JP2015199502A - Packaging article connected body and manufacturing method of the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a packaging article connected body and a manufacturing method of the same which can suppress the leakage of a content of a packaging article.SOLUTION: A packaging bag 14 of a packaging article connected body 11 has a main heat-welded part 21 and a sub-heat-welded part 22 having lower thermal welding strength than the main heat-welded part 21. The packaging bag 14 comprises an inflow part 23 into which a content 15 inside an accommodation part flows when opening the sub-heat-welded part 22. The packaging article connected body 11 has a structure in which a downstream end 33 of the inflow part 23 provided in a second packaging article 13 is sealed by the main heat-welded part 21 provided in a first packaging article 12. A manufacturing method of the packaging article connected body 11 comprises: a first step of forming a first lateral heat welded part in a base material under a condition in which one of the main heat-welded part 21 and the sub-heat-welded part 22 is formed by using a first mold; and a second step of forming a second lateral heat-welded part in the base material after the first lateral heat-welded part is formed, under a condition in which the other of the main heat-welded part 21 and the sub-heat-welded part 22 is formed by using a second mold.

Description

  The present invention relates to a packaged article assembly and a method for producing the same.

  2. Description of the Related Art Conventionally, a packaging bag having an accommodating portion formed by a heat welding portion is known. Examples of such packaging bags include three-side sealed packaging bags, four-side sealed packaging bags, and pillow packaging bags. Patent Document 1 discloses a three-side sealed packaging bag having a heat-welded portion composed of a vertical seal portion and a pair of horizontal seal portions.

JP 2009-234629 A

  In the packaging article in which the contents are stored in the storage part of the packaging bag, by configuring the heat welding part of the packaging bag from the main heat welding part and the sub heat welding part having a lower heat welding strength than the main heat welding part, It is possible to open the auxiliary heat welding part using the internal pressure of the housing part.

  On the other hand, packaging articles are often manufactured as a packaging article assembly in which a plurality of packaging articles are coupled in order to increase productivity. After such a packaged article assembly is transported, for example, it is separated into individual packaged articles and further accommodated in the package. Here, in the packaged article assembly including the packaging bag having the auxiliary heat welding portion as described above, for example, when the unnecessary force is applied to the storage portion during transportation, the auxiliary heat welding portion is opened and the contents are opened. May leak out.

  This invention is made | formed in view of such a situation, The objective is to provide the packaged article coupling body which can suppress that the content of a packaged article leaks, and its manufacturing method.

  A packaged article assembly that solves the above-described problem includes a plurality of packaged articles including a first packaged article and a second packaged article coupled to the first packaged article, and the packaged article is formed by a heat welding part. A packaged article linking body including a packaging bag having an accommodating part, wherein the thermal welding part of the packaging bag includes a main thermal welding part and a secondary thermal welding part having a thermal welding strength lower than that of the main thermal welding part. And the packaging bag has an inflow portion into which the contents in the housing portion flows when the auxiliary heat welding portion is opened, and the inflow portion is formed by the main heat welding portion or the folding portion of the packaging bag. A first end edge and a second end edge, and the downstream end of the inflow portion of the second packaging article is sealed by the main heat welding portion of the first packaging article. Has a structured.

  According to this configuration, even if the contents flow into the inflow part by opening the secondary heat welding part of the second packaging article, the outflow of the contents to the outside is the main heat welding part of the first packaging article. It is suppressed by.

  The manufacturing method of the said packaged article coupling body is provided with the transverse heat welding process which forms a transverse heat welding part in the base material which has the hollow part continuous in the vertical direction, and the said transverse heat welding process is 1st to the said base material. A first step of forming the first transverse heat welded part under the condition that the auxiliary heat welded part is formed using a mold, and a second mold on the substrate after the formation of the first transverse heat welded part It is preferable to have a second step of forming the second transverse heat welded part under the condition that the main heat welded part is formed by using.

  According to this method, the transverse heat welding process for forming the sub heat welding part and the main heat welding part includes the first stage using the first mold and the second stage using the second mold, and therefore the first stage. And the second stage condition can be set separately. For this reason, in the transverse heat welding process in which both the auxiliary heat welding part and the main heat welding part are formed, it is easy to set conditions for heat welding.

  In the method for manufacturing a packaged article assembly, the first mold is provided on each of a pair of rollers, the first transverse heat welding portion is formed between the pair of rollers, and the first mold is A heating unit for forming the first transverse heat-welded part; and a low thermal conduction part configured to pressurize the base material, the heating part comprising a material having lower thermal conductivity than the heating part, and the heating part and The low heat conduction part is arranged so as to partition the hollow portion into an upstream side and a downstream side in the flow direction of the base material, and the heating part is a downstream heating part, and the base material flows more than the downstream heating part. It is preferable that it has an upstream heating part located in the upstream of a direction, and the said low heat conduction part is arrange | positioned between the said downstream heating part and the said upstream heating part.

  In the above-described method, in the first mold, a low heat conductive portion that is made of a material having lower thermal conductivity than the heating portion and pressurizes the base material is disposed between the downstream heating portion and the upstream heating portion. . For this reason, in the 1st step using a 1st metallic mold, with respect to the substrate which passes between a pair of rollers, the formation of the downstream heat welding part by the downstream heating part, the pressurization by the low heat conduction part, the upstream by the upstream heating part The formation of the heat welding part is performed in this order. For this reason, inflow of the contents and gas into the hollow portion located between the downstream heat weld portion and the upstream heat weld portion is suppressed, and the base located between the downstream heat weld portion and the upstream heat weld portion. The thermal welding of the material is suppressed. Therefore, the base material located between the downstream heat welding part and the upstream heat welding part is suitably secured as a part that forms the inflow part in the second stage using the second mold.

  In the method for manufacturing a packaged article assembly, the second mold is provided on each of a pair of rollers, the second lateral heat welding portion is formed between the pair of rollers, and the second mold is A heating section for forming the second transverse heat weld section; and a low thermal conduction section made of a material having lower thermal conductivity than the heating section, wherein the low thermal conduction section is a flow of the base material It is preferable to pressurize the base material in the direction from the first lateral heat welding portion toward the upstream side.

  In the above method, the second mold used in the second stage has a low thermal conductive portion made of a material having lower thermal conductivity than the heating portion. The low heat conduction part pressurizes the base material from the first lateral heat welding part toward the upstream side in the flow direction of the base material. Thus, in the part pressurized by the low heat conduction part, inflow of contents and gas and heat welding are suppressed.

  The manufacturing method of the said packaged article coupling body is provided with the transverse heat welding process which forms a transverse heat welding part in the base material which has the hollow part continuous in the vertical direction, and the said transverse heat welding process is 1st to the said base material. A first step of forming the first transverse heat welded part under the condition that the main heat welded part is formed using a mold, and a second mold on the base material after the first transverse heat welded part is formed. It is preferable to have a second step of forming the second transverse heat welded part under the condition that the auxiliary heat welded part is formed by using.

  According to this method, the transverse heat welding process for forming the main heat welding portion and the sub heat welding portion includes the first stage using the first mold and the second stage using the second mold. And the second stage condition can be set separately. For this reason, in the transverse heat welding process in which both the auxiliary heat welding part and the main heat welding part are formed, it is easy to set conditions for heat welding.

  In the method for manufacturing a packaged article assembly, the second mold is provided on each of a pair of rollers, the second lateral heat welding portion is formed between the pair of rollers, and the second mold is A heating part for forming the second transverse heat welding part, and a low heat composed of a material that is located downstream of the heating part in the flow direction of the base material and has lower thermal conductivity than the heating part. It is preferable that the low thermal conductivity portion pressurizes the base material from the first transverse heat welded portion toward the upstream side in the flow direction of the base material.

The second mold used in this method has a low heat conduction part which is located downstream of the heating part in the flow direction of the base material and is made of a material having a lower thermal conductivity than the heating part.
For this reason, in the second stage using the second mold, pressurization by the low heat conduction portion and formation of the second transverse heat weld portion by the heating portion are performed in this order on the base material passing between the pair of rollers. Is called. For this reason, the heat welding of the base material located between a 1st side heat weld part and a 2nd side heat weld part is suppressed. Therefore, the base material located between the first lateral heat welded portion and the second lateral heat welded portion is suitably secured as a portion that forms the inflow portion in the second stage using the second mold.

  In the method for manufacturing a packaged article assembly, the first mold is provided on each of a pair of rollers, the first transverse heat welding portion is formed between the pair of rollers, and the first mold is A heating section for forming the first transverse heat-welded section; and a low thermal conduction section made of a material having a lower thermal conductivity than the heating section, wherein the low thermal conduction section is a flow of the base material It is preferable to pressurize the base material in the direction from the first lateral heat welding portion toward the upstream side.

  The first mold used in this method has a low heat conduction part made of a material having lower heat conductivity than the heating part, and the low heat conduction part is formed from the first lateral heat weld part in the flow direction of the base material. It is comprised so that the said base material may be pressurized toward an upstream.

  For this reason, in the first stage using the first mold, formation of the first transverse heat welded portion by the heating portion and pressurization by the low heat conducting portion are performed in this order on the base material passing between the pair of rollers. Is called. The substrate can be temporarily brought into close contact with such a low heat conduction portion by pressurization. Thus, in the pressurization part pressurized by the low heat conduction part, inflow of contents and gas is temporarily suppressed.

  According to this invention, it can suppress that the contents of a packaging article leak.

The schematic diagram which shows the packaging article coupling body of 1st Embodiment. (A) is a schematic diagram which shows the manufacturing method of a packaged article coupling body, (b) is a schematic diagram which shows the surface which pressurizes a base material in a 1st metal mold | die, (c) pressurizes a base material in a 2nd metal mold | die. The schematic diagram which shows a surface. (A) And (b) is a schematic diagram explaining a 1st step, (c) And (d) is a schematic diagram explaining a 2nd step. (A) is a schematic diagram which shows the manufacturing method of the package article coupling body in 2nd Embodiment, (b) is a schematic diagram which shows the surface which pressurizes a base material in a 1st metal mold | die, (c) is in a 2nd metal mold | die. The schematic diagram which shows the surface which pressurizes a base material. (A) is a schematic diagram which shows the manufacturing method of the packaging article coupling body in 3rd Embodiment, (b) is a schematic diagram which shows the surface which pressurizes a base material in a 1st metal mold | die, (c) is in a 2nd metal mold | die. The schematic diagram which shows the surface which pressurizes a base material. (A) is a schematic diagram which shows the manufacturing method of the packaged article coupling body in 4th Embodiment, (b) is a schematic diagram which shows the surface which pressurizes a base material in a 1st metal mold | die, (c) is in a 2nd metal mold | die. The schematic diagram which shows the surface which pressurizes a base material. (A) is a schematic diagram which shows the manufacturing method of the packaging article coupling body in 5th Embodiment, (b) is a schematic diagram which shows the surface which pressurizes a base material in a 1st metal mold | die, (c) is in a 2nd metal mold | die. The schematic diagram which shows the surface which pressurizes a base material.

(First embodiment)
Hereinafter, 1st Embodiment of a packaged article coupling body and its manufacturing method is described with reference to FIGS.

<Packaged article assembly>
As illustrated in FIG. 1, the packaged article connector 11 includes a plurality of packaged articles including a first packaged article 12 and a second packaged article 13 coupled to the first packaged article 12. Each packaging article includes a packaging bag 14 having a housing portion formed by a heat welding portion.

  The heat welding part of each packaging bag 14 has a main heat welding part 21 and a sub heat welding part 22 having a lower heat welding strength than the main heat welding part 21. Each packaging bag 14 has an inflow portion 23 into which the contents 15 in the housing portion flows when the auxiliary heat welding portion 22 is opened. The inflow portion 23 has a first side edge 31 and a second side edge 32 formed by the main heat welding portion 21.

  Each packaging bag 14 has a three-sided seal structure having a longitudinal heat welding portion extending in a direction in which the packaging articles are continuous and a transverse heat welding portion extending in a direction intersecting the longitudinal heat welding portion. The longitudinal heat welding part of each packaging bag 14 is composed of a main heat welding part 21. In each packaging bag 14, the transverse heat welded portion having the inflow portion 23 is composed of a main heat welded portion 21 and a sub heat welded portion 22. In each packaging bag 14, the transverse heat welded portion that seals the edge opposite to the transverse heat welded portion having the inflow portion 23 is constituted by a main heat welded portion 21. In each packaging bag 14, a folded portion 24 of a base material is formed at the edge opposite to the longitudinal heat welding portion.

  The 1st packaging article 12 and the 2nd packaging article 13 are connected by the structure where the downstream end 33 of the inflow part 23 which the 2nd packaging article 13 has was sealed by the main heat welding part 21 which the 1st packaging article 12 has. ing. That is, the upstream end of the inflow portion 23 of the second packaged article 13 is sealed with the auxiliary heat welding portion 22, and the downstream end 33 is sealed with the main heat welding portion 21.

  As shown by a two-dot chain line in FIG. 1, the planned cutting line 16 when the packaged article connector 11 is separated into each packaged article flows when the packaged article connector 11 is separated into each packaging bag 14. The downstream end 33 of the portion 23 is set to be an opening. In the present embodiment, the planned cutting line 16 is set so as to cross both the first side edge 31 and the second side edge 32, but is not limited thereto, and the first side edge 31 and the second side edge 31 are not limited to this. It may be set so as to cross either one of the side edges 32.

  As a base material constituting the packaging bag 14, a heat-weldable resin film is used. Examples of the resin film include a laminated film composed of a base film layer and a sealant layer, and a laminated film in which an intermediate layer is provided between the base film layer and the sealant layer.

  Examples of the resin constituting the base film layer include olefin resins such as polyethylene and polypropylene, ethylene-vinyl alcohol copolymers, polyesters, polyamides, polyimides, and vinylidene chloride. As resin which comprises a sealant layer, polyolefin resin, such as polyethylene and a polypropylene, is mentioned, for example. Examples of the material constituting the intermediate layer include silica, aluminum oxide, aluminum, and vinylidene chloride.

The substrate may be a single layer film. For example, the substrate is appropriately selected from substrates having a thickness in the range of 6 to 300 μm.
Examples of the contents 15 accommodated in the accommodating portion include food and drink. The form of the content 15 is not specifically limited, For example, a liquid body is mentioned. The content 15 may be a mixture of two or more different forms.

  Each packaged article of the present embodiment preferably contains food as the content 15, and more preferably contains a seasoning such as a liquid seasoning or mustard. The packaged article containing the seasoning is provided with a relatively small packaging bag 14, and among the outer dimensions of the packaging bag 14, the largest outer dimension is often configured to be, for example, 150 mm or less.

Next, the operation of the packaged article assembly 11 will be described.
The packaging bag 14 of the packaged article assembly 11 has an inflow portion 23 into which the contents 15 in the housing portion flows when the auxiliary heat welding portion 22 is opened. The 1st packaging article 12 and the 2nd packaging article 13 are connected by the structure where the downstream end 33 of the inflow part 23 which the 2nd packaging article 13 has was sealed by the main heat welding part 21 which the 1st packaging article 12 has. Has been. For this reason, even if the contents 15 flow into the inflow portion 23 by opening the auxiliary heat welding portion 22 of the second packaging article 13, the outflow of the contents 15 to the outside of the first packaging article 12 is the main. It is suppressed by the heat welding part 21.

  The packaged article linking body 11 is preferably separated into each packaged article and further accommodated in the packaged body. For example, when the content 15 is a seasoning, it is accommodated in a package together with food such as natto. Thus, since the packaging article accommodated in the packaging body is protected by the packaging body, an excessive force applied to the accommodation portion is reduced. When the packaged article is used, the auxiliary heat welding part 22 is opened using the internal pressure in the housing part. For example, the auxiliary heat welding part 22 can be opened by pressing a storage part with fingers or the like.

<Method for producing packaged article assembly 11>
Next, a method for manufacturing the packaged article assembly 11 will be described.
As shown to Fig.2 (a), the manufacturing method of the package article coupling body 11 is equipped with the transverse heat welding process which forms a transverse heat welding part in the base material which has the hollow part continuous in the vertical direction. The transverse heat welding process of this embodiment is performed continuously to the longitudinal heat welding process in which a longitudinal heat welding portion is formed on the base material to obtain a base material having a hollow portion. The base material supplied to the longitudinal heat welding step is folded in two at the folding portion 24 along the flow direction D. In the longitudinal heat welding step, the longitudinal heat welded portion is formed by thermally welding the side portion opposite to the folding portion 24. By this vertical heat welding process, the base material is formed into a cylindrical shape.

  The contents 15 are continuously injected from the nozzle N into the hollow portion of the base material obtained in the longitudinal heat welding process. Although the content 15 of this embodiment is a liquid seasoning, it is not limited to this. The manufacturing method of the first embodiment is suitable when a liquid material capable of so-called submerged sealing is accommodated as the contents 15. The submerged seal is a method for forming a heat-welded portion on a base material in which a liquid material exists in a hollow portion.

  The transverse heat welding step includes a first stage in which the first transverse heat welded portion 51 is formed on a base material having a hollow portion obtained in the longitudinal heat welding step using a first mold, and a first transverse heat welded portion. A second stage in which the second transverse heat welded portion 52 is formed on the base material after forming 51 using a second mold.

The first transverse heat welded portion has a downstream heat welded portion 51a and an upstream heat welded portion 51b located on the upstream side of the downstream heat welded portion 51a in the base material flow direction D.
The first stage is performed under the condition that the auxiliary heat welding part 22 is formed. The second stage is performed under the condition that the main heat welding portion 21 is formed. The condition of the first stage for forming the sub heat welded portion 22 is a condition that is relaxed compared with the condition of the second stage for forming the main heat welded portion 21, so that the heat weld strength of the sub heat welded portion 22 is The heat welding strength of the main heat welding part 21 can be set lower.

  Examples of the conditions of the first stage and the second stage include temperature and pressure. For example, the first stage temperature is set lower than the second stage temperature. The conditions of the first stage and the second stage can be set according to the type of substrate used.

  The temperature of the first stage (the temperature of the first mold) is, for example, in the range of 70 ° C. or higher and 140 ° C. or lower. The first-stage pressure (the pressure of the first mold) is, for example, in the range of 100 kPa to 500 kPa. The temperature of the second stage (the temperature of the second mold) is, for example, in the range of 100 ° C. or higher and 180 ° C. or lower. The pressure in the second stage (second mold pressure) is, for example, in the range of 100 kPa to 500 kPa.

Next, details of the first stage and the second stage will be described.
As shown in FIG. 2 (b), in the first mold 71 used in the first stage, the surface that pressurizes the base material is a first heating unit 72 for forming the first transverse heat welding unit 51, And a first low thermal conductive portion 73 made of a material having lower thermal conductivity than the first heating portion 72. The 1st heating part 72 and the 1st low heat conduction part 73 are arranged so that it may partition into the upper stream side of the flow direction D of a base material, and the downstream side about the hollow part of a base material. The 1st heating part 72 has the downstream heating part 72a and the upstream heating part 72b located in the upstream in the flow direction D of a base material rather than this downstream heating part 72a. The first low heat conduction unit 73 is disposed between the downstream heating unit 72a and the upstream heating unit 72b.

  The 1st heating part 72 is comprised from the metal material. As a material which comprises the 1st low heat conductive part 73, inorganic materials, such as a resin material which has heat resistance, and a ceramic, are mentioned, for example. The first low heat conducting portion 73 of this embodiment is made of a fluororesin.

  As shown in FIG. 2C, in the second mold 81 used in the second stage, the surface that pressurizes the base material is composed of a second heating unit 82 for forming the second transverse heat welding unit 52. Has been. The 2nd heating part 82 is extended in the length which seals the hollow part of a substrate along a transverse direction. The second heating unit 82 has a shape corresponding to the outer shape of the inflow portion 23. The second heating unit 82 is made of a metal material.

  As shown in FIGS. 3A and 3B, the first mold 71 is provided on each of the pair of first rollers R1. The 1st side heat welding part 51 is formed between a pair of 1st roller R1. The temperature, pressure, and rotation speed of each first roller R1 are controlled in the same manner as a known filling and packaging machine. In addition, the surface which pressurizes the base material of the 1st metal mold | die 71 is formed in the curved surface shape so that a base material may be pressurized with a substantially constant pressure.

  As shown in FIGS. 3C and 3D, the second mold 81 is provided on each of the pair of second rollers R2. The second lateral heat welding part 52 is formed between the pair of second rollers R2. The temperature, pressure, and rotation speed of each second roller R2 are controlled in the same manner as a known filling and packaging machine. In addition, the surface which pressurizes the base material of the 2nd metal mold | die 81 is formed in the curved surface shape so that a base material may be pressurized with a substantially constant pressure.

  The speed of the base material in the first stage and the second stage can be set according to the temperature condition or pressure condition of the first mold 71 and the second mold 81, for example. The speed of this base material is, for example, in the range of 4 m / min to 30 m / min.

  The above-described packaged article assembly 11 is manufactured by, for example, a packaging and filling machine including a longitudinal heat welding mechanism, a transverse heat welding mechanism, a content supply mechanism, and a control unit. The filling and packaging machine is provided with a feeding unit that feeds a wound body of the substrate on which the substrate is wound. The longitudinal heat welding mechanism includes a pair of heating rollers. The pair of heating rollers is configured to be rotationally driven, and heats and pressurizes the base material passing between the rollers. The transverse heat welding mechanism includes the first roller R1 provided with the first mold 71 and the second roller R2 provided with the second mold 81, and the first roller R1 and the second roller R2 are: , Configured to be rotationally driven. The content supply mechanism supplies the content 15 from the nozzle N to the hollow portion of the base material through the vertical heat welding mechanism. The control unit is configured to control the rotation speed, temperature, pressure, and the like of the first roller R1 and the second roller R2, for example.

Next, the effect | action of the manufacturing method of the packaged article coupling body 11 of 1st Embodiment is demonstrated.
As shown to Fig.2 (a), the manufacturing method of the package article coupling body 11 is equipped with the transverse heat welding process which forms a transverse heat weld part in a base material. The transverse heat welding process has a first stage and a second stage. The first stage is a stage in which the first lateral heat welded portion 51 is formed on the base material on the condition that the sub heat welded portion 22 is formed using the first mold 71. In the second stage, the second lateral heat welded portion 52 is formed on the base material after the first lateral heat welded portion 51 is formed under the condition that the main heat welded portion 21 is formed using the second mold 81. It is a stage.

  Since the transverse heat welding process for forming the sub heat welding part 22 and the main heat welding part 21 in this way has a first stage using the first mold 71 and a second stage using the second mold 81, The stage condition and the second stage condition can be set separately. For this reason, in the transverse heat welding process in which both the auxiliary heat welding part 22 and the main heat welding part 21 are formed, it is easy to set conditions for heat welding.

  As shown to Fig.3 (a), in the 1st step using the 1st metal mold | die 71, with respect to the base material which passes between between a pair of 1st roller R1, first of the downstream heat welding part 51a by the downstream heating part 72a. Formation and pressurization by the first low thermal conduction portion 73 are performed in this order.

As shown in FIG. 3 (b), the upstream heat welding part 51 b is formed by the upstream heating part 72 b following the pressurization by the first low heat conduction part 73 on the base material.
When forming the downstream heat welding portion 51a and the upstream heat welding portion 51b, the hollow portion located between the downstream heat welding portion 51a and the upstream heat welding portion 51b is pressurized by the first low heat conduction portion 73. Yes. For this reason, while the inflow of the content 15 and gas to the hollow part located between the downstream heat welding part 51a and the upstream heat welding part 51b is suppressed, between the downstream heat welding part 51a and the upstream heat welding part 51b, The thermal welding of the base material located between is suppressed. Therefore, the base material located between the downstream heat welding part 51 a and the upstream heat welding part 51 b is suitably secured as a part for forming the inflow part 23 in the second stage using the second mold 81.

  As shown in FIG.3 (c), in the 2nd step using the 2nd metal mold | die 81, formation of the 2nd side heat weld part 52 is performed with respect to the base material which passes between between a pair of 2nd roller R2. . The second stage is performed corresponding to the position pressurized by the first heating unit 72 and the first low thermal conduction unit 73 in the first stage.

  As shown in FIG. 3D, as the base material advances between the pair of second rollers R2, the inflow portion 23 described above is formed, and a part of the upstream heat weld portion 51b is a packaging article. It remains as the secondary heat welding part 22 opened at the time of use.

The effects exhibited by the first embodiment are described below.
(1) The packaged article connector 11 has a structure in which the downstream end 33 of the inflow part 23 of the second packaged article 13 is sealed by the main heat welding part 21 of the first packaged article 12. For this reason, even if the contents 15 flow into the inflow portion 23 by opening the auxiliary heat welding portion 22 of the second packaging article 13, the outflow of the contents 15 to the outside of the first packaging article 12 is the main. It is suppressed by the heat welding part 21. Therefore, the contents 15 of the packaged article can be prevented from leaking.

  (2) The manufacturing method of the package article coupling body 11 includes a transverse heat welding step of forming a transverse heat weld portion on the base material. The transverse heat welding process has a first stage and a second stage. The first stage is a stage in which the first lateral heat welded portion 51 is formed on the base material on the condition that the sub heat welded portion 22 is formed using the first mold 71. In the second stage, the second lateral heat welded portion 52 is formed on the base material after the first lateral heat welded portion 51 is formed under the condition that the main heat welded portion 21 is formed using the second mold 81. It is a stage. According to this method, in the transverse heat welding process in which both the auxiliary heat welding part 22 and the main heat welding part 21 are formed, it is easy to set conditions for heat welding. Therefore, the packaged article assembly 11 having the auxiliary heat welding part 22 can be easily manufactured.

  (3) In the manufacturing method of the packaged article assembly 11, the first mold 71 is provided on each of the pair of first rollers R1, and the first transverse heat welding portion 51 is formed between the pair of first rollers R1. The The 1st metal mold | die 71 is comprised from the 1st heating part 72 for forming the 1st side heat welding part 51, and the material whose heat conductivity is lower than the 1st heating part 72, and pressurizes a base material. And a low heat conduction portion 73. The 1st heating part 72 and the 1st low heat conduction part 73 are arrange | positioned so that the hollow part of a base material may be divided into the upstream and downstream of the flow direction D of a base material. The 1st heating part 72 has the downstream heating part 72a and the upstream heating part 72b located in an upstream in the flow direction D of a base material. The first low heat conduction unit 73 is disposed between the downstream heating unit 72a and the upstream heating unit 72b.

  According to this method, the inflow of the contents 15 and the gas into the hollow portion located between the downstream heat weld portion 51a and the upstream heat weld portion 51b is suppressed, and the downstream heat weld portion 51a and the upstream heat weld portion. The thermal welding of the base material located between 51b is suppressed. Therefore, the base material located between the downstream heat welding part 51 a and the upstream heat welding part 51 b is suitably secured as a part for forming the inflow part 23 in the second stage using the second mold 81. Thereby, it becomes easy to suppress the inflow of the contents 15 and the gas into the inflow portion 23, and it becomes easy to stably manufacture the shape and physical properties of the inflow portion 23.

  (4) In the manufacturing method according to the first embodiment, the inflow of the content 15 into the hollow portion located between the downstream heat welding portion 51a and the upstream heat welding portion 51b is suppressed. For this reason, in the manufacturing method of the package article coupling body 11 that contains the liquid material as the contents 15, it is possible to perform submerged sealing in which the liquid material is continuously filled instead of intermittently filling the liquid material. In the submerged seal, the conveyance of the base material and the filling of the liquid material can be performed continuously, so that the production speed of the packaged article linking body 11 can be ensured comparable to the conventional packaged article continuum. Therefore, the manufacturing method of the present embodiment is also advantageous from the economical aspect.

(Second Embodiment)
2nd Embodiment of the manufacturing method of the package article coupling body 11 is described with reference to FIG. In the second embodiment, since the transverse heat welding process is different from the first embodiment in the manufacturing method of the packaged article assembly 11, this point will be mainly described, and the description of the parts common to the first embodiment will be omitted. .

  As shown in FIGS. 4 (a) and 4 (b), the first heating part 72 of the first mold 71 and the first transverse heat welding part 51 formed in the first stage are formed by hollow portions of the base material. Is not arranged so as to be divided into an upstream side and a downstream side in the flow direction D of the base material, and a hollow portion in which the upstream side and the downstream side communicate with each other exists on the side of the first lateral heat welded portion 51.

  As shown in FIG. 4C, the surface of the second mold 81 that pressurizes the base is more than the second heating unit 82 for forming the second lateral heat welding unit 52 and the second heating unit 82. And a second low thermal conductivity portion 83 made of a material having low thermal conductivity. The second low heat conduction unit 83 is made of the same material as the first low heat conduction unit 73 of the first embodiment. The second low heat conduction part 83 pressurizes from the first lateral heat welding part 51 toward the upstream side. The second low heat conducting portion 83 has a shape corresponding to the outer shape of the inflow portion 23.

The 1st metal mold | die 71 and the 2nd metal mold | die 81 are provided in 1st roller R1 and 2nd roller R2, respectively similarly to 1st Embodiment.
Next, the effect | action of the manufacturing method of the package article coupling body 11 of 2nd Embodiment is demonstrated.

  The second mold 81 used in the second stage has a second low thermal conductive portion 83 made of a material having lower thermal conductivity than the second heating portion 82. The second low heat conduction part 83 pressurizes the base material from the first transverse heat weld part 51 toward the upstream side in the base material flow direction D. Thus, in the part pressurized by the 2nd low heat conduction part 83, inflow of the content 15 and gas, and heat welding are suppressed.

The effects exhibited by the second embodiment will be described below.
(5) In the method for manufacturing the packaged article assembly 11, the second mold 81 is provided on each of the pair of second rollers R2. The second lateral heat welding part 52 is formed between the pair of second rollers R2. The second mold 81 includes a second heating unit 82 for forming the second lateral heat welding unit 52, a second low thermal conduction unit 83 made of a material having lower thermal conductivity than the second heating unit 82, and have. The second low heat conduction part 83 pressurizes the downstream side of the first lateral heat welding part 51.

  According to this method, it is possible to easily form the inflow portion 23 in which the inflow of the contents 15 and gas is suppressed and the shape and physical properties are stabilized in the portion pressurized by the second low heat conduction portion 83. it can.

  (6) In the manufacturing method of the second embodiment, the inflow of the contents 15 is suppressed in the portion pressurized by the second low heat conduction unit 83. Therefore, in the manufacturing method of the packaged article assembly 11 that contains the liquid material as the contents 15, it is advantageous as described in the section (4) of the first embodiment.

(Third embodiment)
3rd Embodiment of the manufacturing method of the package article coupling body 11 is described with reference to FIG. In the third embodiment, since the transverse heat welding process is different from that of the first embodiment in the method for manufacturing the packaged article assembly 11, this point will be mainly described, and the description of the parts common to the first embodiment will be omitted. .

  5 (a) to 5 (c) manufacture the packaged article assembly 11 using the first mold in which the upstream heating part 72b and the first low heat conduction part 73 in the first mold 71 of the first embodiment are omitted. Shows how to do. In this manufacturing method, conveyance of the base material and injection of the contents 15 into the packaging bag 14 are performed intermittently. That is, the contents 15 are injected into the upstream side of the transverse heat welded portion after the completion of the first stage and the second stage. Then, the 1st side heat weld part 51 is formed by performing a 1st step. Then, injection | pouring of the content 15 is stopped and a transverse heat welding part is formed by performing a 2nd step. In this case, a 1st metal mold | die is not provided in 1st roller R1, but it is comprised so that it may pressurize by pinching | interposing a base material intermittently.

  Here, in the manufacturing method of 1st Embodiment and 2nd Embodiment mentioned above, the 1st metal mold | die 71 which has the 1st low heat conduction part 73 or the 2nd metal mold | die 81 which has the 2nd low heat conduction part 83 is used. Yes. In this regard, as in the third embodiment, it is possible to change to a manufacturing method using a first mold in which the first low heat conduction portion 73 is omitted and a second mold in which the second low heat conduction portion 83 is omitted. is there.

  In the case of 3rd Embodiment, since conveyance of a base material and injection | pouring of the content 15 to the packaging bag 14 are performed intermittently, it becomes difficult to improve the productivity of the package article coupling body 11. In this respect, the manufacturing methods of the first embodiment and the second embodiment are advantageous.

(Fourth embodiment)
4th Embodiment of the manufacturing method of the package article coupling body 11 is described with reference to FIG. In the fourth embodiment, in the manufacturing method of the packaged article assembly 11, the transverse heat welding process is different from that of the first embodiment. Therefore, this point will be mainly described, and the description of the parts common to the first embodiment will be omitted. .

  As shown to Fig.6 (a), in the 1st step in the transverse heat welding process of 4th Embodiment, the 1st transverse heat weld part 61 is formed on the conditions in which the main heat weld part 21 is formed. Further, in the second stage in the transverse heat welding process of the fourth embodiment, the second transverse heat welded portion 62 is formed under the conditions for forming the auxiliary heat welded portion 22.

  As shown in FIG. 6B, in the fourth embodiment, the second mold 81 used in the first embodiment is used as the first mold 91. The surface for pressing the base material of the first mold 91 used in the fourth embodiment includes a first heating unit 92 for forming the first transverse heat welding unit 61. The 1st heating part 92 is extended in the length which seals the hollow part of a base material along a horizontal direction. The first heating unit 92 has a shape corresponding to the outer shape of the inflow portion 23.

  As shown in FIG.6 (c), in 4th Embodiment, the 2nd metal mold | die 101 which abbreviate | omitted the downstream heating part 72a of the 1st metal mold | die 71 used in 1st Embodiment is used. In the second mold 101 used in the second stage of the fourth embodiment, the surface that pressurizes the base material includes the second heating unit 102 for forming the second lateral heat welding unit 62, and the second low thermal conduction unit. 103.

  The second low heat conduction unit 103 is located downstream of the second heating unit 102 in the base material flow direction D. The second low heat conduction part 103 pressurizes the base material from the first lateral heat welding part 61 formed in the first stage toward the upstream side.

Next, the effect | action of the manufacturing method of the packaged article coupling body 11 of 4th Embodiment is demonstrated.
The second mold 101 used in the second stage has a second low thermal conduction part 103 made of a material having lower thermal conductivity than the second heating part 102. The second low heat conduction part 103 pressurizes the base material from the first lateral heat welding part 61 toward the upstream side in the base material flow direction D. Thus, in the part pressurized by the 2nd low heat conduction part 103, inflow of the content 15 and gas, and heat welding are suppressed.

The effects exhibited by the fourth embodiment will be described below.
(7) The manufacturing method of the packaged article assembly 11 includes a transverse heat welding step of forming a transverse heat weld portion on the base material. The transverse heat welding process has a first stage and a second stage. The first stage is a stage in which the first lateral heat welded portion 61 is formed on the base material on the condition that the main heat welded portion 21 is formed using the first mold 91. In the second stage, the second lateral heat welded portion 62 is formed on the base material after the first lateral heat welded portion 51 is formed under the condition that the secondary heat welded portion 22 is formed using the second mold 101. It is a stage. According to this method, in the transverse heat welding process in which both the main heat welded portion 21 and the sub heat welded portion 22 are formed, the heat welding conditions can be easily set. Therefore, the packaged article assembly 11 having the auxiliary heat welding part 22 can be easily manufactured.

  (8) In the manufacturing method of the packaged article assembly 11, the second mold 101 is provided on each of the pair of second rollers R2, and the second transverse heat welding portion 62 is formed between the pair of second rollers R2. The The second mold 101 is located on the downstream side in the base material flow direction D with respect to the second heating unit 102 for forming the second transverse heat welding unit 62, and the second heating unit 102. And a second low thermal conductive portion 103 made of a material having a lower thermal conductivity than 102. The second low heat conduction part 103 is configured to pressurize the base material from the first lateral heat welding part 61 toward the upstream side in the base material flow direction D. According to this method, in the second stage using the second mold 101, the base material passing between the pair of second rollers R2 is pressurized by the second low heat conduction unit 103, and by the second heating unit 102. The formation of the second transverse heat welded portion 62 is performed in this order. For this reason, the heat welding of the base material located between the 1st side heat weld part 61 and the 2nd side heat weld part 62 is suppressed. Therefore, the base material positioned between the first lateral heat welded portion 61 and the second lateral heat welded portion 62 is suitably secured as a portion for forming the inflow portion 23 in the second stage using the second mold 101. Is done. Thereby, it becomes easy to suppress the inflow of the contents 15 and the gas into the inflow portion 23, and it becomes easy to stably manufacture the shape and physical properties of the inflow portion 23.

  (9) In the manufacturing method of the fourth embodiment, the inflow of the contents 15 into the hollow portion located between the first lateral heat weld portion 61 and the second lateral heat weld portion 62 is suppressed. For this reason, in the manufacturing method of the package article coupling body 11 that contains the liquid material as the contents 15, it is possible to perform submerged sealing in which the liquid material is continuously filled instead of intermittently filling the liquid material. In the submerged seal, the conveyance of the base material and the filling of the liquid material can be performed continuously, so that the production speed of the packaged article linking body 11 can be ensured comparable to the conventional packaged article continuum. Therefore, the manufacturing method of the present embodiment is also advantageous from the economical aspect.

  (10) In the manufacturing method shown in the first embodiment (FIG. 2), after the first stage in the transverse heat welding process, if the heat welding strength of the downstream heat welding part 51a or the upstream heat welding part 51b is insufficient, the downstream heat Inflow of the contents 15 or gas may be allowed between the welded part 51a and the upstream heat welded part 51b. In order to further suppress the inflow of such contents 15 and gas, it is necessary to increase the thermal welding strength of the auxiliary heat welding portion 22 in the first stage, and the degree of freedom in setting the thermal welding strength of the auxiliary heat welding portion 22. Will drop. In this regard, in the manufacturing method according to the fourth embodiment, the main heat welding portion 21 is formed in the first stage and the sub heat welding portion 22 is formed in the second stage. For this reason, about the heat welding intensity | strength of the auxiliary | assistant heat welding part 22, it can set to the intensity | strength required after the 2nd step. Therefore, it is possible to increase the degree of freedom for setting the heat welding strength of the auxiliary heat welding part 22. Thereby, in the packaging article which opens the sub heat welding part 22 using the internal pressure in an accommodating part, it becomes possible to comprise so that it can open more easily using the sub heat welding part 22. FIG.

(Fifth embodiment)
5th Embodiment of the manufacturing method of the package article coupling body 11 is described with reference to FIG. In the fifth embodiment, since the transverse heat welding process is different from the first embodiment in the manufacturing method of the packaged article assembly 11, this point will be mainly described, and the description of the parts common to the first embodiment will be omitted. .

  As shown to Fig.7 (a), in the 1st step in the transverse heat welding process of 5th Embodiment, the 1st transverse heat welding part 61 is formed on the conditions in which the main heat welding part 21 is formed. Further, in the second stage in the transverse heat welding process of the fifth embodiment, the second transverse heat welded portion 62 is formed under the conditions for forming the auxiliary heat welded portion 22.

  As shown in FIG. 7B, the first heating unit 92 in the first mold 91 of the fifth embodiment has the same shape as the second heating unit 82 of the second mold 81 used in the first embodiment. have. The surface of the first mold 91 used in the fifth embodiment that pressurizes the base material has a first heating unit 92 for forming the first lateral heat welding unit 61 and a thermal conductivity than the first heating unit 92. It has the 1st low heat conduction part 93 comprised from a low material. The 1st heating part 92 is extended in the length which seals the hollow part of a base material along a horizontal direction. The first low heat conduction unit 93 is made of the same material as the first low heat conduction unit 73 of the first embodiment. The first low heat conduction part 93 pressurizes from the first lateral heat welding part 61 toward the upstream side.

As shown in FIG. 7C, the second heating unit 102 of the second mold 101 is configured to form a second lateral heat welding unit 62.
The effects exhibited by the fifth embodiment will be described below.

  The first mold 91 used in the first stage has a first low heat conduction part 93 made of a material having lower heat conductivity than the first heating part 92. The first low heat conduction portion 93 is configured to pressurize the base material from the first lateral heat weld portion 61 toward the upstream side in the flow direction D of the base material.

  In such a first stage, the formation of the first transverse heat welding part 61 by the first heating part 92 and the pressurization by the first low heat conduction part 93 are performed in this order on the base material passing between the pair of first rollers R1. Done in The base material can be temporarily brought into close contact with the first low heat conduction portion 93 by pressurization. Thus, in the pressurization part 63 pressurized by the 1st low heat conduction part 93, inflow of the contents 15 and gas is suppressed temporarily.

  (11) In the method for manufacturing the packaged article assembly 11, the first mold 91 is provided on each of the pair of first rollers R1. The 1st side heat welding part 61 is formed between a pair of 1st roller R1. The first mold 91 includes a first heating unit 92 for forming the first lateral heat welding unit 61, a first low thermal conduction unit 93 made of a material having lower thermal conductivity than the first heating unit 92, and have. The first low heat conducting portion 93 pressurizes the downstream side of the first lateral heat welding portion 61.

  According to this method, in the pressurizing unit 63 pressurized by the first low heat conducting unit 93, the inflow portion 23 in which the inflow of the contents 15 and gas is suppressed and the shape and physical properties are stabilized is easily formed. can do.

  (12) In the manufacturing method of the fifth embodiment, the inflow of the contents 15 is suppressed in the pressurizing unit 63 pressurized by the first low heat conducting unit 93. Therefore, in the manufacturing method of the packaged article assembly 11 that contains the liquid material as the contents 15, it is advantageous as described in the section (4) of the first embodiment.

(Example of change)
The above-described embodiments can be modified as follows.
In the package article linking body 11 of each embodiment, the first side edge 31 of the packaging bag 14 is formed by the main heat welding portion 21, but may be formed by the folding portion 24 of the packaging bag 14. Moreover, in the package article coupling body 11 of each embodiment, the second side edge 32 of the packaging bag 14 is formed by the transverse heat welded portion that is the main heat welded portion 21, but is also the main heat welded portion 21. It may be formed by the longitudinal heat welding part. The manufacturing method of each of the above embodiments may also be applied to the packaged article assembly 11 of such a modified example.

  In the package article linking body 11 of each embodiment, the packaging bag 14 has a three-side seal structure, but the folding portion 24 is changed to a packaging bag 14 having a four-side seal structure in which a longitudinal heat welding portion is configured. Also good. Furthermore, the packaging bag 14 may be changed to a vertical pillow packaging bag.

  -Although the manufacturing method of each embodiment has a longitudinal heat welding process, it may be changed to a manufacturing method having only a lateral heat welding process. That is, the manufacturing method of each embodiment can prepare the base material which has a hollow part beforehand, and can change into the manufacturing method of the packaged article coupling body 11 using the base material. However, in this case, it is difficult to increase the number of connected packaging articles and to inject the contents 15. In this respect, the manufacturing method having the longitudinal heat welding step as in each embodiment is advantageous because it becomes easy to increase productivity.

  -The 1st heating part 72 of the 1st metal mold 71 used with the manufacturing method of a 1st embodiment does not partition the upstream and downstream of the flow direction D of a base material, and the downstream heating part 72a and the upstream heating part 72b, You may further have the intermediate heating part which connects. That is, the 1st heating part 72 may be changed into the shape (frame shape or U shape) which has an intermediate heating part in addition to the downstream heating part 72a and the upstream heating part 72b. Moreover, the 1st heating part 72 may be changed into the shape with which the end of the downstream heating part 72a and the end of the upstream heating part 72b were connected, for example, the end of the downstream heating part 72a, and the upstream heating part 72b The shape may be changed so that one end is connected and the other end of the downstream heating unit 72a and the other end of the upstream heating unit 72b are connected. Thus, the downstream heating unit 72a and the upstream heating unit 72b only need to be separated from each other at the portion where the first low heat conduction unit 73 is disposed, and other portions may be connected.

  -Although the 1st metal mold | die 71 used with the manufacturing method of 1st Embodiment has the 1st low heat conductive part 73, the 1st low heat conductive part 73 was formed from the same material as the 1st heating part 72. It may be changed to one mold. In the case of this first mold, the temperature between the downstream heating unit 72a and the upstream heating unit 72b is controlled to be lower than that of the downstream heating unit 72a and the upstream heating unit 72b. Thereby, it is also possible to suppress the heat welding of the base material located between the downstream heat welding part 51a and the upstream heat welding part 51b. The second mold 81 used in the manufacturing method of the second embodiment, the second mold 101 used in the manufacturing method of the fourth embodiment, and the first mold 91 used in the manufacturing method of the fifth embodiment are similarly changed. be able to. In the case of this modified example, the temperature control of the first mold or the second mold may be complicated or it may be difficult to set the temperature to a desired temperature. In this respect, the manufacturing methods of the first embodiment and the second embodiment are advantageous.

  -In 2nd Embodiment, the 1st heating part 72 of the 1st metal mold | die 71 is such that the 1st side heat welding part 51 partitions the hollow part of a base material into the upstream and downstream of the flow direction D of a base material. It may be changed so that it is arranged.

  -In 4th Embodiment, the 2nd low heat conductive part 103 of the 2nd metal mold | die 101 may be abbreviate | omitted. Also in the fifth embodiment, the first low thermal conductive portion 93 of the first mold 91 may be omitted. Thus, when the 2nd low heat conductive part 103 and the 1st low heat conductive part 93 are abbreviate | omitted, conveyance of a base material and injection | pouring of the content 15 to the packaging bag 14 are performed intermittently. That is, the contents 15 are injected into the upstream side of the transverse heat welded portion after the completion of the first stage and the second stage. Then, the 1st side heat weld part 51 is formed by performing a 1st step. Then, injection | pouring of the content 15 is stopped and a transverse heat welding part is formed by performing a 2nd step.

-The manufacturing method of each embodiment may be further equipped with the cooling process which cools a transverse heat welding part after a 2nd step.
Next, the technical idea that can be grasped from the embodiment and the modified examples will be described below.

(A) A packaged article assembly for use in which the packaged article constituting the packaged article assembly is separated into each packaged article and then the packaged article is further accommodated in the packaged body.
(B) In the manufacturing method of the said packaged article coupling body, it has the vertical heat welding process which forms a vertical heat welding part in a base material, and the said horizontal heat welding process WHEREIN: The said hollow obtained by the said vertical heat welding process The manufacturing method of the packaged article coupling body by which the base material which has a part is supplied continuously.

  DESCRIPTION OF SYMBOLS 11 ... Packaging article coupling body, 12 ... 1st packaging article, 13 ... 2nd packaging article, 14 ... Packaging bag, 15 ... Contents, 21 ... Main heat welding part, 22 ... Sub heat welding part, 23 ... Inflow part, 24 ... Folding part, 31 ... First side edge, 32 ... Second side edge, 33 ... Downstream end, 51, 61 ... First lateral heat welding part, 52,62 ... Second lateral heat welding part, 71,91 ... 1st mold, 72, 92 ... 1st heating part, 72a ... Downstream heating part, 72b ... Upstream heating part, 73, 93 ... 1st low heat conduction part, 81, 101 ... 2nd mold, 82, 102 ... 1st 2 heating part, 83,103 ... 2nd low heat conduction part, D ... flow direction, R1 ... 1st roller, R2 ... 2nd roller.

Claims (7)

A packaging comprising a plurality of packaging articles including a first packaging article and a second packaging article connected to the first packaging article, wherein the packaging article comprises a packaging bag having an accommodating portion formed by a heat welded portion. A connected article comprising:
The heat-welded portion of the packaging bag has a main heat-welded portion and a sub-heat-welded portion having a heat-welding strength lower than that of the main heat-welded portion,
The packaging bag has an inflow portion into which the contents in the housing portion flows when the auxiliary heat welding portion is opened,
The inflow portion has a first side edge and a second side edge formed by the main heat welded portion or the folded portion of the packaging bag,
The packaged article assembly has a structure in which a downstream end of an inflow portion of the second packaged article is sealed by a main heat welding part of the first packaged article. A method for producing a packaged article assembly according to claim 1,
A transverse heat welding step for forming a transverse heat weld portion on a base material having a hollow portion continuous in the longitudinal direction,
The transverse heat welding process includes
A first step of forming a first transverse heat-welded portion on the base material under a condition that the auxiliary heat-welded portion is formed using a first mold;
And a second stage of forming the second transverse heat welded portion on the base material after the first transverse heat welded portion is formed under the condition that the main heat welded portion is formed using a second mold. A method for producing a packaged article assembly characterized by the above. The first mold is provided on each of a pair of rollers, and the first transverse heat welding portion is formed between the pair of rollers,
The first mold includes a heating unit for forming the first lateral heat welding unit,
It is composed of a material having a lower thermal conductivity than the heating part, and has a low thermal conduction part that pressurizes the base material,
The heating unit and the low heat conduction unit are arranged to partition the hollow portion into an upstream side and a downstream side in the flow direction of the base material,
The heating unit includes a downstream heating unit, and an upstream heating unit located upstream of the downstream heating unit in the flow direction of the base material,
The said low heat conductive part is a manufacturing method of the packaged article coupling body of Claim 2 arrange | positioned between the said downstream heating part and the said upstream heating part. The second mold is provided on each of a pair of rollers, and the second transverse heat welding portion is formed between the pair of rollers,
The second mold includes a heating unit for forming the second lateral heat welding unit,
Having a low thermal conductivity portion made of a material having lower thermal conductivity than the heating portion,
The said low heat conductive part is a manufacturing method of the packaged article coupling body of Claim 2 which pressurizes the said base material toward the upstream from the said 1st side heat weld part in the flow direction of the said base material. A method for producing a packaged article assembly according to claim 1,
A transverse heat welding step for forming a transverse heat weld portion on a base material having a hollow portion continuous in the longitudinal direction,
The transverse heat welding process includes
A first step of forming a first transverse heat-welded portion on the base material under a condition that the main heat-welded portion is formed using a first mold;
And a second stage of forming the second transverse heat welded portion on the base material after the first transverse heat welded portion is formed using the second mold under the condition that the auxiliary heat welded portion is formed. A method for producing a packaged article assembly characterized by the above. The second mold is provided on each of a pair of rollers, and the second transverse heat welding portion is formed between the pair of rollers,
The second mold includes a heating unit for forming the second lateral heat welding unit,
A low thermal conduction part that is located downstream of the heating part in the flow direction of the base material and is made of a material having a lower thermal conductivity than the heating part;
The said low heat conduction part is a manufacturing method of the packaged article coupling body of Claim 5 which pressurizes the said base material toward the upstream from the said 1st side heat weld part in the flow direction of the said base material. The first mold is provided on each of a pair of rollers, and the first transverse heat welding portion is formed between the pair of rollers,
The first mold includes a heating unit for forming the first lateral heat welding unit,
Having a low thermal conductivity portion made of a material having lower thermal conductivity than the heating portion,
The said low heat conduction part is a manufacturing method of the packaged article coupling body of Claim 5 which pressurizes the said base material toward the upstream from the said 1st side heat weld part in the flow direction of the said base material.