JP6114206B2 - Method for producing food in plastic packaging bags - Google Patents

Description

The present invention relates to a method of manufacturing a synthetic resin packaging bags food, especially food filled in the synthetic resin packaging bag of the structure having the heat seal structure of bag synthetic resin packaging focusing on ease of opening It relates to a manufacturing method .

  A packaging bag made by heat-sealing a synthetic resin film and processed into a bag shape is lightweight and easy to handle. Furthermore, since the volume after use is reduced, the time and effort for disposal is reduced. For this reason, it has grown greatly in recent years in place of cans and bottles. In particular, hot packs, boil sterilization, and retort sterilization are possible after filling, and are therefore frequently used in the food field. Such a packaging bag is filled with the contents at the same time as the supply of the synthetic resin film, and further sealed and cut. For example, a pillow packaging bag is a typical example.

  Synthetic resin film packaging bags use heat-resistant synthetic resin films that are resistant to hot packs, boil sterilization and retort sterilization, and prevent the contents from leaking. Is done. Therefore, since it is necessary to pursue the robustness as a packaging bag, the ease of opening cannot be said to be good. In general, when opening, the user cuts the packaging bag using scissors, a knife or the like, and takes out the contents. In other words, since another tool was used when opening the packaging bag, it was time-consuming.

  In view of this, various proposals have been made to improve the ease of opening in a packaging bag made of a synthetic resin film. For example, there is a packaging bag in which cuts are provided at predetermined positions on the bag body (for example, see Patent Document 1). According to the packaging bag of Patent Document 1, the packaging bag can be broken along the cuts, and convenience is improved. However, the user must tear the packaging bag with one hand while holding the body of the packaging bag with the other hand. In other words, both hands are inevitably used when opening. Also, depending on how the packaging bag is opened, the packaging bag may be unnaturally opened and the contents may spill out.

  Apart from this flow, a packaging bag has also been proposed in which the opening performance is improved by devising the structure of the heat seal part itself. For example, there is a packaging bag in which another film is sandwiched between heat seal portions and the heat seal strength at the heat seal portions is increased or decreased (see Patent Document 2). In addition, there are packaging bags and containers in which the pressure-bonding force is provided with a height difference by devising the shape of a seal block (heat platen) for heat sealing (see Patent Documents 3 and 4).

  According to the packaging bags disclosed in Patent Documents 2 to 4, the heat-sealed portion is easily destroyed appropriately, and can contribute to ease of taking out the contents. However, there is a problem in terms of productivity due to the use of separate materials and dedicated parts when manufacturing packaging bags. Therefore, it is not necessarily suitable for continuous production. In particular, packaging in the food field is required to suppress material costs as much as possible, and equipment costs and cost control are important.

  For example, there are many requests for easy opening without using tools in scenes such as sports and outdoor activities. Furthermore, opening with only one hand is also expected. In the fields of medical care and nursing care, it is also desired to reduce the burden of food intake and pharmaceutical administration. In particular, the viewpoint that the contents can be taken out without soiling the surroundings even when opening with only one hand has not been sufficiently emphasized in existing packaging bags.

  Therefore, various contents including foods can be stably sealed, and can be easily opened at the time of use, and a wearing bag that is easier to use than before has been desired.

Japanese Patent No. 4338175 Japanese Patent No. 436672 JP 2006-176128 A Japanese Patent No. 469416

  Thereafter, the inventor has developed a packaging bag satisfying both the stability of sealing and the ease of opening by reviewing the heat sealing conditions at the time of making a packaging bag made of a synthetic resin film.

The present invention has been made in view of the above-mentioned points. Along with the stable encapsulation of the contents, the food in a bag for synthetic resin packaging that can be easily opened with one hand at the time of use and has improved the burden at the time of use . A manufacturing method is provided.

That is, the invention of claim 1, wherein the jelly, Uiro, kuzumochi, agar, jelly, bean curd, konjac, miso or the food product to be selected from pastes in the lateral direction perpendicular to the feeding direction of the packing while the synthetic resin film material, synthetic resin film bodies was heat sealed to form a transverse heat-sealed portion, the in the transverse heat-sealed portion is opened by grasping with one hand you formed by cutting the transverse heat-sealed portion in the transverse direction plastic packaging A method for producing a bag- containing food , wherein the transverse heat seal part is a first temperature hot platen set in a first temperature range of 140 to 145 ° C and a second temperature range set in a second temperature range of 170 to 180 ° C. A first heat seal portion produced by pressure bonding with the first temperature heat platen, through the pressure bonding of the heat seal platen portion provided closely and in parallel with the temperature heat platen; It is formed as a second heat seal portion generated by pressure bonding with a temperature hot platen, and the transverse cutting in the horizontal heat seal portion is performed between the first heat seal portion and the second heat seal portion, and the synthesis Direction display parts for displaying the opening order as well as the opening direction on the resin packaging bag are provided at least in the middle of the synthetic resin packaging bag in the length direction and in the vicinity of the second heat seal part. The second heat seal portion exhibits a heat seal strength four times or more that of the first heat seal portion, so that the heat seal strength of the first heat seal portion of the synthetic resin packaging bag after the cutting is the first. 2 The direction of the intermediate portion in the longitudinal direction of the synthetic resin packaging bag when weakened than the heat seal strength of the heat seal portion and gripping the synthetic resin packaging bag with one hand The food filled in the synthetic resin packaging bag through the compression of the indicating part is pushed out from the first heat seal part side, and then the food through the direction display part in the vicinity of the second heat seal part Is extruded from the side of the first heat seal part, and relates to a method for producing a food in a bag for synthetic resin packaging that is opened by grasping with one hand .

According to another aspect of the invention, opened by the synthetic resin packaging bag, grab with one hand according to the synthetic resin film body according to claim 1 Center, a pillow bag having a center seal portion formed in the feed direction of the The present invention relates to a method for producing a food in a bag for synthetic resin packaging.

According to the method for producing a food product for a synthetic resin packaging bag according to the invention of claim 1, a synthetic resin film is filled while filling a food selected from yokan, uiro, kuzumochi, agar, jelly, tofu, konjac, miso, or kneaded food. forming a transverse heat-sealed portion by heat-sealing the synthetic resin film bodies in the transverse direction perpendicular to the feeding direction of the body, to form by cutting the transverse heat-sealed portion in the transverse direction in the transverse heat-sealed portion A method for producing a food in a plastic resin packaging bag that is opened by grasping with one hand , wherein the transverse heat seal part is a first temperature hot plate set in a first temperature range of 140 to 145 ° C. and 170 to 180. Through the pressure bonding of the heat seal platen provided close and in parallel with the second temperature hot platen set in the second temperature range of 0 ° C., A first heat seal portion that is generated and a second heat seal portion that is generated by pressure bonding by the second temperature hot platen, and the transverse cut in the horizontal heat seal portion is the first heat seal portion and the second heat seal. A direction indicator for displaying the order of opening as well as the opening direction on the synthetic resin packaging bag at least an intermediate portion in the length direction of the synthetic resin packaging bag and the second heat seal. The second heat seal portion has a heat seal strength four times or more that of the first heat seal portion, so that the second portion of the cut bag for the synthetic resin packaging is provided. The synthetic resin package when the heat seal strength of one heat seal portion is weaker than the heat seal strength of the second heat seal portion and the synthetic resin packaging bag is grasped with one hand The food filled in the synthetic resin packaging bag is pushed out from the first heat seal portion side through the compression of the direction display portion at the intermediate portion in the length direction of the bag, and then the second heat seal portion Since the food is pushed out from the first heat seal portion side through the compression of the direction display portion in the vicinity , the contents can be stably sealed and can be easily opened at the time of use. An improved synthetic resin-packed food for packaging can be provided.

Further, the inclination of the heat seal strength of both can be realized relatively easily without interposing a separate strength adjusting film. Furthermore, it becomes easy to distinguish a portion that is easy to open, and it is possible to open from the first heat seal portion side almost certainly according to the user's opening operation.

In addition, since the synthetic resin packaging bag is a center pillow bag provided with a center seal portion formed in the supply direction of the synthetic resin film body, the heat seal portion does not protrude from the side surface portion, and the synthetic resin packaging It becomes easier to grasp the bag surface portion of the bag by hand.

It is a schematic diagram of the manufacturing stage of the synthetic resin packaging bag. It is a whole perspective view of the synthetic resin packaging bag. It is a front view of the heat seal state at the time of bag making. It is a conceptual diagram of the change of heat seal temperature and the amount of heat fusion. It is a whole perspective view of the finished product of a synthetic resin packaging bag. It is a schematic diagram which shows the state by which the contents are extruded from the synthetic resin packaging bag. It is the whole front view of the synthetic resin packaging bag of another form.

With overall perspective view of a synthetic resin packaging bag 10 in the overview diagram and 2 stages of manufacture of plastics packaging bag 10 of FIG. 1, illustrating the heat-sealing structure S of synthetic resin packaging bag. The synthetic resin film body F constituting the synthetic resin packaging bag 10 is supplied to the illustrated bag making and filling apparatus 1, and the content C is filled simultaneously with the heat seal bonding of the film body F. The illustrated bag making and filling apparatus 1 is an example of a vertical pillow bag making apparatus.

  The synthetic resin film body F is supplied from a film roll (not shown) and guided to the guide tube 2 of the bag making and filling apparatus 1. The synthetic resin film body F is supplied in the vertical direction of the bag making and filling apparatus 1 while being in close contact with the guide tube 2 and wrapping the outside thereof. That is, the vertical direction is the supply direction Df of the synthetic resin film F. A hopper 4 for supplying the contents C is connected to the guide tube 2 inside the synthetic resin film body F. The contents C are filled in conjunction with the bag making of the synthetic resin film body F by a filling device (not shown) in the guide cylinder 2.

  Since the synthetic resin packaging bag 10 is a so-called individual package product, it is divided into capacities of predetermined contents C. Therefore, the synthetic resin film bodies F are heat-sealed in the lateral direction Dh orthogonal to the supply direction Df. The horizontal heat seal part 11 is formed by this heat sealing. Then, as shown in FIG. 2, the horizontal heat seal part 11 is cut up and down by the horizontal cutting part 12, and each synthetic resin packaging bag 10 is completed. The transverse heat seal part 11 is divided into two parts, a first heat seal part 13 and a second heat seal part 14, by cutting at the transverse cutting part 12. Thus, both ends of one synthetic resin packaging bag 10 are collectively formed as a first heat seal portion 13 and a second heat seal portion 14.

The synthetic resin packaging bag 10 disclosed in FIGS. 1 and 2 is a form called a center pillow bag or the like . A center seal portion (vertical seal portion, third heat seal portion) 16 is formed in the supply direction Df of the synthetic resin film body F. In the case of the synthetic resin packaging bag 10 adopting this form, the heat seal portion does not protrude from the side surface portion, so that the bag surface portion 15 of the synthetic resin packaging bag 10 can be easily grasped by hand.

  When the center seal portion 16 is formed, the synthetic resin film body F is bonded and heat-sealed at the same time when passing through the center heat seal board portion 3 (see FIG. 1). Thus, the original flat plate-shaped synthetic resin film body F is processed into a cylindrical shape. In addition to the illustration, the bag making and filling apparatus 1 includes a transport roller for transporting the synthetic resin film F in a timely manner, a controller for transport control, and the like.

  As can be understood from FIG. 1, the heat seal board 20 is used in forming the lateral heat seal part 11 of the synthetic resin packaging bag 10. The heat seal board part 20 is composed of two hot boards arranged in parallel with a first temperature hot board 21 and a second temperature hot board 22. A pressure receiving mat 25 that receives pressure from the heat seal board 20 is installed on the back surface of the heat seal board 20. After heat-sealing through the heat-sealing board 20 (21, 22), the horizontal heat-sealing part 11 is sandwiched and cooled by a cooling board (not shown). During this cooling, the transverse heat seal part 11 is cut in the transverse direction Dh by a cutter (not shown). In addition, if the heat | fever sealing of the horizontal heat seal part 11 is after heat sealing, you may perform in an appropriate | suitable step, and is good also immediately after completion of heat sealing of the heat seal board | substrate part 20.

FIG. 3 is an enlarged front view of the vicinity of the lateral heat seal portion 11 of the synthetic resin packaging bag 10 by the heat seal board portion 20. In the heat seal board part 20 of an Example, it is the arrangement | positioning provided in parallel which makes the 1st temperature heating board 21 the lower side of a paper surface, and the 2nd temperature heating board 22 the upper side. In particular , in the heat seal board 20, there is a difference in temperature between the first temperature hot board 21 and the second temperature hot board 22 set at a higher temperature than the first temperature hot board 21.

  Then, as shown in FIG. 3A, the first horizontal seal portion 13 is formed by heat seal pressure bonding of the first temperature hot platen 21, and the second horizontal seal portion 14 is formed by heat seal pressure bonding of the second temperature hot platen 22. Is done. In the drawing, the first heat seal portion 13 is light gray and the second heat seal portion 14 is dark gray. The center seal portion 16 is also dark gray. The time point in FIG. 5A is before cutting, and the first heat seal portion 13 and the second heat seal portion 14 are connected as the horizontal heat seal portion 11. Thereafter, as shown in FIG. 3B, the transverse heat seal portion 11 is separated into the first heat seal portion 13 and the second heat seal portion 14 by the transverse cutting portion 12 generated by the cutter during the pressure bonding by heat sealing. The The formation of the lateral heat seal part 11 and the cutting of the part are performed in a lump, and individual synthetic resin packaging bags 10 are formed.

  The relationship between the temperature of the hot platen and the fused state when the synthetic resin film body F is heat-sealed is shown using the conceptual diagram of FIG. The synthetic resin film body F is a multilayer film body obtained by laminating various resin films such as polyethylene, polypropylene, nylon (polyamide). The synthetic resin film body F in the illustrated example is a three-layer laminate product in the order of “k”, “l”, and “m” from the side in contact with the contents to the outer surface side. The resin composition constituting each layer is selected from the above resins in consideration of the compatibility of the resins. The k layers are bonded together by folding. “*” In the figure is a heat fusion site generated as a result of heat conduction, and is conceptually visualized. The more “*” displayed, the stronger the heat seal (high heat seal strength).

  In addition, the synthetic resin film body F can be laminated with a gas barrier resin film, a matte film, a printed film, or the like. Furthermore, an aluminum vapor deposition layer can be added to improve the light shielding property and the like. The type of synthetic resin film body is selected in consideration of the type of contents, storage period, application, size, durability, etc. The number of laminate layers is not limited to the three layers shown, but is increased to five or seven layers. Can increase functionality. It is appropriate. In addition, the resin film such as the k layer and the l layer is composed of a resin composition having cohesive fracture property or interlaminar fracture property in order to have both heat sealing ease and opening ease.

  FIG. 4A shows a state in which the synthetic resin film body F is heat-sealed by the first temperature hot platen 21. Although the heat seal temperature of the first temperature hot platen 21 depends on the type of the synthetic resin film body F, it is set to a first temperature range of approximately 135 to 155 ° C. The said 1st temperature range is the temperature which exhibits sufficient heat seal intensity | strength in the use assumption generally assumed in heat seal packaging. When the first temperature heating platen 21 presses the synthetic resin film body F, the heat of the first temperature heating platen 21 is conducted to the synthetic resin film body F. The heat of the first temperature hot platen 21 is conducted to the k layers that are in close contact with each other, and further to the vicinity of the l layer. As a result, the thermal fusion of the resin of the k layer and the surrounding layers proceeds mainly by the amount of heat in the first temperature range. Thus, heat sealing is performed by the first temperature hot platen 21, and the first horizontal sealing portion 13 is generated.

  FIG. 4B shows a state in which the synthetic resin film body F is heat-sealed by the second temperature hot platen 22. Although the heat seal temperature of the second temperature hot platen 22 depends on the type of the synthetic resin film body F, it is set to a second temperature range of approximately 170 to 190 ° C. The said 2nd temperature range is temperature which exhibits strong heat seal intensity | strength in heat seal packaging. When the second temperature hot platen 22 presses the synthetic resin film body F, as a result of the heat conduction of the second temperature hot platen 22, the heat fusion of the resin of the k layer and the surrounding layers by the amount of heat in the second temperature range. Advances. A series of processes is the same as in the case of the first temperature hot platen described above, and heat sealing is performed by the second temperature hot platen 22 to generate the second horizontal seal portion 14.

However , the second temperature range of the second temperature hot platen 22 is set to be higher than the first temperature range of the first temperature hot platen 21. The amount of heat conducted from the second temperature hot platen 22 to the synthetic resin film body F is larger than that of the first temperature hot platen 21. Accordingly, the amount of heat-sealing between the layers of the synthetic resin film body F that are in close contact with each other, and the resin layers in the vicinity thereof is increased. As the heat fusion progresses further and the joining proceeds, the strength as the heat seal portion is further increased.

  As understood from the illustrations of FIGS. 4A and 4B, the difference in the amount of heat conduction at the time of heat sealing is expressed as the number of display of “*”. In this way, the first heat seal part 13 and the second heat seal part 14 of the horizontal heat seal part 11 which are both ends of the synthetic resin packaging bag 10 are heat sealed with different heat seal strengths. Then, the heat seal strength of the first heat seal portion 13 of the synthetic resin packaging bag 11 after the transverse heat seal portion 11 is cut is weaker than the heat seal strength of the second heat seal portion 14. For this reason, the inclination of the heat seal strength of both can be realized relatively easily without interposing a separate strength adjusting film.

The evaluation method of the heat seal strength of the first heat seal part 13 and the second heat seal part 14 is based on the measurement specified in JIS K 0238 (1998). Since this evaluation method is a general and simple method for measuring the strength of a heat-sealed portion of a resin bag, it was applied as it is. Further, based on the measurement, the heat seal strength can be quantitatively grasped. Specifically, the heat seal strength of the second heat seal portion 14 is at least twice the heat seal strength of the first heat seal portion 13.

  More preferable heat seal strength is 3 times or more, and still more preferable heat seal strength is 4 times or more. The heat seal strength itself sufficiently secures the sealing performance of the first heat seal portion 13 and the second heat seal portion 14. In addition to this, by providing a difference in intentional heat seal strength, it is possible to open from the first heat seal portion 13 side almost certainly according to the user's opening operation. About the multiple difference of the heat seal intensity | strength of the 2nd heat seal part 14 and the 1st heat seal part 13, it derives from the evaluation in the below-mentioned Example. Moreover, a width | variety arises also in the material and structure of a synthetic resin film body.

  In the synthetic resin packaging bag 10, it is not necessary to open the center seal portion 16 itself. For this reason, the heat seal temperature of the center heat seal board part 3 is equal to or higher than the first temperature heat board 21, and the center seal part 16 is bonded with a stronger heat seal strength than the first heat seal part 13.

  FIG. 5 is an overall perspective view of the synthetic resin packaging bag 10 completed based on a series of steps. As described above, the heat seal strength differs between the first heat seal portion 13 and the second heat seal portion 14 of the synthetic resin packaging bag 10. However, in the 1st heat seal part 13 and the 2nd heat seal part 14, it cannot distinguish which is a part which is easy to open in appearance. Therefore, it is necessary to clearly indicate which heat seal part is the easy opening part so that the user who opens the synthetic resin packaging bag 10 is not confused.

For this reason , the synthetic resin packaging bag 10 is provided with the direction display unit 30 for displaying the opening direction. The direction display unit 30 shown in the figure includes a printing unit 31 for “thick arrow”, “push”, “push”, “open”, and “close”, “open”, “circled number 1”, and “circled number”. Two types of 2 ”seals 32 are illustrated. The printing unit 31 may perform printing on the synthetic resin film body F itself, or may laminate a printed film when the synthetic resin film body F is manufactured. The seal 32 is affixed to a necessary place afterwards. The display content of the direction display unit 30 is not limited to the illustration, and is appropriately defined by the type of content, the size and shape of the synthetic resin packaging bag, and the like. For example, coloring, graphics, and inscriptions of Braille are also possible.

  The “open arrow” in the figure is the pressure (compression) against the bag surface portion 15 of the synthetic resin packaging bag 10. Normally, no matter which part of the bag surface portion 15 is pressed, the heat seal on the first heat seal portion 13 side is almost surely determined from the difference in heat seal strength between the second heat seal portion 14 and the first heat seal portion 13. Destroyed. In particular, in the case of the illustrated synthetic resin packaging bag 10, the central “circled number 1” portion is first pressed, and then the “rounded number 2” portion in the vicinity of the second heat seal portion 14 Pressed. If it carries out like this, the heat seal of the 1st heat seal part 13 can be opened comparatively easily, and extrusion of the contents is also easy.

  The manner in which the contents are extruded from the synthetic resin packaging bag will be described with reference to the schematic diagram of FIG. Reference numeral 18 denotes an initial boundary line of the first heat seal portion 13, and 19 denotes a receding boundary line generated by pressing. FIG. 6A shows the first heat seal part 13 and the second heat seal part 14 before pressing. Both are in a close contact state by heat sealing. The adhesion part of the boundary line 18 and the 1st heat seal part 13 corresponds. In FIG. 5B, the heat seal adhesion starts to be slightly broken (peeled) from the inner side of the first heat seal portion 13 due to the pressure (open arrow) applied to the bag surface portion 15.

  In FIG. 6C, the degree of destruction of the first heat seal portion 13 is further increased due to the pressure (open arrow) applied to the bag surface portion 15. Finally, as shown in FIG. 4 (d), the destruction of the first heat seal portion 13 proceeds, and finally an opening portion is formed in the first heat seal portion 13, from which the contents C are outside the synthetic resin packaging bag 10. To leak. However, there is no breakage due to the strong heat seal on the second heat seal portion 14 side. Therefore, since the outflow direction of the contents is determined on one side, it is possible to prevent the excess fouling as well as easy opening of the synthetic resin packaging bag.

  FIG. 7 is a front view of a synthetic resin packaging bag 10x according to another embodiment. The heat sealing structure S for a synthetic resin packaging bag of the present invention is applied to a synthetic resin packaging bag 10x generally called a three-sided bag in addition to the center pillow bag disclosed in FIGS. In the case of the synthetic resin packaging bag 10x, the synthetic resin film body F is bonded by the side end seal portion 16x and processed into a cylindrical shape through the bag making and filling apparatus 1 shown in FIG. Then, the filling of the contents, the heat seal sealing of the first heat seal part 13 and the second heat seal part 14 which are the horizontal heat seal part 11, and the cutting in the horizontal heat seal part 11 are performed. This process is the same as the synthetic resin packaging bag 10 disclosed in FIG.

  Even in the synthetic resin packaging bag 10x, the heat seal strength of the first heat seal portion 13 is weaker than that of the second heat seal portion 14 and the side end seal portion 16x. From this, the content flows out only from the first heat seal portion 13 side through the pressure applied to the bag surface portion 15 of the synthetic resin packaging bag 10x. As an example of the direction display part 30 of the synthetic resin packaging bag 10x, there are provided two types of "thick arrow" and "opening" printing part 31, and "first press 1" and "next press 2" seal 32. It is done.

  Thus, the heat seal structure S of the synthetic resin packaging bag of the present invention can be applied to a wide range of bag-like materials on the premise of heat seal sealing. Of course, in addition to the illustration, it can be applied to a heat-sealed bag-like material such as a horizontal pillow packaging bag and a four-side sealed bag.

  The contents to be packaged in the synthetic resin packaging bag having the heat seal structure of the present invention are not particularly limited as long as the contents can be filled in the bag making and filling apparatus 1 disclosed in FIG. The synthetic resin packaging bag provided with the heat seal structure of the present invention is mainly useful as a packaging material for articles intended to be used up. Further, since the size and shape of the synthetic resin packaging bag itself is also free, it can be flexibly selected according to the type of contents.

  Specific contents include skin care products such as face wash, cleansing agent, lotion, emulsion, sunscreen agent (sunscreen cream), after shave lotion, shaving soap, liquid foundation, lipstick, lip gloss and the like. Hair care products such as shampoos, conditioners, rinses, hair color treatments, hair styling products, pomades, hair tonics, and hair liquids. Oral care products such as toothpastes, mouth washes, and mouthwashes. In addition, perfumes such as eau de cologne, eau de toilette, parfum and the like can be mentioned. Also included are pharmaceuticals such as liquids and ointments, liquid soaps, medicinal oils and the like. Furthermore, it is suitable for packaging a wide range of contents such as paints, paints, adhesives, various chemical products, reagents, reactants, disinfectants, deodorants, water purification agents, agricultural chemicals, fertilizers and the like.

In addition , the main content to be packaged in the synthetic resin packaging bag having the heat seal structure of the present invention is food. For example, seasonings such as soy sauce, miso, sauce, ketchup, mayonnaise, fish sauce, salsa sauce, sauce, bittern, brown sauce, demiglace sauce, white sauce (bechamel sauce), hollandaise sauce, curry sauce, anchovy etc. Is mentioned. Also included are honey, maple syrup, chocolate sauce, starch syrup, liquid sugar, whipped cream, jam, marmalade, peanut butter, butter, margarine, cheese, yogurt and the like.

Furthermore, existing foods that are marketed as retort and canned foods, stew, porridge, stewed foods, kneaded foods, konnyaku, liver paste, tofu, jelly, agar, kuzumochi, ice cream, squid, red beans, etc. It covers almost all foods such as bean sauce. In addition to this, the food that is the content is yokan.

  According to the article in a bag for a synthetic resin packaging provided with the heat seal structure of the present invention, it can be easily opened with one hand, which is convenient when it is added at the time of work. In particular, it is subdivided on the premise that the predetermined amount is used up, and it is easy to grasp the additional amount. Also, if the hand is wet, it is difficult to break the opening. However, since the contents can be pushed out by pressing, an extra burden is not required for opening the shampoo, for example, when taking a bath.

  In addition, since the various foods listed above can be included in the packaging object of the synthetic resin packaging bag having the heat seal structure of the present invention, it is possible to provide a synthetic resin packaging bag-containing food that can be easily opened. For example, it is effective when oil is attached to a hand and becomes slippery during cooking. In addition, the burden on the caregiver when opening the packaging bag is reduced, which helps care. In addition, it is convenient for replenishing food, salt, sugar and other nutrients during sports and outdoors. In particular, it has been epoch-making because no attempt has been made to make yokan easy to eat. At the same time, it is possible to propose a new way of eating that is not found in existing candy.

[Production of synthetic resin packaging bags]
The inventors prepared a synthetic resin film used for general hot packs, boil sterilization, and retort sterilization packaging, and used “bag filling and packaging machine 2030” manufactured by ORIHIRO ENGINEERING CO., LTD. The shape of the center pillow bag was made. The contents to be filled were yokan (yokan) made from red beans, sugar, agar, etc. as raw materials by a conventional method.

  The size of the synthetic resin packaging bag (center pillow bag) was set to 153 mm in the total length of the synthetic resin film supply direction, 30 mm in the lateral direction (width) orthogonal to the supply direction, and 12 to 14 mm in thickness. The length (supply direction) of the first heat seal portion and the second heat seal portion constituting the horizontal heat seal portion was set to 10 to 15 mm. The capacity of the can as the contents was set to 40 g.

[Conditions for heat sealing]
Using the bag filling and packaging machine described above, the hot platen was adjusted to the first temperature hot platen set temperature (° C) and the second temperature hot platen set temperature (° C) shown in Table 1, and the heat seal time ( Second), the bag was made while filling by heat sealing (Prototype Examples 1 to 5). In addition, the center seal part was heat-sealed by the center heat seal board | substrate part of the vertical direction set to 140 degreeC and 180 degreeC on either side. After heat sealing through the hot platen, the horizontal heat seal portion was cooled by the cooling plate, and at the time of the cooling, the horizontal heat seal portion was cut in the horizontal direction with a cutter and separated into upper and lower portions.

[Measurement of heat seal strength]
The heat seal strength of the synthetic resin packaging bag was measured according to JIS K 0238 (1998). Specifically, the synthetic resin packaging bag (food in a bag) after heat-sealing packaging was cut in the lateral direction at an intermediate position of the full length to scrape the contents, and the inside of the bag was washed with water. Thereafter, the cut bag was cut in the length direction while maintaining the width of 15 mm, including the first heat seal portion side and the second heat seal portion side. By doing so, a test piece having a heat seal portion in the middle was obtained. Therefore, each test piece was pulled using a tensile tester, and the load at the time of breaking the heat seal portion was measured. The unit of intensity in the measurement is “N / 15 mm”.

  Table 1 shows the results of the first temperature hot platen set temperature, the second temperature hot platen set temperature, the heat seal time, the first heat seal portion strength, and the second heat seal portion strength for Prototype Examples 1 to 5. .

[Consideration of hot plate temperature and heat seal strength]
According to the synthetic resin packaging bags of Prototype Examples 1 to 4, the difference in strength between the first and second heat seal parts is twice or more, and in particular, for Prototype Examples 1 to 3, it is four times or more. Thus, since the clear strength difference is provided in the heat seal part, when the synthetic resin packaging bag is pressed, only the first heat seal part can be opened first with certainty.

  In Prototype Example 4, since the second temperature hot platen set temperature was somewhat low, it is considered that the strength of the second heat seal portion was weakened. In Prototype Example 5, the second temperature hot platen set temperature is too low, and there is no practical difference in heat seal strength.

[Pressure strength test]
In addition to Prototype Example 1 above, bag making while filling the contents of the canister by heat sealing under the conditions of the first temperature hot platen setting temperature, the second temperature hot platen setting temperature, and the heat sealing time shown in Table 2 Prototype examples 6 to 8 were also prepared. Prototype Example 1 and Prototype Examples 6 to 8 all have the same shape and capacity.

  The filled synthetic resin packaging bag (food in a synthetic resin packaging bag) was placed on a measurement part of a commercially available weight scale, and the intermediate portion in the length direction of the synthetic resin packaging bag was pressed. And the load value of the weight scale when the contents were exposed from the 1st heat seal part side of the synthetic resin packaging bag was read. Therefore, the numerical value was used as the pressure strength value (kgf) in the synthetic resin packaging bag. The results are shown in Table 2.

[Consideration of pressure strength test]
According to Prototype Examples 1 and 6, since the first temperature hot platen set temperature and the second temperature hot platen set temperature are appropriately separated, it is easy to open the first heat seal part and ensure the strength of the second heat seal part. Is properly planned. It is a value that is not extremely high like the pressure strength value in the table. However, in the prototype examples 7 and 8, since the first temperature hot platen set temperature and the second temperature hot platen set temperature are close to each other, the mutual heat seal strength is increased. Therefore, the ease of opening the first heat seal part is retreated, and the pressure strength value is also increased.

[Summary]
As can be seen from the measurement of the heat seal strength and the pressure strength test, in the case where a difference in heat seal strength is provided by a single type of synthetic resin film, heat fusion at different heat seal temperatures is extremely simple and simple. In particular, the adjustment of the heat seal strength can be realized by changing only the temperature setting of the hot platen of the bag filling and packaging machine. In addition, existing filling, bag making and cutting synthetic resin packaging bags can be used without greatly changing the processing technology and processing equipment. Accordingly, it is possible to appeal the ease of opening to the user side, and it is possible to provide the heat seal product to the producer side without excessive capital investment.

The food in a plastic resin packaging bag produced by the production method of the present invention has a heat-sealing structure that realizes a difference in strength at the time of opening by controlling the heat-sealing temperature, so that it is easier to open than existing bag-like products. Can be realized. Therefore, it is promising as an alternative to existing bag-like products by heat sealing. Moreover , the ease of eating can be improved more than before from the ease of opening. This can also open up new ways of use.

DESCRIPTION OF SYMBOLS 1 Bag making and filling apparatus 2 Guide cylinder 3 Center heat-sealing board part 4 Hopper 10, 10x Plastic resin packaging bag 11 Lateral heat-sealing part 12 Lateral cutting part 13 1st heat-sealing part 14 2nd heat-sealing part 15 Bag surface part 16 Center seal part 20 Heat seal board part 21 First temperature hot board 22 Second temperature hot board 25 Pressure receiving mat 30 Direction display part 31 Printing part 32 Seal F Synthetic resin film body C Contents S Heat seal structure of synthetic resin packaging bag Df Synthetic resin film supply direction Dh Transverse direction orthogonal to supply direction

Claims (2)

Youkan, Uiro, kuzumochi, agar, jelly, bean curd, konjac, miso or heat-sealing the synthetic resin film bodies in the transverse direction perpendicular to the feed direction of the synthetic resin film material while filling the food product is selected from the kneaded, Te to form a transverse heat-sealed portion, met production method of a synthetic resin for packaging bags food opened by grasping with one hand you formed by cutting the transverse heat-sealed portion in the transverse direction in the transverse heat-sealed portion And
The horizontal heat seal portion includes a first temperature heating plate set in a first temperature range of 140 to 145 ° C. and a second temperature heating plate set in a second temperature range of 170 to 180 ° C. in close proximity to each other. Formed as a first heat seal portion generated by pressure bonding with the first temperature hot platen and a second heat seal portion generated by pressure bonding with the second temperature heat plate through pressure bonding of the heat seal plate portion,
The transverse cutting in the transverse heat seal part is performed between the first heat seal part and the second heat seal part,
Direction display portions for displaying the opening order as well as the opening direction on the synthetic resin packaging bag are provided at least at an intermediate portion in the length direction of the synthetic resin packaging bag and at two locations near the second heat seal portion. And
When the second heat seal portion exhibits a heat seal strength four times or more that of the first heat seal portion, the heat seal strength of the first heat seal portion of the synthetic resin packaging bag after the cutting is the second. The synthetic resin packaging, which is weaker than the heat seal strength of the heat seal portion, through the compression of the direction display portion at the intermediate portion in the length direction of the synthetic resin packaging bag when the synthetic resin packaging bag is grasped with one hand The food filled in the bag is pushed out from the first heat seal part side, and then the food comes from the first heat seal part side through compression of the direction display part near the second heat seal part. A method for producing a food in a bag for synthetic resin packaging, wherein the food is opened by grasping with one hand . The synthetic resin packaging bag, the synthetic resin film body of synthetic resin packaging bags of opening by gripping with one hand of Claim 1 Center, a pillow bag having a center seal portion formed in the feed direction of the A method for producing food .

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