CN112497885A - Compounding process of high-temperature-resistant cooking bag - Google Patents

Abstract

The invention relates to the field of processing of cooking bags, in particular to a compounding process of a high-temperature-resistant cooking bag. The method comprises the following steps of (1) enabling a PET film to be opposite to an aluminum foil, extruding glue between the PET film and the aluminum foil, simultaneously pressing the PET film and the aluminum foil, and heating to 35-40 ℃ to obtain a PET-aluminum foil film; step 2, extruding glue between the PET-aluminum foil film and the nylon film, simultaneously pressing the PET-aluminum foil film and the nylon film, and heating to 40-45 ℃ to obtain a composite film; step 3, heating the composite film to 40-50 ℃ and keeping the temperature for 50-70 hours, and then cutting the composite film into useless waste edges and a plurality of bag bodies which can be used for subsequent processes; and the end part of the composite film passes through the space between the compression roller and the supporting roller, then the end part of the composite film is pulled, so that the composite film slides relative to the compression roller, and meanwhile, a bag body pushed out by a push plate hinged on the supporting roller is collected. The compounding process of the high-temperature resistant cooking bag does not need to transport the composite film in a whole roll, so that the workload of transportation is reduced, and the processing efficiency is improved.

Description

Compounding process of high-temperature-resistant cooking bag

Technical Field

The invention relates to the field of processing of cooking bags, in particular to a compounding process of a high-temperature-resistant cooking bag.

Background

The retort pouch is a composite plastic film pouch capable of being heated, and has the advantages of both a can container and a boiling-water-resistant plastic pouch, so that the retort pouch is also called a 'soft can', and is an ideal food packaging container. The existing cooking bag generally comprises a plurality of procedures of printing, compounding, bag making, detecting and the like, wherein the compounding procedure is to compound at least two layers of different layered structures together to form a compound film, so that the cooking bag has the advantage of integrating different layered structures.

At present in the manufacturing process, the complex film through compound process processing rolls earlier, then unified transportation to the system bag process again, but the weight of the complex film of rolling is great, the work load of transportation is great, and still need take off the wind-up roll from the equipment that is used for rolling the complex film, and install to the equipment of system bag process on, careless complex film that leads to the rolling drops during the installation slightly easily, injures the workman by a crashing object, and pull down, the installation also needs the certain time, lead to machining efficiency to reduce.

Disclosure of Invention

The invention aims to provide a compounding process of a high-temperature-resistant cooking bag without transporting a composite film in a whole roll, so that the transportation workload is reduced, and the processing efficiency is improved.

In order to achieve the purpose, the invention adopts the following technical scheme: a compounding process of a high-temperature-resistant cooking bag comprises the following steps:

step 1, enabling a PET film and an aluminum foil to face each other, extruding glue between the PET film and the aluminum foil, simultaneously pressing the PET film and the aluminum foil, and heating to 35-40 ℃ until the PET film and the aluminum foil are compounded to obtain a PET-aluminum foil film;

step 2, enabling the nylon film to be opposite to the aluminum foil on the PET-aluminum foil film, extruding glue between the PET-aluminum foil film and the nylon film, simultaneously pressing the PET-aluminum foil film and the nylon film, and heating to 40-45 ℃ until the PET-aluminum foil film and the nylon film are compounded to obtain a composite film;

step 3, heating the composite film to 40-50 ℃ and keeping the temperature for 50-70 hours, then cutting the composite film into useless waste edges and a plurality of bag bodies which can be used for subsequent processes, and enabling the bag bodies and the waste edges to have adhesion parts during cutting; and the end part of the composite film passes through the space between the compression roller and the supporting roller, then the end part of the composite film is pulled, so that the composite film slides relative to the compression roller, and meanwhile, a bag body pushed out by a push plate hinged on the supporting roller is collected.

The beneficial effect of this scheme does:

1. and 3, cutting the composite film, wherein the cut bag body is used for processing a cooking bag, and the waste edge cannot be utilized and belongs to a waste part. Compare with the whole system bag processes of transporting of the complex film of tradition with the rolling, need not to transport the slitter edge in this scheme, reduce the weight that needs the transportation part to reduce the work load of transportation. Secondly, the complex film has been cut in this scheme, so the bag body of transporting to the system bag process can directly use, need not to install the complex film of rolling in advance in the equipment of system bag, reduces the time that the change membrane book needs, further improves machining efficiency.

2. Because the bag body has been cut, but the bag body after cutting passes through the conveyer belt rapid transport to the system bag process, and when transporting through the conveyer belt, the bag body can tile on the conveyer belt one by one moreover, and it is more convenient to take when system bag process adds man-hour, further makes things convenient for follow-up processing.

Further, the pressure applied to the nylon film and the PET-aluminum foil film in the step 2 is 0.28-0.32 mPa.

The beneficial effect of this scheme does: the pressure to the nylon membrane and the PET-aluminum foil membrane is small in the scheme, and the nylon membrane and the PET-aluminum foil membrane can be prevented from being greatly deformed to cause damage to the nylon membrane and the PET-aluminum foil membrane.

Further, the gluing amount of the glue in the step 2 is 2-2.2 g/square meter.

The beneficial effect of this scheme does: the gluing amount of the glue is small, so that the situation that the glue is too much and overflows from the side edge of the nylon film and the PET-aluminum foil film when the nylon film and the PET-aluminum foil film are pressed to cause glue waste or the glue is adhered to the surface of the composite film to cause the composite film to be adhered to other structures of equipment can be avoided.

Further, a winding roller is adopted to wind the slitter edges in the step 3.

The beneficial effect of this scheme does: can roll up the slitter edge fast through the wind-up roll, can also make the bag body of being connected with the slitter edge remove when carrying out the rolling to the slitter edge moreover to avoid the operator direct and bag body contact, lead to the bag body to receive the pollution.

Further, a guide roller is arranged between the supporting roller and the winding roller in the step 3.

The beneficial effect of this scheme does: the guide roll guides the slitter edge, and avoids the slitter edge from moving and interfering with other structures of equipment in the winding process.

Further, the winding pressure of the waste edge in the step 3 is 0.25-0.3 mPa.

The beneficial effect of this scheme does: along with the rolling, the number of the waste edges rolled on the rolling roller is increased, and under the condition that the rotating speed of the rolling roller is the same, the length of the rolled waste edges in unit time is increased, so that the tension on the waste edges and the composite film is increased, and the waste edges and the composite film are easy to deform. This scheme can control the slew velocity of wind-up roll through control rolling pressure for the pulling force to the complex film is the same, avoids the complex film to take place obvious deformation.

Drawings

FIG. 1 is an elevational vertical cross-sectional view of a support roller for use with an embodiment of the present invention;

fig. 2 is a schematic view illustrating a state after the support roller of fig. 1 is rotated.

Detailed Description

The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: composite film 1, compression roller 2, main shaft 3, lug 31, push pedal 32, conveyer belt 4, negative pressure hole 41, negative pressure chamber 42, support bar 43.

Examples

A compounding process of a high-temperature-resistant cooking bag comprises the following steps:

step 1, enabling a PET film and an aluminum foil to face each other, extruding glue between the PET film and the aluminum foil, simultaneously pressing the PET film and the aluminum foil, and heating to 35-40 ℃ until the PET film and the aluminum foil are compounded to obtain a PET-aluminum foil film;

step 2, enabling the nylon film to be opposite to the aluminum foil on the PET-aluminum foil film, extruding glue between the PET-aluminum foil film and the nylon film, wherein the gluing amount is 2-2.2 g/square meter, simultaneously applying pressure to the PET-aluminum foil film and the nylon film, keeping the pressure at 0.28-0.32 mPa, heating to 40-45 ℃ until the PET-aluminum foil film and the nylon film are compounded, and obtaining a composite film;

step 3, heating the composite film to 40-50 ℃, keeping the temperature for 50-70 h, cutting the composite film into useless waste edges and a plurality of bag bodies which can be used for subsequent processes, and enabling the bag bodies and the waste edges to have adhesion parts during cutting; the end part of the composite film penetrates through the space between the compression roller and the supporting roller, then the end part of the composite film is wound on the winding roller, the composite film is pulled by the winding roller to slide relative to the compression roller, and meanwhile, a bag body pushed out by a push plate hinged on the supporting roller is collected; meanwhile, a guide roller is arranged between the supporting roller and the winding roller to guide the waste edge; when the slitter edge is rolled, the rolling pressure of the slitter edge is kept at 0.25-0.3 mPa, and specifically, the tension of the composite film is detected through the tension sensor in the actual processing process.

The supporting roller related to the step 3 comprises a main shaft 3 opposite to the compression roller 2, at least one pushing unit is axially distributed on the main shaft 3 and comprises a plurality of pushing assemblies which are uniformly distributed along the circumferential direction of the main shaft 3, each pushing assembly comprises a convex block 31 and a push plate 32, the middle part of each push plate 32 is hinged with the convex block 31, and the main shaft 3 is positioned above the winding roller and the cutter.

Adjacent lateral wall rounding off of push pedal 32 and the equal radius angle of apex angle of push pedal 32 cause the damage to complex film 1 when avoiding push pedal 32 and complex film 1 to contact, and during the backing roll use, because the backing roll is higher than cutter and wind-up roll, so lie in backing roll and compression roller 2 between complex film 1 the effect of backing roll under the arch that makes progress, 1 downward slopping of complex film of the backing roll left and right sides promptly. Adopt conveyer belt 4 and backing roll cooperation in step 3 for with the bag body to bag process transportation, it is concrete, conveyer belt 4 is located the right side of main shaft 3, and the wind-up roll is located the below of conveyer belt 4, the left end of conveyer belt 4 pastes with complex film 1 mutually, and promotes bag body right-hand member at push pedal 32 right-hand member, leads to bag body right-hand member and slitter edge separation and right perk back, and conveyer belt 4 surface pastes with the bag body mutually. A negative pressure cavity 42 is arranged in the transmission belt, a plurality of negative pressure holes 41 communicated with the negative pressure cavity 42 are formed in the surface of the transmission belt 4, a support bar 43 shaped like a Chinese character 'jing' is further arranged in the negative pressure cavity 42, the support block is also made of flexible rubber, and a plurality of through holes are formed in the support block, so that the negative pressure cavity 42 can keep negative pressure everywhere.

The composite film 1 in the step 3 is opposite to the push plate 32 when being positioned on the left side of the main shaft 3, then along with the clockwise rotation of the main shaft 3, the push plate 32 on the left side gradually rotates to the position opposite to the compression roller 2, the push plate 32 rotates clockwise under the action of the compression roller 2, and the left end of the bag body is pushed leftwards by the left end of the push plate 32, so that the left end of the bag body is separated from the waste edge. Along with the rotation of wind-up roll, complex film 1 moves right the right side to main shaft 3, meanwhile, main shaft 3 rotates, make push pedal 32 along with 1 synchronous motion of complex film, after lug 31 of being connected with push pedal 32 rotates to the right side of compression roller 2, anticlockwise rotation takes place under compression roller 2's effect for push pedal 32, the right-hand member of the bag body is promoted right with push pedal 32's right-hand member, make the right-hand member of the bag body perk right and contact with conveyer belt 4, the right-hand member of the bag body is adsorbed on conveyer belt 4 this moment, along with conveyer belt 4's operation, the bag body is driven right, separate with the slitter edge, the last bag body pastes completely on conveyer belt 4, be transported to the system bag process by conveyer belt 4.

When the bag making machine adopts the compression roller 2 and the supporting roller, the two ends of the bag body can be respectively pushed by the two ends of the pushing plate 32, so that the bag body is separated from the waste edges, and finally the bag body can be transported to a bag making process by the conveyor belt 4. Compared with the method that the bag body is completely cut off by the cutter for transportation, when the bag body is cut by the annular cutter, the bag body is easily clamped into the annular cutter and is difficult to fall out, and if the bag body is blown downwards by air flow, the bag body is easily displaced by the air flow and is difficult to accurately fall on the conveyor belt 4 because the weight of the bag body is smaller when the bag body is separated from the cutter; and the air current still makes the bag body take place the upset easily, need adjust the bag body when the system bag, and the equipment that this embodiment adopted can fix a position the bag body, avoids the upset of bag body and aversion.

Specifically, the present invention provides embodiments 1 to 3, the operation steps of embodiments 1 to 3 are the same as the above steps, and only the heating temperature of step 1, the sizing amount and pressure of step 2, the heating temperature and heating time of step 3, and the winding pressure in step 3 are different, and specific values are shown in the following table:

on the basis of the example 1, a comparative example 1 is designed, and the other operations of the steps 1 to 3 are the same as those of the example 1 except that the composite film is not cut in the step 3 of the comparative example 1, or the structure of the press roll and the support roll is not adopted, the composite film is firstly wound, then the whole rolled composite bag is transported to a bag making process, and then the composite film is cut by a cutter.

Counting the time required for producing the bag bodies with the same quantity and specification and the number of workers required in the processing process, and calculating the ratio of the time length of the comparative example 1 to the time length of the example 1 on the basis of the time length required by the example 1; based on the number of workers required in the example, the ratio of the number of workers required in comparative example 1 to the number of workers in example 1 was calculated, and the test results were as follows:

	length of time ratio	Number of workers required
			Example 1	1	1
Comparative example 1	1.45	1.67

It can be seen from the comparison tests that the time required by the embodiment is shorter, the number of required workers is less, and the workload of the workers can be reduced while the production efficiency is improved. In addition, in the embodiment 1, the coiled composite film does not need to be carried, so that the composite film with larger weight can be prevented from falling down and injuring workers, and the production safety is improved.

The foregoing is merely an example of the present invention and common general knowledge in the art of designing and/or characterizing particular aspects and/or features is not described in any greater detail herein. It should be noted that, for those skilled in the art, without departing from the technical solution of the present invention, several variations and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims (6)

1. A composite process of a high-temperature-resistant cooking bag is characterized by comprising the following steps: the method comprises the following steps:

step 1, enabling a PET film and an aluminum foil to face each other, extruding glue between the PET film and the aluminum foil, simultaneously pressing the PET film and the aluminum foil, and heating to 35-40 ℃ until the PET film and the aluminum foil are compounded to obtain a PET-aluminum foil film;

step 2, enabling the nylon film to be opposite to the aluminum foil on the PET-aluminum foil film, extruding glue between the PET-aluminum foil film and the nylon film, simultaneously pressing the PET-aluminum foil film and the nylon film, and heating to 40-45 ℃ until the PET-aluminum foil film and the nylon film are compounded to obtain a composite film;

step 3, heating the composite film to 40-50 ℃ and keeping the temperature for 50-70 hours, then cutting the composite film into useless waste edges and a plurality of bag bodies which can be used for subsequent processes, and enabling the bag bodies and the waste edges to have adhesion parts during cutting; and the end part of the composite film passes through the space between the compression roller and the supporting roller, then the end part of the composite film is pulled, so that the composite film slides relative to the compression roller, and meanwhile, a bag body pushed out by a push plate hinged on the supporting roller is collected.

2. The compounding process of a retort pouch according to claim 1, wherein: and in the step 2, the pressure applied to the nylon film and the PET-aluminum foil film is 0.28-0.32 mPa.

3. The compounding process of the autoclavable bag of claim 2, wherein: and (3) the gluing amount of the glue in the step 2 is 2-2.2 g/square meter.

4. The compounding process of a autoclavable bag of claim 3, wherein: and 3, winding the slitter edges by adopting a winding roller.

5. The compounding process of the autoclavable bag of claim 4, wherein: and 3, arranging a guide roller between the supporting roller and the winding roller.

6. The compounding process of a retort pouch according to claim 5, wherein: and the winding pressure of the waste edge in the step 3 is 0.25-0.3 mPa.

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