slightly shifted to the upstream side from the position determined by both the first monitoring target position P74s1 and the design value of the overall length 11a which is the natural length of the connected product 11a. Therefore, such a theoretical position is obtained by, for example, an experimental method. That is, the connected product 11a is actually conveyed on the belt conveyor 71, and the position of the uppermost individual packaged product 11 when the first detection sensor 74s1 detects the downstream end 11aed of the connected product 11a is measured a plurality of times. The theoretical position is obtained.

  The controller 74c is, for example, a computer or a PLC, and output signals are input from the first, second, and third sensors 74s1, 74s2, and 74s3, respectively.

  And according to the inspection device 74 having such a configuration, the inspection of the overall length L11a of the connected product 11a is performed as follows. First, the connected product 11 a separated from the continuous body 11 aa by the separating device 60 is conveyed downstream by the belt conveyor 71. When the downstream end 11aed of the connected product 11a passes through the first monitoring target position P74s1 during conveyance by the belt conveyor 71, a signal indicating that the passage has been detected is received from the first sensor 74s1 that has detected the passage. It is transmitted to the controller 74c. Then, the controller 74c checks the output states of the second sensor 74s2 and the third sensor 74s3 when this signal is received. When the output state of the second sensor 74s2 indicates “there is a connected product 11a” and the output state of the third sensor 74s3 indicates “there is no connected product 11a”, the “connected product 11a” Is a good product. On the other hand, when the output state is a combination other than the above, it is determined that “the connected product 11a is a defective product”.

  Incidentally, when the output state of the third sensor 74 s 3 indicates “with the connected product 11 a”, the overall length L 11 a is longer than the assumed length range, and in this case, It corresponds to one of the three types of non-defective products (partially cut out of the perforated portion 12ac, complete cutting of the perforated portion 12ac, and presence of an empty individual packaged product 11). In addition, when the output state of the second sensor 74s2 indicates “no connected product 11a”, as described above, the connected product 11a does not have the target number of individually packaged products 11 and the number of stations is insufficient. It corresponds to the aspect of.

  In this example, a photoelectric tube is used as each of the first to third sensors 74s1 to 74s3. However, the present invention is not limited to this, and an appropriate sensor such as a laser sensor can also be applied.

  In addition, when the number of stations is changed, the assumed length range of the connected product 11a also changes, so it is necessary to change the installation positions of the second and third sensors 74s2 and 74s3. Therefore, it is possible to easily cope with the station number change.

  As shown in FIG. 5, the distribution mechanism 75 is connected to the downstream of the belt conveyor 71 in the MD direction, and sucks and holds the connected product 11a from above and conveys it downstream in the MD direction. The belt conveyor 77 disposed on the lower side facing only the downstream portion in the MD direction of the suction belt conveyor 76, and the upstream portion of the suction belt conveyor 76, and injecting air downward. Thus, the air injection device 78 for removing the defective connected product 11a downward from the suction belt conveyor 76 is provided.

  And according to the said structure, the space SPtb in which a belt conveyor does not exist is provided under the upstream part in the suction belt conveyor 76, The said space SPtb discharges | emits the above-mentioned discharge path Tb. Function as. That is, the air injection device 78 is activated when the connected product 11a that is conveyed upward in the MD direction while being adsorbed upward by the suction belt conveyor 76 passes through the upstream portion of the suction belt conveyor 76. When the air is jetted, the connected product 11a falls to the lower discharge path Tb, and is thereby discharged from the regular transport path Tg. And if the connection goods 11a finishes passing, it will stop injecting air and will be in a standby state.

  In addition, when each connected product 11a passes the position of the air injection device 78, the process of selectively operating the device 78 only for the connected product 11a determined to be defective is performed as follows, for example. Realized. First, the distance L78 from the first monitoring target position P74s1 of the first sensor 74s1 to the air injection device 78 is a known fixed value, and it is also known how many cycles of the synchronization signal the distance L78 corresponds to. is there. Therefore, the data of the distance L78 is recorded in advance in the memory of the controller 74c in the form of a converted value converted into the cycle number of the synchronization signal. Further, both the output signal and the synchronization signal of the first sensor 74s1 are input to the controller 74c. Further, for example, the memory has a pass / fail determination flag, and the flag is determined by the inspection device 74. Moreover, the data of the pass / fail judgment result, which is the latest inspection result, is always overwritten and recorded.

  Therefore, when the controller 74c receives a signal indicating that the first sensor 74s1 has passed through the first monitoring target position P74s1 of the first sensor 74s1, the controller 74c receives the signal indicating that the first sensor 74s1 has passed. The cycle of the synchronization signal is counted from the time point. When the count value matches the converted value, the controller 74c refers to the pass / fail determination flag in the memory, and when the “non-defective flag” is recorded in the pass / fail determination flag, the air injection The connected product 11a is transported downstream through the regular transport path Tg without operating the device 78. On the other hand, when the “defective product flag” is recorded in the pass / fail judgment flag, the air injection device 78 is operated to inject air toward the connected product 11a. As a result, the connected product 11a is separated from the regular transport path Tg and discharged through the discharge path Tb. The air injection stop operation is performed, for example, when the upstream end 11aeu of the connection product 11a has finished passing the position of the air injection device 78 based on the count value of the synchronization signal.

  By the way, in the above-described inspection device 74, the quality of the overall length L11a of the connected product 11a is determined by referring to the output state of the second sensor 74s2 and the third sensor 74s3 based on the output signal of the first sensor 74s1. However, in such an inspection method, there is a possibility that a defective product is erroneously determined as a good product depending on the situation.

  For example, as shown in FIG. 6, in the case where the connection product 11a is unintentionally cut at the center perforation portion 12ac in the MD direction due to the conveyance tension or the like, two five-part products 11a5 and 11a5 are used. Are generated, both of which are fraction defective with insufficient number of stations. Then, depending on the situation, as shown in FIG. 6, the output signal of the second sensor 74s2 of the inspection device 74 is “the connected product 11a exists” for the connected product 11a including the two fractional defective products 11a5 and 11a5. And the output signal of the third sensor 74s3 may indicate “no connected product 11a”. In this case, the above-described inspection apparatus 74 uses a connection consisting of these fraction defective products 11a5 and 11a5. The product 11a is erroneously determined to be a non-defective product.

  Therefore, in the example of FIG. 6, a second inspection device 84 is additionally provided, which makes it possible to reliably inspect the presence or absence of cutting at the perforated portion 12ac that is not to be cut. Specifically, the second inspection device 84 includes an inspection sensor 84s provided in, for example, an upstream portion of the inspection conveyor 71, and a controller 84c provided corresponding to the sensor 84s. A photoelectric tube 84s is used as the sensor 84s, and the photoelectric tube 84s constantly transmits an output value signal corresponding to the amount of received light to the controller 84c. On the other hand, the controller 84c compares the output value of this signal with predetermined threshold data, thereby detecting the presence or absence of cutting at the perforated portion 12ac that is not to be cut. That is, if there is a perforated portion 12ac in the connection product 11a, a gap G12ac is generated there. Therefore, the presence or absence of cutting is detected from the change in the light receiving state of the photoelectric tube 84s when the gap G12ac passes. Can do.

  More details are as follows. First, when the output value of the signal from the photoelectric tube 84s enters a predetermined numerical range defined by the threshold data, the downstream end 11aed of the connected product 11a passes through the monitoring target position P84s of the photoelectric tube 84s after this time. It is considered as the time when. Then, the controller 84c counts the cycle of the synchronization signal starting from the time point, and this count value spans a time range until it matches the number of cycles corresponding to the total length L11a of the connected product 11a of the target station number. If the output value of the signal from the phototube 84s does not fall outside the above numerical range, the “non-defective flag” is recorded in the second pass / fail judgment flag provided in the memory of the controller 84c. On the other hand, if the output value is out of the numerical range even once, it is considered that the gap G12ac is present, and the “flag indicating defective product” is recorded in the second pass / fail judgment flag. The second pass / fail determination flag is always overwritten and recorded.

  Therefore, if the air injection device 78 is operated based on the second pass / fail judgment flag, the connected product 11a composed of the short-numbered defective products 11a5 and 11a5 is discharged from the discharge path Tb, and the target station number Only good products can be sent to the regular transport path Tg.

  For example, in the memory of the controller 84c, conversion value data obtained by converting the distance L78a from the monitoring target position P84s of the photoelectric tube 84s to the air injection device 78 into the cycle number of the synchronization signal is recorded in advance. In addition, the controller 84c counts the number of cycles of the synchronization signal starting from the passage of the monitoring target position P84s of the phototube 84s of the connected product 11a. When the count value matches the converted value, the controller 84c determines that the connected product 11a has reached the position of the air injection device 78. Therefore, at this time, the controller 84c refers to the second pass / fail judgment flag, and when the “flag indicating a defective product” is recorded in the second pass / fail judgment flag, the controller 84c causes the air injection device 78 to It operates and injects air toward the connected product 11a, whereby the connected product 11a is separated from the regular transport path Tg and discharged from the discharge path Tb. On the other hand, when the “non-defective flag” is recorded in the second pass / fail judgment flag, the connected product 11a is transported downstream through the regular transport path Tg without operating the air injection device 78.

  In some cases, such sensors 84s are provided at a plurality of locations on the belt conveyor 71, and the second pass / fail judgment flag is obtained when the pass / fail judgment result based on the signal from any one of the sensors 84s, 84s. In addition, a “flag indicating a defective product” may be recorded. In this way, it is possible to improve the detection accuracy of the connected product 11a having an insufficient number of stations.

  In the above description, the dedicated sensor 84s is provided in the second inspection device 84 separately from the second and third sensors 74s2 and 74s3. However, the second and third sensors 74s2 and 74s3 are connected to the sensor 84s. The second and third sensors 74s2 and 74s3 may also be used as the sensor 84s. And if it does in this way, sensor 84s can be omitted and equipment cost can be reduced. Furthermore, the controller 84c of the second inspection apparatus 84 may also serve as the controller 74c of the first inspection apparatus 74.

  Incidentally, among the defective connected products 11a discharged from the discharge path Tb, those that are determined as defective due to insufficient number of stations are not defective products when viewed as the individually packaged products 11, 11,. . For this reason, the connected products 11a, 11a having insufficient number of stations may be shipped after being aligned with the target number of stations by connecting them with an adhesive tape or the like.

=== Other Embodiments ===
As mentioned above, although embodiment of this invention was described, said embodiment is for making an understanding of this invention easy, and is not for limiting and interpreting this invention. Further, the present invention can be changed or improved without departing from the gist thereof, and needless to say, the present invention includes equivalents thereof. For example, the following modifications are possible.

  In the above-described embodiment, the separation device 60 has cut the perforated portion 12ac to be cut in the MD direction. However, the method for cutting the perforated portion 12ac is not limited to this, and for example, shearing may be used. . In the case of shearing, for example, when the perforated portion 12ac to be cut passes along the MD direction, the portion adjacent to the downstream side of the perforated portion 12ac in the continuous sheet 12aa and the perforated portion 12ac in the sheet 12aa. By applying displacements opposite to each other in the thickness direction of the continuous sheet 12aa with respect to the portion adjacent to the upstream side of the sheet, shear deformation in the vertical direction is given, thereby cutting the perforated portion 12ac. Can be mentioned. In addition, as a mechanism (not shown) for giving displacements in opposite directions to each other, a first plate member that is arranged downstream in the MD direction and moves up and down, and an upper and lower side that is arranged upstream from the first plate member. Examples include a second plate member that moves up and down, and a drive mechanism that reversely moves the first plate and the second plate member.

  In the above-described embodiment, in the separation device 60, when the perforated portion 12ac to be cut passes between the pair of nip roll mechanisms 62 and 64, the conveyance speed value V11aa of the continuous body 11aa in the downstream nip roll mechanism 64 is set. By increasing the speed, the perforated part 12ac is pulled and cut in the MD direction with the upstream nip roll mechanism 62, but the invention is not limited to this.

  That is, when the perforated portion 12ac to be cut passes between the pair of nip roll mechanisms 62 and 64, the conveyance speed value V11aa of the continuous body 11aa in the downstream nip roll mechanism 64 and the continuity in the upstream nip roll mechanism 62 are detected. As long as the perforated portion 12ac to be cut can be pulled in the MD direction and cut by increasing the difference from the conveyance speed value V11aa of the body 11aa, the speed increasing process is not limited to the above.

  For example, the conveyance speed value V11aa in the downstream nip roll mechanism 64 is reduced by reducing the conveyance speed value V11aa in the upstream nip roll mechanism 62 while maintaining the conveyance speed value V11aa in the downstream nip roll mechanism 64 substantially constant. The difference from the conveyance speed value V11aa in the upstream nip roll mechanism 62 is increased, and thereby, the tensile force in the MD direction is applied to the perforated portion 12ac to be cut while passing between the pair of nip roll mechanisms 62 and 64. May be cut.

  In the above-described embodiment, as an example of the separation device 60, the pair of nip roll mechanisms 62 and 64 arranged in the MD direction are illustrated as shown in FIG. 3, but the present invention is not limited to this. For example, as shown in the schematic side views of FIGS. 7A and 7B, instead of one nip roll mechanism 62 (64) of the pair of nip roll mechanisms 62, 64, a pair of upper and lower endless belts 162u, 162d ( An endless belt mechanism 162 (164) having 164u, 164d) may be used. According to the endless belt mechanism 162 (164), the pair of upper and lower endless belts 162u, 162d (164u, 164d) can convey the continuous body 11aa from the thickness direction while being pressed, so that the nip roll mechanism 62 (64 ), The perforated portion 12ac to be cut can be pulled in the MD direction. Therefore, such a configuration may be used as the separation devices 60a and 60b.

  Furthermore, as shown in the schematic side view of FIG. 7C, the separation device 60c may be configured by arranging two endless belt mechanisms 162 and 164 in the MD direction. That is, when the perforated portion 12ac to be cut passes between the endless belt mechanism 162 located on the upstream side in the MD direction and the endless belt mechanism 164 adjacent to the downstream side, the endless belts 162u and 164u of each other are passed. The perforated portion 12ac to be cut may be pulled in the MD direction for cutting by increasing the difference between the peripheral speed values V162 and V164.

  In the above-described embodiment, the air injection device 78 is used as a device for removing the defective connected product 11a from the suction belt conveyor 76 of the distribution mechanism 75 (for example, FIG. 5), but this is not a limitation. For example, instead of the air injection device 78, a device (not shown) in which an obstacle member appears and disappears in the conveyance path of the suction belt conveyor 76 may be provided. And according to the device, by putting the obstacle member in the exiting state, it is possible to cause the coupling member 11a to collide with the obstacle member and disengage from the suction belt conveyor 76, while on the other hand, by placing the obstacle member in the submerged state, The conveyance by the suction belt conveyor 76 can be maintained.

  In the above-described embodiment, a configuration including the first to third sensors 74s1, 74s2, and 74s3 is shown as an example of the first inspection device 74, and the first sensor 74s1 detects the passage of the downstream end 11aed of the connection product 11a. Based on the output states of the second sensor 74s2 and the third sensor 74s3 at the time of the determination, it has been determined whether or not the total length L11a of the connected product 11a is within the assumed length range, but is not limited thereto. For example, a contact-type or non-contact-type speed measurement sensor (not shown) that measures the conveyance speed value V11a of the connected product 11a is provided at a predetermined position while facing the conveyance path of the belt conveyor 71. Then, the speed measurement sensor transmits to the controller (not shown) in real time over the entire time from when the connected product 11a starts to pass through the monitoring target position (measurement target position) of the speed measurement sensor. The controller integrates the speed value to calculate the full length dimension L11a, and compares the calculated value of the full length dimension L11a with the data of the assumed length range recorded in the memory of the controller in advance. An inspection of L11a may be performed.

  In addition, in order to use a sensor of the same type as the speed measurement sensor as a part of the specific device, the sensor may be separately provided at a position near the separation device 60. In this case, first, the controller 66 integrates the velocity value transmitted from the sensor, thereby obtaining the length of the continuum 11aa that has passed the position. When the length reaches the target length corresponding to the target station number, it is determined that the perforated portion 12ac to be cut has entered between the upstream nip roll mechanism 62 and the downstream nip roll mechanism 64. Then, the downstream side nip roll mechanism 64 is accelerated to cut the continuous body 11aa. Incidentally, at the same time that the integral value of the speed value reaches the target length, the integral value is reset to zero, so that the controller 66 is provided for the integration process of the next station number.

  In the above-described embodiment, the entire length L11a of the connected product 11a is inspected while the connected product 11a is being conveyed by the belt conveyor 71 of the inspection conveyor 70. However, the present invention is not limited to this. For example, a separate belt conveyor may be connected downstream of the belt conveyor 71, and the inspection may be performed during conveyance by the belt conveyor. In other words, the length L11a may be inspected after being conveyed by the belt conveyor 71. Also in this case, since the inspection of the total length 11La is performed on the connected product 11a that has been extended in the MD direction when transferring from the separating device 60 to the belt conveyor 71, the inspection is accurate. Become.

  In the above-described embodiment, the end seal and perforation device 50 has a pair of upper and lower rolls 51u and 51d. The upper roll 51u is provided with a pair of sealing portion convex portions 53us and 53us as a pair of pressing portions, and is provided with a perforating blade 53uc as a blade member, and the lower roll 51d While the pair of receiving portions 53ds and 53ds are provided and the receiving blade 53dc is provided, the present invention is not limited to this. That is, the up-and-down arrangement of the sealing portion convex portions 53us and 53us and the receiving portion may be reversed, and the up-and-down arrangement of the perforating blade 53uc and the receiving blade 53dc may be reversed.

  In some cases, a pair of sealing convex portions 53us, 53us is provided on one roll 51u (51d) of the pair of upper and lower rolls 51u, 51d, and the other roll 51d (51u) is provided. A perforated blade 53uc may be provided. However, also in this case, when the perforation blade 53uc processes the perforation portion 12ac in the continuous sheet 12aa, the perforation blade 53uc is positioned between the corresponding pair of sealing portion convex portions 53us, 53us. As described above, the upper and lower rolls 51u and 51d are rotated, and such rotation operation is realized by position control of the servo motor.

  In the above-described embodiment, the disposable diaper 1 is illustrated as an example of the absorbent article. There may be.

1 disposable diapers (absorbent articles),
11 individually packaged product, 11ed downstream end, 11eu upstream end,
11a connected product, 11a5 fraction defective product,
11aa continuum, 11aed downstream end, 11aeu upstream end,
12 Packaging sheet,
12a packaging sheet, 12ab part, 12ae end,
12aa A continuous body of packaging sheets (continuous sheet),
12 aab part, 12 aae end,
12ac perforated part, 12as sealing part,
30 wrapping device, 32 belt conveyor,
34a guide plate, 34b guide plate,
40 center seal device, 42 heating section,
50 End seal and perforation device (continuum generator),
51u roll (roll-shaped member), 51d roll (roll-shaped member),
52u upper processing part, 52d lower processing part,
53uc perforation blade (blade member), 53dc receiving blade,
53us sealing part convex part (pressing part), 53ds receiving part,
60 detaching device, 60a detaching device,
60b cutting device, 60c cutting device,
62 upstream nip roll mechanism, 62u nip roll, 62d nip roll,
64 downstream nip roll mechanism, 64u nip roll, 64d nip roll,
66 controller (specific device), 68 disconnection confirmation sensor,
70 inspection conveyor, 71 belt conveyor (downstream conveyor),
71u upper endless belt, 71d lower endless belt, 72u roller, 72d roller,
74 first inspection device, 74c controller,
74s1 first sensor, 74s2 second sensor, 74s3 third sensor,
75 sorting mechanism, 76 suction belt conveyor, 77 belt conveyor,
78 air injection device,
84 Second inspection device, 84c controller, 84s sensor,
162 endless belt mechanism, 162u endless belt, 162d endless belt,
164 endless belt mechanism, 164u endless belt, 164d endless belt,
CV belt conveyor,
C62 rotation axis, C64 rotation axis,
D60 interval, G11a interval, G12ac gap, G51 gap,
Tb discharge route, Tg regular transport route,
P1 predetermined position,
P74s1 first monitoring target position, P74s2 second monitoring target position,
P74s3 third monitoring target position, P84s monitoring target position,
R74s3 range,
SPtb space,

Claims (9)

A predetermined number of the individual packaged products are connected from a continuous body of individual packaged products formed by connecting a plurality of individual packaged products in which absorbent articles are individually accommodated in a lined-up state through a perforated portion. An apparatus for manufacturing the connected product by separating the connected product of the individually packaged product,
From the perforations of the continuum that is conveyed with the alignment direction as the transport direction, a specifying device that identifies perforations to be cut corresponding to the predetermined number;
A disconnecting device for disconnecting the connected product in which the predetermined number of individually packaged products are connected from the continuous body transported along the transport direction by cutting the perforated portion specified by the specifying device; The manufacturing apparatus of the connection product of the individual package goods which concerns on an absorbent article characterized by having. An apparatus for manufacturing a linked product of individually packaged products according to claim 1,
The separating device according to an absorbent article, wherein the perforated portion is cut by pulling the perforated portion in the transport direction when the identified perforated portion passes through the separating device. Equipment for manufacturing linked products of individual packages. An apparatus for manufacturing a linked product of individually packaged products according to claim 1 or 2,
The specific device includes an input unit that inputs information relating to the predetermined number, and a memory that updates and records the predetermined number based on the information input from the input unit,
The identification device identifies the perforation portion to be cut corresponding to the predetermined number recorded in the memory, and causes the separation device to cut the identified perforation portion. Equipment for manufacturing linked products of individually packaged products. An apparatus for manufacturing a linked product of individually packaged products according to any one of claims 1 to 3,
The separating apparatus has a pair of nip roll mechanisms having a pair of rolls that rotate while sandwiching the continuous body from the thickness direction of the continuous body, aligned in the transport direction,
When the perforated portion to be cut passes between the pair of nip roll mechanisms, the conveyance speed value of the continuous body in the downstream nip roll mechanism of the pair of nip roll mechanisms, and the upstream nip roll mechanism An apparatus for manufacturing a connected product of individually packaged products according to an absorbent article, wherein the perforated portion is pulled in the transport direction to cut by increasing a difference from the transport speed value of the continuous body in the above. An apparatus for manufacturing a linked product of individually packaged products according to claim 4,
In the absorbent article, the interval between the pair of nip roll mechanisms is set so that the number of perforations existing between the pair of nip roll mechanisms is always one or less. Equipment for manufacturing linked products of such individually packaged products. An apparatus for manufacturing a linked product of individually packaged articles according to any one of claims 1 to 5,
Except when cutting the perforated portion to be cut, when the transport speed value of the continuous body and the connected product transported by the cutting device is a first speed value,
On the downstream side in the transport direction with respect to the separation device, there is a downstream transport device that transports the continuous body and the connected product at a transport speed value faster than the first speed value,
Connection of individually packaged articles according to absorbent articles, comprising a first inspection device for inspecting the overall length dimension of the connected product in the transport direction during or after transport of the connected product by the downstream transport device Product manufacturing equipment. An apparatus for manufacturing a linked product of individually packaged articles according to any one of claims 1 to 6,
An individually packaged product according to an absorbent article having a second inspection device for inspecting the presence or absence of a perforated portion cut out of the perforated portions that should be included in the connected product during conveyance of the connected product Equipment for manufacturing connected products. An apparatus for manufacturing a linked product of individually packaged articles according to any one of claims 1 to 7,
At a position upstream of the separating device in the transport direction,
A wrapping device for wrapping a plurality of the absorbent articles conveyed in the conveying direction in a state aligned in the conveying direction with a continuous sheet for packaging conveyed in the conveying direction;
A pair of sealing parts are formed in each part between the absorbent articles in the continuous sheet to individually accommodate the absorbent article, and at a position between the pair of sealing parts in each part. A continuous body generating device that generates a continuous body of the individually packaged product by forming the perforated portion;
The continuous body generating device has a pair of roll-shaped members that rotate in conjunction with the conveying operation of the continuous sheet while facing an outer peripheral surface of the continuous sheet.
On the outer peripheral surface of at least one roll-shaped member of the pair of roll-shaped members, a pair of pressing portions that press-form the pair of sealing portions on the continuous sheet is provided,
A blade member that presses and forms the perforated portion on the continuous sheet is provided on the outer peripheral surface of at least one of the pair of roll-shaped members,
When processing the perforated part, the blade member is located at a position between the pair of pressing parts, and the manufacturing apparatus for a connected product of individually packaged products according to the absorbent article. A predetermined number of the individual packaged products are connected from a continuous body of individual packaged products formed by connecting a plurality of individual packaged products in which absorbent articles are individually accommodated in a lined-up state through a perforated portion. A method of manufacturing the connected product by separating the connected product of the individually packaged product,
Identifying the perforations to be cut corresponding to the predetermined number from the perforations of the continuum that is transported with the alignment direction as the transport direction;
Severing the identified perforated portion to separate the connected product in which the predetermined number of individually packaged products are connected from the continuous body transported along the transport direction. A method for producing a linked product of individually packaged products relating to an absorbent article.

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