CN116119079B - Integrated production method and equipment for film heat-sealing package - Google Patents

Abstract

The invention relates to an integrated production method and equipment for film heat-seal packaging, wherein the integrated production method for the film heat-seal packaging comprises the following steps: s1, providing a bottom plate, wherein the bottom plate comprises a first wing plate, a bearing plate and a second wing plate which are sequentially connected; s2, placing the product on a bearing plate; s3, providing a film roll, wherein the film pulled out of the film roll is covered on the bottom plate; placing the product between the film and the carrier plate; processing one end of the film out of the film into a complete bag and sleeving a first wing plate; fixing the other end of the film to a second wing plate, and cutting off the film from the film roll; s4, folding the first wing plate and the second wing plate towards the back of the bottom plate so as to stretch the film and press the product on the bearing plate. The invention can complete the forming, folding and packaging of the film composite packaging lining and the fixing of the product through one production line, effectively reduces the occupied area of the production line and saves the whole flow, the production time and the storage cost.

Description

Integrated production method and equipment for film heat-sealing package

Technical Field

The invention relates to the technical field of film packaging, in particular to an integrated production method and equipment for film heat-seal packaging.

Background

The film composite packaging lining is formed by compounding film and paperboard, and has wide application prospect due to the advantages of good product compatibility, low storage and transportation cost, light weight, environmental protection and the like. In conventional composite packaging production, two production lines are typically required, one for producing the film composite packaging liner and the other for packaging the product through the liner. However, the production mode is complex in flow, and the thin film composite packaging lining which is produced by storage is required between the two production lines, so that the packaging cost and the storage cost are high.

Disclosure of Invention

In view of the foregoing, it is desirable to provide an integrated method and apparatus for producing heat sealed packages of film.

The invention provides an integrated production method of film heat-seal packaging, which comprises the following steps:

s1, providing a bottom plate, wherein the bottom plate comprises a first wing plate, a bearing plate and a second wing plate which are sequentially connected;

s2, placing the product on the bearing plate;

s3, providing a film roll, wherein the pulled film of the film roll is covered on the bottom plate; placing a product between the film and the carrier plate; processing one end of the film out of the film into a complete bag and sleeving the complete bag with the first wing plate; fixing the other end of the film to the second wing plate, and cutting the film from the film roll;

S4, folding the first wing plate and the second wing plate towards the back of the bottom plate so as to stretch the film and press the product on the bearing plate.

By the arrangement, the forming, folding and packaging of the film composite packaging lining can be completed through one production line, so that the occupied area of the production line is effectively reduced, and the whole flow and the production time are saved; in addition, the product can be placed on the bottom plate in advance in the process of connecting the film and the bottom plate, so that the storage cost can be greatly saved; the integrated production method of the film heat-seal package can increase the connection reliability between the film and the first wing plate in a mode that one end of the film roll out of the film is processed into a complete bag which is sleeved on the first wing plate; when effectively reducing the bottom plate and turning over the packing product, the tensile force that film tensioning produced causes the risk of being connected between film and the bottom plate and breaks away from, and the packing reliability of product is better.

In one embodiment of the present invention, the S3 includes:

s31, providing a film roll, wherein the pulled film of the film roll is covered on the bottom plate; placing a product between the film and the carrier plate; folding one end of the film out of the bottom plate to the side close to the bottom plate, and heat-sealing two sides of the folded part of the film to form the bagging, wherein the first wing plate is sleeved on the bagging; and fixing the other end of the film to the second wing plate, and cutting the film from the film winding roller.

So set up, the sack of cover bag can be towards the bottom plate, and the first pterygoid lamina of bottom plate of being convenient for gets into in the cover bag.

In one embodiment of the present invention, the S31 includes:

s311, providing a film roll, wherein the film pulled out of the film roll is covered on the bottom plate; placing a product between the film and the carrier plate; folding one end of the film out of the bottom plate to the side close to the bottom plate, and heat-sealing two sides of the folded part of the film to form the bagging; the first wing plate is turned over by a preset angle so that the bagging is sleeved with the first wing plate; and fixing the other end of the film to the second wing plate, and cutting the film from the film winding roller.

So set up, the cover bag can be formed through folding and heat-seal, and is simple and convenient swift, and after the angle was predetermine was turned over into to the first pterygoid lamina, the cover bag can be more convenient cup joints the tip of first pterygoid lamina, improves machining efficiency.

In one embodiment of the present invention, the S311 includes:

s3111, providing a film roll, wherein the film pulled out of the film roll is covered on the bottom plate; placing a product between the film and the carrier plate; folding one end of the film out of the bottom plate to the side close to the bottom plate, and heat-sealing two sides of the folded part of the film to form the bagging; moving a bender in integrated production equipment to a moving path of the bottom plate, and turning over the first wing plate by a preset angle by using the bender so that the first wing plate is sleeved by the bagging; moving the bender so that the bender allows the base plate to continue to move along the path of movement; and fixing the other end of the film to the second wing plate, and cutting the film from the film winding roller.

So set up, film play membrane one end on the film roll can be by the preprocessing formation cover bag, the buckle ware can buckle first pterygoid lamina to preset the angle in order to cup joint with the cover bag fast, avoids first pterygoid lamina and cover bag to cup joint the in-process and appears in the condition that first pterygoid lamina tip can't insert the cover bag or can't all insert the cover bag.

In one embodiment of the present invention, the step S3111 includes:

s31111, providing a film roll, wherein the film pulled out of the film roll is covered on the bottom plate; placing a product between the film and the carrier plate; folding one end of the film out of the bottom plate to the side close to the bottom plate, and heat-sealing two sides of the folded part of the film to form the bagging; sliding a bender in integrated production equipment onto a moving path of the bottom plate, and turning over the first wing plate by a preset angle by using the bender so that the first wing plate is sleeved by the bagging; sliding the bender so that the bender moves away from the path of travel of the base plate to allow the base plate to continue to move along the path of travel; and fixing the other end of the film to the second wing plate, and cutting the film from the film winding roller.

So set up, after first pterygoid lamina cup joints with the cover bag, the buckle ware can avoid the travel path of bottom plate through the slip, and the length and width height of the product of placing on the bottom plate is difficult for restricting because of the setting of buckle ware.

In one embodiment of the present invention, the S3 includes:

s32, providing a film roll, wherein the pulled film of the film roll is covered on the bottom plate; placing a product between the film and the carrier plate; processing one end of the film out of the film into a complete bag and sleeving the complete bag with the first wing plate; and fixing the other end of the film to the second wing plate, naturally straightening the film in the process of passing the product from the first wing plate to the second wing plate, and cutting the film from the film winding roller.

The setting is convenient for tectorial membrane device carries out the tectorial membrane to the bottom plate, and the length that the film tectorial membrane was established on the bottom plate is not greater than the extension route of film.

In one embodiment of the present invention, the S3 includes:

s33, gluing the first wing plate and the second wing plate to provide a film roll, wherein the pulled film of the film roll is covered on the bottom plate; placing a product between the film and the carrier plate; processing one end of the film out of the film into a complete bag and sleeving the complete bag with the first wing plate; and (3) hot-pressing and bonding the other end of the film to the second wing plate, and cutting the film from the film winding roller while hot-pressing.

So set up, can make the film through the mode of hot pressing and the rubber coating region quick connect on first pterygoid lamina and the second pterygoid lamina.

The invention also provides integrated production equipment for heat-sealing and packaging films, which comprises a film laminating device, a folding device and a first conveying device, wherein the film laminating device comprises a film roll, a bagging processing mechanism and a pressing and cutting mechanism, the film on the film roll is pulled out and connected to the bagging processing mechanism, the bagging processing mechanism is used for processing one end of the film out of a complete bag and sleeving the complete bag on a first wing plate on a bottom plate, and the pressing and cutting mechanism is used for pressing and pasting the other end of the film to a second wing plate on the bottom plate and cutting the film from the film roll;

the first conveying device is used for conveying the base plate after film coating to the folding device, and the folding device is used for folding the first wing plate and the second wing plate towards the back of the base plate so as to stretch the film and compress the product on the bearing plate of the base plate.

By means of the arrangement, the integrated production equipment for the film heat-sealing package can complete a series of production processes of forming the film end bagging, laminating the bottom plate, folding the bottom plate packaging products and the like through the mutual cooperation of the laminating device, the folding device and the first conveying device, and can solve the problems that after integrated production, the initial adhesive strength of the film is insufficient, and the film is separated from the bottom plate due to stretching of the film when the products are packaged.

In one embodiment of the invention, the bagging processing mechanism comprises a film sucking winding drum and two groups of heating plates, wherein the two groups of heating plates are respectively positioned at two sides of the film winding roller;

the film on the film roll is pulled out and connected to the film sucking winding drum, the film sucking winding drum is used for folding one end of the film, which is close to one side of the bottom plate, of the film, and the heating plate is used for heat-sealing two sides of the folded part of the film to form the bagging.

So set up, can form the cover bag through the film play membrane end preliminary working on the cover bag processing mechanism with the film roller, when production, the bottom plate of being convenient for conveys to this station, first pterygoid lamina can cup joint with the cover bag fast.

In one embodiment of the invention, the integrated production apparatus further comprises a bender slidably disposed on the first conveyor, the bender being switchable between a connected state and a yielding state;

in the guide connection state, the bender can move above the first conveying device, the first conveying device drives the bottom plate to move to the bender, and the bender is used for turning over the first wing plate by a preset angle so that the bagging sleeve is sleeved with the first wing plate;

In the yielding state, the bender moves to the side of the first conveying device so as to allow the first conveying device to convey the bottom plate to the next station.

The sleeve bag is arranged in such a way, and in the guide connection state, the first wing plate can be bent to a preset angle through the bending device to be sleeved with the sleeve bag, so that the situation that the end part of the first wing plate cannot be inserted into the sleeve bag or cannot be fully inserted into the sleeve bag in the sleeving process of the first wing plate and the sleeve bag is avoided; under the state of stepping down, the bottom plate can be ensured to move to the next station.

Drawings

FIG. 1 is a schematic view of the steps of the integrated production method of the film heat-seal package provided by the invention;

FIG. 2 is a schematic structural view of an integrated production device for heat-sealing packaging of films;

FIGS. 3 to 12 are schematic views showing a process of packaging a product by an integrated production method and an integrated production apparatus of film heat-seal packaging;

FIG. 3a is an enlarged schematic view of the structure shown in FIG. 3A;

FIG. 4a is an enlarged schematic view of the structure shown at B in FIG. 4;

FIG. 5a is an enlarged schematic view of FIG. 5C;

FIG. 6a is an enlarged schematic view of the structure shown at D in FIG. 6;

FIG. 8a is an enlarged schematic view of the structure of FIG. 8E;

FIG. 9a is an enlarged schematic view of the structure shown at F in FIG. 9;

FIG. 11a is an enlarged schematic view of the structure of FIG. 11G;

FIG. 12a is an enlarged schematic view of the structure of FIG. 12 at H;

FIG. 13 is a schematic illustration of the attachment of a membrane to a base plate;

FIG. 14 is a schematic view of the structure of the base plate and the product;

FIG. 15 is a schematic view of the process of bagging one end of a film.

1. An integrated production method; 100. an integrated production device; 10. a film covering device; 11. a film roll; 12. a bagging processing mechanism; 121. a film sucking winding drum; 122. a heating plate; 13. a pressing and cutting mechanism; 131. pressing the air pressing rod; 132. a cutting member; 20. a folding device; 21. an adsorption mechanism; 22. a first baffle; 23. a second baffle; 30. a first conveying device; 40. a bender; 41. a guide slope; 50. a gluing device; 51. a glue spreading roller; 52. a moving mechanism; 60. a second conveyor belt; 70. a clamping device; 71. a clamping arm; 72. a base; 80. a carrier; 200. a bottom plate; 210. a first wing plate; 220. a carrying plate; 230. a second wing plate; 240. a support plate; 201. a gluing area; 202. a bagging area; 300. a film; 310. bagging; 400. and (5) a product.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully, and it is apparent that the described embodiments are only some, but not all, embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present invention without making any inventive effort, are intended to fall within the scope of the present invention.

It will be understood that when an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may also be present. When an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "secured to" another element, it can be directly secured to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "or/and" as used herein includes any and all combinations of one or more of the associated listed items.

The film composite packaging lining is formed by compounding film and paperboard, and has wide application prospect due to the advantages of good product compatibility, low storage and transportation cost, light weight, environmental protection and the like. In conventional composite packaging production, two production lines are typically required, one for producing the film composite packaging liner and the other for packaging the product through the liner. However, the production mode is complex in flow, and the thin film composite packaging lining which is produced by storage is required between the two production lines, so that the packaging cost and the storage cost are high.

Referring to fig. 1, fig. 2, fig. 3-fig. 12, fig. 3a, fig. 4a, fig. 5a, fig. 6a, fig. 8a, fig. 9a, fig. 11a and fig. 12a, fig. 1 is a schematic diagram illustrating steps of an integrated production method 1 of a film heat-seal package provided by the present invention; fig. 2 is a schematic structural view of an integrated production apparatus 100 for heat-sealing a film package according to the present invention; fig. 3 to 12 are schematic views showing a process of packaging a product 400 by the integrated production method 1 and the integrated production apparatus 100 of film heat-seal packaging; FIG. 3a is an enlarged schematic view of the structure shown in FIG. 3A; FIG. 4a is an enlarged schematic view of the structure shown at B in FIG. 4; FIG. 5a is an enlarged schematic view of FIG. 5C; FIG. 6a is an enlarged schematic view of the structure shown at D in FIG. 6; FIG. 8a is an enlarged schematic view of the structure of FIG. 8E; FIG. 9a is an enlarged schematic view of the structure shown at F in FIG. 9; FIG. 11a is an enlarged schematic view of the structure of FIG. 11G; FIG. 12a is an enlarged schematic view of the structure of FIG. 12 at H; it is necessary to provide an integrated production method 1 of film heat-seal packages.

In view of this, the present application provides an integrated production method 1 of film heat-seal packaging, which is applied to forming and folding of film composite packaging lining and packaging of products. It can be appreciated that the integrated production method of the film heat-seal package provided by the invention can be suitable for machine automated production processing.

It should be noted that, the film composite packaging liner generally includes at least the base plate 200 and the film 300, but the packaging structure of the film composite packaging liner may be various, as long as the final folded packaging structure of the film composite packaging liner can effectively package the product 400. In other words, the shape of the bottom plate 200 can be cut according to the requirement, the length of the film 300 can be adapted to the bottom plate and the product according to the requirement, the film composite package liner can be folded by different ways to form various package structures by folding the bottom plate 200 and the film 300, and the common points of the package structures can be used for compressing and fixing the product 400 through the cooperation of the bottom plate 200 and the film 300.

The invention provides an integrated production method 1 of film heat-seal packaging, which comprises the following steps:

s1, providing a bottom plate 200, wherein the bottom plate 200 comprises a first wing plate 210, a bearing plate 220 and a second wing plate 230 which are sequentially connected;

s2, placing the product 400 on the bearing plate 220;

s3, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product 400 between the film 300 and the carrier plate 220; processing the film outlet end of the film 300 into a complete bag 310 and sleeving the complete bag with the first wing plate 210; fixing the other end of the film 300 to the second wing plate 230, and cutting the film 300 from the film roll 11;

S4, folding the first wing plate 210 and the second wing plate 230 towards the back of the bottom plate 200, so that the film 300 stretches and the product 400 is pressed on the bearing plate 220.

By the arrangement, the forming, folding and packaging of the film composite packaging lining and the fixing of the product 400 can be completed through one production line, so that the occupied area of the production line is effectively reduced, and the whole flow and the production time are saved; in addition, since the product 400 can be placed on the base plate 200 in advance in the process of connecting the film 300 with the base plate 200, the storage cost can be greatly saved; in the integrated production method 1 for the film heat-seal package, the connection reliability between the film and the first wing plate is greatly improved in a mode that the film outlet end of the film roll 11 is sleeved with the complete bag 310; when the bottom plate turns over the packaging product, the tensile force generated by the tensioning of the film causes the risk of connection and disconnection between the film and the bottom plate to be reduced, and the packaging reliability of the product is better.

In other words, in the traditional film composite packaging lining, two ends of the film are generally adhered to two ends of the bottom plate in a direct flat adhesion mode, when the bottom plate is folded to form a packaged product, the film can be tensioned and stretched in the folding process and the height of the product, the two ends of the film are easy to be degummed with the bottom plate under the action of tension, and when the film is manually packaged, a worker can relatively control folding force or pinch two ends of the film to adhere part in a mode of pinching two hands, so that the risk of film degumping is reduced; but on the production line, the machine is difficult to control the processing force flexibly like the manual work, so in the prior art, after the film composite package lining is generally molded, the film composite package lining needs to be placed in a factory to stand, and after the film and the bottom plate colloid are cured and connected relatively firmly, the film and the bottom plate colloid are taken out again, the product is placed in the lining, and the package is completed through folding. This process needs to pass through two production lines, and two production lines switch in-process and still need get into the warehouse and store, and overall process is loaded down with trivial details, and is consuming time for a long time, need occupy great factory storehouse and store, and manufacturing cost and storage cost are all higher.

In the invention, the end part forming complete bag of the film 300 is sleeved and fixed at the end part of the bottom plate 200, and the bottom plate 200 is folded to drive the complete bag 310 to be folded to the back surface of the bottom plate 200, so that when the film 300 stretches and compresses the product 400, the end parts of the first wing plate 210 and/or the second wing plate 230 can be matched with the complete bag 310 to prevent the film 300 and the bottom plate 200 from being separated from each other, the connection reliability between the film 300 and the bottom plate 200 is effectively enhanced, and the machine can integrally complete the forming and folding of the inner liner of the film composite package and the packaging of the product. And because the product is just placed on the bottom plate before the film is connected with the bottom plate, the forming of film composite package lining, folding package product and the like do not need to be carried out in two production lines and intervals, and the whole production and the process of packaging the product do not need to occupy larger storage space, so that continuous production of flow production can be realized, and storage cost and production cost are reduced.

Referring again to fig. 3-12, it is further emphasized that in this embodiment, the process of forming the base 200 and film 300 into a film composite package liner and securing the product 400 package between the base 200 and film 300 is performed interactively. Therefore, the film 300 is more convenient and easy to adhere to the base plate 200, and the problem that it is difficult for both ends of the film 300 to be adhered to both ends of the base plate 200 by a machine when the length of the film 300 is longer than that of the base plate 200 in the prior art is solved.

It will be appreciated that film 300 may be sleeved on base plate 200 with one end of sleeve 310, or may be sleeved on base plate 200 with both ends forming sleeve 310.

It will be appreciated that in other embodiments, a suitable film composite package liner may be formed corresponding to the product 400 to be packaged, and then the product 400 may be placed in the film composite package liner, and the product may be completely packaged and secured by folding.

Alternatively, base 200 includes, but is not limited to being implemented as paperboard. In this embodiment, the bottom board 200 is preferably a cardboard, which has low cost, is convenient to fold, has relatively high supporting force and buffering force after folding, and has excellent packing cost performance when the cardboard is used for packing the product 400. It is understood that the specific materials of the paperboard include, but are not limited to, corrugated paper, cardboard, and the like.

It will be appreciated that the film 300 is generally a transparent plastic sheet having certain flexibility, extensibility and stretchability, and the particular materials may be selected according to the needs, and are not limited in this application, as long as the packaging of the product 400 is not compromised.

Further, the product 400 includes, but is not limited to, electronic devices, parts, food products, toys, etc.; the shape of the product 400 is not limited.

In one embodiment of the present invention, step S3 includes:

S31, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product 400 between the film 300 and the carrier plate 220; folding one end of the film 300 toward one side close to the bottom plate 200, and heat-sealing both sides of the folded part of the film 300 to form a bagging 310, wherein the bagging 310 is sleeved with the first wing plate 210; the other end of the film 300 is fixed to the second wing 230, and the film 300 is cut from the film roll 11.

So arranged, the end of the film 300 can be formed into the pouch 310 by folding and heat sealing the two sides, and the mouth of the pouch 310 can face the bottom plate 200, so that the first wing plate 210 of the bottom plate 200 can enter the pouch 310.

It should be noted that, the end of the first wing 210 enters or is inserted into the pocket 310, and not the entire first wing 210 is located in the pocket 310. It can be understood that, when the product 400 is located between the carrier 220 and the film 300 and the first wing plate 210 is folded towards the back of the bottom plate 200, the bag 310 will be folded and pressed against the back of the bottom plate 200 along with the first wing plate 210, the film 300 compresses the product 400, the bag 310 is stressed, and the end of the first wing plate 210 can prevent the bag 310 from separating, so that the connection between the film 300 and the bottom plate 200 is more stable, and the product 400 is more firm and safe after being packaged.

It will be appreciated that at this point, the integrated production method 1 comprises the steps of:

s1, providing a bottom plate 200, wherein the bottom plate 200 comprises a first wing plate 210, a bearing plate 220 and a second wing plate 230 which are sequentially connected;

s2, placing the product 400 on the bearing plate 220;

s31, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product 400 between the film 300 and the carrier plate 220; folding one end of the film 300 toward one side close to the bottom plate 200, and heat-sealing both sides of the folded part of the film 300 to form a bagging 310, wherein the bagging 310 is sleeved with the first wing plate 210; fixing the other end of the film 300 to the second wing plate 230, and cutting the film 300 from the film roll 11;

s4, folding the first wing plate 210 and the second wing plate 230 towards the back of the bottom plate 200, so that the film 300 stretches and the product 400 is pressed on the bearing plate 220.

Referring to fig. 1, 3-12 and 15 again, in one embodiment of the present invention, step S31 includes:

s311, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product 400 between the film 300 and the carrier plate 220; folding one end of the film 300 to a side close to the bottom plate 200, and heat-sealing both sides of the folded part of the film 300 to form a pouch 310, and folding the first wing plate 210 by a preset angle so that the pouch 310 is sleeved with the first wing plate 210; the other end of the film 300 is fixed to the second wing 230, and the film 300 is cut from the film roll 11.

So set up, cover bag 310 can be through folding and heat-seal formation, and is simple and convenient swift, and after the first pterygoid lamina 210 turns over into the angle of predetermineeing, the cover bag 310 can more convenient cup joint the tip of first pterygoid lamina 210, improves machining efficiency.

It will be appreciated that in other embodiments, the film 300 with the pocket 310 may be formed separately and then placed in the manufacturing line to be sleeved over the end of the first wing 210.

It will be appreciated that at this point, the integrated production method 1 comprises the steps of:

s1, providing a bottom plate 200, wherein the bottom plate 200 comprises a first wing plate 210, a bearing plate 220 and a second wing plate 230 which are sequentially connected;

s2, placing the product 400 on the bearing plate 220;

s311, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product 400 between the film 300 and the carrier plate 220; folding one end of the film 300 to a side close to the bottom plate 200, and heat-sealing both sides of the folded part of the film 300 to form a pouch 310, and folding the first wing plate 210 by a preset angle so that the pouch 310 is sleeved with the first wing plate 210; fixing the other end of the film 300 to the second wing plate 230, and cutting the film 300 from the film roll 11;

s4, folding the first wing plate 210 and the second wing plate 230 towards the back of the bottom plate 200, so that the film 300 stretches and the product 400 is pressed on the bearing plate 220.

In one embodiment of the present invention, step S311 includes:

s3111, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product between the film 300 and the carrier plate 220; folding one end of the film 300 toward a side close to the bottom plate 200, and heat-sealing both sides of the folded portion of the film 300 to process and form a pouch 310; moving the bender 40 in the integrated production equipment to a moving path of the bottom plate 200, and folding the first wing plate 210 by a preset angle by using the bender 40 so as to sleeve the first wing plate 210 by the sleeve bag 310; moving bender 40 such that bender 40 allows base plate 200 to continue moving along a path of movement; the other end of the film 300 is fixed to the second wing 230, and the film 300 is cut from the film roll 11.

So arranged, one end of the film 300 on the film roll 11, which is out of the film, can be prefabricated to form a bagging 310, the bender 40 can bend the first wing plate 210 to a preset angle to be quickly sleeved with the bagging 310, so that the situation that the end part of the first wing plate 210 cannot be inserted into the bagging 310 or cannot be completely inserted into the bagging 310 in the sleeving process of the first wing plate 210 and the bagging 310 is avoided

It will be appreciated that at this point, the integrated production method 1 comprises the steps of:

S1, providing a bottom plate 200, wherein the bottom plate 200 comprises a first wing plate 210, a bearing plate 220 and a second wing plate 230 which are sequentially connected;

s2, placing the product 400 on the bearing plate 220;

s3111, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product between the film 300 and the carrier plate 220; folding one end of the film 300 toward a side close to the bottom plate 200, and heat-sealing both sides of the folded portion of the film 300 to process and form a pouch 310; moving the bender 40 in the integrated production equipment to a moving path of the bottom plate 200, and folding the first wing plate 210 by a preset angle by using the bender 40 so as to sleeve the first wing plate 210 by the sleeve bag 310; moving bender 40 such that bender 40 allows base plate 200 to continue moving along a path of movement; fixing the other end of the film 300 to the second wing plate 230, and cutting the film 300 from the film roll 11;

s4, folding the first wing plate 210 and the second wing plate 230 towards the back of the bottom plate 200, so that the film 300 stretches and the product 400 is pressed on the bearing plate 220.

In one embodiment of the present invention, step S3111 includes:

s31111, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product between the film 300 and the carrier plate 220; folding one end of the film 300 toward a side close to the bottom plate 200, and heat-sealing both sides of the folded portion of the film 300 to process and form a pouch 310; sliding the bender 40 in the integrated production equipment onto the moving path of the bottom plate 200, and folding the first wing plate 210 by a preset angle by using the bender 40 so as to sleeve the first wing plate 210 by the sleeve bag 310; sliding bender 40 such that bender 40 is out of the path of movement of base plate 200 to allow base plate 200 to continue to move along the path of movement; the other end of the film 300 is fixed to the second wing 230, and the film 300 is cut from the film roll 11.

So arranged, after the first wing plate 210 is sleeved with the sleeve 310, the bender 40 can avoid the moving path of the bottom plate 200 by sliding, and the length, width and height of the product placed on the bottom plate 200 are not easy to be limited due to the arrangement of the bender 40.

It will be appreciated that at this point, the integrated production method 1 comprises the steps of:

s1, providing a bottom plate 200, wherein the bottom plate 200 comprises a first wing plate 210, a bearing plate 220 and a second wing plate 230 which are sequentially connected;

s2, placing the product 400 on the bearing plate 220;

s31111, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product between the film 300 and the carrier plate 220; folding one end of the film 300 toward a side close to the bottom plate 200, and heat-sealing both sides of the folded portion of the film 300 to process and form a pouch 310; sliding the bender 40 in the integrated production equipment onto the moving path of the bottom plate 200, and folding the first wing plate 210 by a preset angle by using the bender 40 so as to sleeve the first wing plate 210 by the sleeve bag 310; sliding bender 40 such that bender 40 is out of the path of movement of base plate 200 to allow base plate 200 to continue to move along the path of movement; fixing the other end of the film 300 to the second wing plate 230, and cutting the film 300 from the film roll 11;

S4, folding the first wing plate 210 and the second wing plate 230 towards the back of the bottom plate 200, so that the film 300 stretches and the product 400 is pressed on the bearing plate 220.

In one embodiment of the present invention, step S3 includes:

s32, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product between the film 300 and the carrier plate 220; processing the film outlet end of the film 300 into a complete bag 310 and sleeving the complete bag with the first wing plate 210; the other end of the film 300 is fixed to the second wing 230, and the film 300 is naturally straightened by the first wing 210 passing through the product to the second wing 230, cutting the film 300 from the film roll 11.

Thus, the film laminating device 10 is convenient for laminating the bottom plate 200, and the length of the film 300, which is arranged on the bottom plate 200, is not greater than the extension path of the film 300.

It will be appreciated that at this point, the integrated production method 1 comprises the steps of:

s1, providing a bottom plate 200, wherein the bottom plate 200 comprises a first wing plate 210, a bearing plate 220 and a second wing plate 230 which are sequentially connected;

s2, placing the product 400 on the bearing plate 220;

s32, providing a film roll 11, wherein the film 300 pulled out of the film roll 11 is covered on the bottom plate 200; placing the product between the film 300 and the carrier plate 220; processing the film outlet end of the film 300 into a complete bag 310 and sleeving the complete bag with the first wing plate 210; fixing the other end of the film 300 to the second wing plate 230, and naturally straightening the film 300 in the process of passing the product from the first wing plate 210 to the second wing plate 230, so as to cut off the film 300 from the film roll 11;

S4, folding the first wing plate 210 and the second wing plate 230 towards the back of the bottom plate 200, so that the film 300 stretches and the product 400 is pressed on the bearing plate 220.

In one embodiment of the present invention, step S3 includes:

s33, gluing the first wing plate 210 and the second wing plate 230 to provide a film roll 11, and coating the bottom plate 200 with the film 300 pulled out of the film roll 11; placing the product between the film 300 and the carrier plate 220; processing the film outlet end of the film 300 into a complete bag 310 and sleeving the complete bag with the first wing plate 210; the other end of the film 300 is hot-pressed and adhered to the second wing plate 230, and the film 300 is cut from the film roll 11 while hot-pressing.

So arranged, the film 300 can be quickly connected with the gluing areas on the first wing plate 210 and the second wing plate 230 by means of hot pressing.

It will be appreciated that at this point, the integrated production method 1 comprises the steps of:

s1, providing a bottom plate 200, wherein the bottom plate 200 comprises a first wing plate 210, a bearing plate 220 and a second wing plate 230 which are sequentially connected;

s2, placing the product 400 on the bearing plate 220;

s33, gluing the first wing plate 210 and the second wing plate 230 to provide a film roll 11, and coating the bottom plate 200 with the film 300 pulled out of the film roll 11; placing the product between the film 300 and the carrier plate 220; processing the film outlet end of the film 300 into a complete bag 310 and sleeving the complete bag with the first wing plate 210; the other end of the film 300 is hot-pressed and adhered to the second wing plate 230, and the film 300 is cut off from the film roll 11 while hot-pressing;

S4, folding the first wing plate 210 and the second wing plate 230 towards the back of the bottom plate 200, so that the film 300 stretches and the product 400 is pressed on the bearing plate 220.

It should be noted that, the steps S33, S32 and S31 may be performed after being combined.

It will be appreciated that in other embodiments, the various steps described above may be selectively fused, interleaved, or interchanged as desired. The forming, folding and packaging of the film composite packaging lining are not influenced.

Referring to fig. 3-12, 3a, 4a, 5a, 6a, 8a, 9a, 11a and 12a again, and also referring to fig. 13, 14 and 15, fig. 13 is a schematic diagram illustrating the connection between the film 300 and the base plate 200; FIG. 14 is a schematic diagram of the structure of the base 200 and the product 400; fig. 15 is a schematic view of a process for forming a pouch 310 at one end of a film 300. It will be appreciated that the film 300 may be directly adhered to the second wing 230, or the shaped bag set 310 may be sleeved on the end of the second wing 230. In other words, in this embodiment, one end of the film 300 is adhered in parallel to one end of the base plate 200, and the other end of the film 300 is formed into a sleeve 310 sleeved on the other end of the base plate 200, wherein the portion of the base plate 200 for adhesion is an adhesive area 201, and the portion for sleeved on the sleeve 310 is called a sleeved area. However, in other embodiments, both ends of the film 300 may be formed into a sleeve 310 that is sleeved with both ends of the base 200, so as to further ensure the connection strength between the film 300 and the base 200, and avoid the situation that the base 200 and the film 300 are separated from each other when the product 400 is packaged.

Referring to fig. 2, the present invention further provides an integrated production apparatus 100 for film heat-seal packaging, where the integrated production apparatus 100 for film heat-seal packaging is capable of completing the formation of the liner of the film composite package by the integrated production method 1 for film heat-seal packaging and the package fixation of the product 400 during the formation of the liner of the film composite package.

The integrated production equipment 100 for film heat-sealing packaging comprises a film laminating device 10, a folding device 20 and a first conveying device 30, wherein the film laminating device 10 comprises a film roll 11, a bagging processing mechanism 12 and a pressing and cutting mechanism 13, a film 300 on the film roll 11 is pulled out and connected to the bagging processing mechanism 12, the bagging processing mechanism 12 is used for processing one end of the film 300, which is out of a film, into a bag set 310 and sleeving the bag set 310 on a first wing plate 210 on a bottom plate 200, and the pressing and cutting mechanism 13 is used for pressing and adhering the other end of the film 300 to a second wing plate 230 on the bottom plate 200 and cutting the film 300 from the film roll 11;

the first conveying device 30 is used for conveying the coated base plate 200 to the folding device 20, and the folding device 20 is used for folding the first wing plate 210 and the second wing plate 230 towards the back surface of the base plate 200, so that the film 300 is stretched and the product 400 is pressed on the bearing plate 220.

By means of the arrangement, the integrated production equipment 100 for heat-sealing and packaging the film can complete a series of production processes of forming the end part bagging 310 of the film 300, coating the film on the bottom plate 200, packaging the product 400 by folding the bottom plate 200 and the like through the mutual matching of the film coating device 10, the folding device 20 and the first conveying device 30, and can solve the problems that the initial adhesive strength of the film 300 is insufficient after integrated production, and the film 300 is separated from the bottom plate 200 due to stretching of the film 300 when the product 400 is packaged.

Referring to fig. 5, 5a, 6a and 15 again, in the present embodiment, the bagging processing mechanism 12 includes a film sucking drum 121 and two sets of heating plates 122, and the two sets of heating plates 122 are respectively located at two sides of the film winding roller 11; the film 300 on the film roll 11 is drawn out and attached to the film sucking roll 121, the film sucking roll 121 is used to fold one end of the film 300, which is to be film-fed, toward one side near the bottom plate 200, and the heating plate 122 is used to heat-seal both sides of the folded portion of the film 300 to process and form the pouch 310.

So set up, can form the cover bag 310 through cover bag processing mechanism 12 with the film 300 play membrane end preliminary working on the film roll 11, when the production, the bottom plate 200 of being convenient for conveys to this station, first pterygoid lamina 210 can cup joint with the cover bag 310 fast.

Referring again to fig. 15, two heating plates 122 are heat sealed at sides Y, where X remains open for the sleeve 310 to nest with the end of the first wing 210.

Referring to fig. 2, 8 and 8a again, in the present embodiment, the integrated production apparatus 100 further includes a bender 40, the bender 40 is slidably disposed on the first conveying device 30, and the bender 40 can be switched between a guiding state and a yielding state;

in the guiding state, the bender 40 can move above the first conveying device 30, the first conveying device 30 drives the bottom plate 200 to move to the bender 40, and the bender 40 is used for turning over the first wing plate 210 by a preset angle so that the bagging 310 is sleeved with the first wing plate 210; in the yield state, the bender 40 moves to the side of the first conveyor 30 to allow the first conveyor 30 to convey the base plate 200 to the next station.

In such a setting, in the guiding state, the first wing plate 210 can be bent to a preset angle by the bending device 40 to be sleeved with the sleeve bag 310, so that the situation that the end part of the first wing plate 210 cannot be inserted into the sleeve bag 310 or cannot be completely inserted into the sleeve bag 310 in the sleeving process of the first wing plate 210 and the sleeve bag 310 is avoided; in the abdication state, the base plate 200 can be ensured to move to the next station.

Referring again to fig. 2 and 8a, in particular, the bender 40 has a guiding inclined surface 41, and a certain inclination angle is formed between the guiding inclined surface 41 and the first conveying device 30; in the guiding state, the bender 40 slides onto the first conveyor 30, and when the bottom plate 200 moves to the bender 40, the end of the first wing plate 210 can move upwards along the guiding inclined plane 41 of the bender 40 until part of the end is suspended, so that the sleeve 310 is convenient to sleeve. After the sleeve 310 is sleeved with the end of the first wing plate 210, the bender 40 is switched from the guiding state to the yielding state, that is, the bender 40 slides to the outside of the first conveying device 30 to yield until the bottom plate 200 is not affected to move to the next station. Specifically, a screw guide (not numbered) is provided at a side of the first transfer device 30, through which the bender 40 slides.

It should be understood that, in other embodiments, the bender 40 may be disposed on the conveying path of the first conveying device 30 by means of rotation, lifting, etc., so long as the first wing plate 210 can be folded by a preset angle in the guiding state, so as to facilitate the sleeving of the bagging 310; and in the abdication state, the first conveying device 30 is allowed to convey the bottom plate 200 to the next station.

For example, in one embodiment, the bender 40 is rotatably disposed on the first conveyor 30, and the bender 40 is capable of switching between a conductive state and a yielding state; in the guiding state, the bender 40 can rotate to have a certain inclination angle with the first conveying device 30, the first conveying device 30 drives the bottom plate 200 to move to the bender 40, and the bender 40 can fold the first wing plate 210 by a preset angle so that the bagging 310 is sleeved with the first wing plate 210; in the yielding state, the bender 40 rotates to be not protruded from the first conveyor 30, so as to allow the first conveyor 30 to convey the base plate 200 to the next station.

Referring to fig. 13 and 14, for ease of understanding, in this embodiment, the rubberized portion of the second wing plate 230 is referred to as a rubberized area 201, and the portion of the first wing plate 210 sleeved by the sleeve 310 is a sleeve area 202.

Referring to fig. 2, 3a, 4 and 4a again, further, in the present embodiment, the integrated production apparatus 100 further includes a gluing device 50, the gluing device 50 is used for gluing the second wing 230 of the base plate 200, and the first conveying device 30 is used for conveying the glued base plate 200 to the film covering device 10. So arranged, the second wing 230 can be adhered to the film 300 by the adhesive means 50. It will be appreciated that in other embodiments, the second wing 230 can be attached to the membrane 300 by any desired method, including but not limited to by adhesive bonding. It will be appreciated that in other embodiments, the end of the first wing 210 may be glued at the same time, so that the sleeve 310 formed by the film 300 can be sleeved on the first wing 210 and adhered to the first wing 210. To further strengthen the connection strength between the film 300 and the base 200 and reduce the risk of the products 400 being separated from each other when packaged.

Referring to fig. 2, 3a, 4 and 4a again, in the present embodiment, the integrated production apparatus 100 further includes a second conveyor belt 60 and a clamping device 70, the second conveyor belt 60 is used for conveying the product 400 to be packaged, and the clamping device 70 is used for clamping the product 400 to be packaged from the second conveyor belt 60 to the bottom plate 200 at the gluing device 50.

So set up, product 400 can be placed on bottom plate 200 through second conveyer belt 60 and clamping device 70 is automatic and is carried out the transmission packing, further improves degree of automation, improves packing efficiency.

Referring to fig. 2, 9 and 9a again, in the present embodiment, the pressing and cutting mechanism 13 includes a pressing rod 131 and a cutting member 132, the pressing rod 131 is used for pressing the film 300 onto the second wing plate 230 and pressing and heat-sealing, and the cutting member 132 is used for cutting the film 300 from the film roll 11.

After the first wing plate 210 and the second wing plate 230 are coated, the film 300 on the film roll 11 and the film 300 on the bottom plate 200 can be separated by the cooperation of the pressing rod 131 and the cutting member 132, so that the bottom plate 200 after the coating is completed can enter the next station under the action of the first conveying device 30.

Referring to fig. 2, 10, 11a, 12 and 12a again, further, in the present embodiment, the folding device 20 includes an adsorption mechanism 21, two sets of first baffles 22 and two sets of second baffles 23, the adsorption mechanism 21 can adsorb and lift the coated base plate 200 away from the first conveying device 30, the two sets of first baffles 22 are respectively used for folding the first wing 210 and the second wing 230 on the base plate 200 towards the back of the base plate 200, the adsorption mechanism 21 can put the base plate 200 back to the first conveying device 30, and the second baffles 23 are used for folding the support plate 240 on the base plate 200 to be supported on two sides of the base plate 200. By the arrangement, the base plate 200 after film coating is completed can be folded, so that the film 300 on the base plate 200 is stretched to compress the product 400, and packaging of the product 400 is completed. The supporting plates 240 are supported on two sides of the product 400 to play a role in buffering and protecting, so that the protection capability of the bottom plate 200 to the product 400 after folding and packaging is effectively enhanced.

It should be noted that, the adsorption mechanism 21 includes two adsorption plates capable of lifting, and the two adsorption plates are respectively used for adsorbing two sides of the bottom plate provided with the support plate 260, so as to avoid affecting the two first baffles 22 to fold the first wing plate 210 and the second wing plate 230.

Referring again to fig. 2, the integrated production apparatus 100 includes a stage 80, and the above devices are all mounted on the stage 80.

In this embodiment, the present invention further includes a plurality of mounting frames (not numbered), and the film covering device 10, the folding device 20, and the like are mounted on the carrier 80 by corresponding mounting frames and are located on the conveying path of the first conveying device 30. It will be appreciated that the specific structure of the mounting frame for mounting the different components and devices may be the same or different, as long as it is ensured that the devices can stably perform their respective functions after being mounted.

Referring again to fig. 3-12, 3a, 4a, 5a, 6a, 8a, 9a, 11a and 12a, based on the integrated film heat-seal package production method 1 and the integrated production apparatus 100, in one embodiment of the present invention, the process of forming and folding the inner liner of the film composite package into the corresponding package structure to package the product is as follows:

The base plate cut into the desired structure and size is transferred to a spreading station, and the spreading device 50 includes a spreading roller 51 and a moving mechanism 52, wherein the spreading roller 51 can horizontally move by the rotation and moving mechanism 52 (see fig. 3a and 4 a), and a certain amount of adhesive is applied to a spreading area 201 of the base plate. In this embodiment, when the cut base plate 200 passes through the gluing device 50, the gluing device 50 glues the end of the second wing 230.

Further, after the gluing is completed, the clamping arms 71 of the clamping device 70 clamp the products 400 on the second conveyor belt 60, and rotate the base 72 to a corresponding angle, the products 400 are placed on the carrier plate 220. The bender 40 is switched to a conductive state, and the film laminating apparatus 10 uses the film sucking roller 121 to fold one end of the film, inwards around the roller, and applies a certain pressure to the film 300 by clinging to the heating plate 122, and heat-seals both ends of the film 300, and forms a bag 310 at the film outlet end of the film 300.

Further, the base plate 200 with the product 400 placed thereon is transported to the bender 40 by the first conveyor 30, and the end of the first wing plate 210 is bent by the bender 40 by a predetermined angle. The film covering device 10 is used for sleeving the formed bagging 310 at the end part of the first wing plate 210; the bender 40 is switched to a state of yielding, the base plate 200 moves forward, after reaching a preset position, the air bar 131 is pressed to press the film 300 on the film roll 11 to the second wing plate 230, so that the film 300 is adhered to the colloid at the end of the second wing plate 230, and meanwhile, the cutting piece 132 cuts off the film 300, and the whole process of covering the film by the base plate 200 is completed.

It will be appreciated that the horizontal direction of movement of the applicator roll 51 is perpendicular to the direction of movement of the first conveyor 30. It is further understood that the two sides of the glue roller 51 can glue the first wing plate 210 and the second wing plate 230 simultaneously according to the requirement.

Further, after the film coating is completed, the first conveying device 30 conveys the film composite package liner and the product located in the liner to the folding station where the folding device 20 is located, the adsorption mechanism 21 of the folding device 20 can adsorb and lift the coated bottom plate 200 away from the first conveying device 30, and the two sets of first baffles 22 respectively fold the first wing plate 210 and the second wing plate 230 towards the back of the bottom plate 200, so that the film 300 stretches and sticks to the product 400. Further, the adsorption mechanism 21 can put the bottom plate 200 back to the first conveying device 30, and the two sets of second baffles 23 fold the support plates 240 on the bottom plate 200 to be supported on two sides of the bottom plate 200, so as to complete the folding of the liner packaging structure of the film composite package and the packaging of the product 400.

Further, the film composite packing liner after the product 400 is packed may be also put into the outer packing box for packing, so as to facilitate storage and transportation.

The integrated production method 1 and the integrated production equipment 100 for the film heat-seal package can finish the forming, folding and packaging of the film composite package lining and the packaging of the fixed product 400 through one production line, thereby effectively reducing the occupied area of the production line and saving the whole flow and the production time; in addition, since the product 400 can be placed on the base plate 200 in advance in the process of connecting the film 300 with the base plate 200, the storage cost can be greatly saved; in the integrated production method 1 of the film heat-seal package, the connection reliability between the film 300 and the first wing plate 210 is greatly improved by sleeving the processing complete bag 310 at one end of the film, which is out of the film, of the film roll 11 on the first wing plate 210; when the bottom plate 200 is folded to pack the product 400, the risk of connection and disconnection between the film 300 and the bottom plate 200 due to the tensile force generated by tensioning the film 300 is reduced, the packing reliability of the product 400 is better, and the efficient green production of full-flow automation of packing is realized.

The technical features of the above-described embodiments may be combined in any manner, and for brevity, all of the possible combinations of the technical features of the above-described embodiments are not described, however, all of the combinations of the technical features should be considered as being within the scope of the present disclosure as long as there is no contradiction between the combinations of the technical features.

It will be appreciated by persons skilled in the art that the above embodiments have been provided for the purpose of illustrating the invention and are not to be construed as limiting the invention, and that suitable modifications and variations of the above embodiments are within the scope of the invention as claimed.

Claims (10)

1. The integrated production equipment for the film heat-sealing packaging is characterized by comprising a film coating device (10), a folding device (20) and a first conveying device (30), wherein the film coating device (10) comprises a film roll (11), a bagging processing mechanism (12) and a pressing and cutting mechanism (13), a film (300) on the film roll (11) is pulled out and connected to the bagging processing mechanism (12), the bagging processing mechanism (12) is used for processing one end of the film (300) out of a bag set (310) and sleeving the bag set (310) on a first wing plate (210) on a bottom plate (200), and the pressing and cutting mechanism (13) is used for pressing and adhering the other end of the film (300) to a second wing plate (230) on the bottom plate (200) and cutting the film (300) from the film roll (11);

The first conveying device (30) is used for conveying the base plate (200) with the products (400) to the laminating device (10), conveying the laminated base plate (200) to the folding device (20), and the folding device (20) is used for folding the first wing plate (210) and the second wing plate (230) towards the back of the base plate (200) so as to stretch the film (300) and compress the products (400) on the bearing plate (220) of the base plate (200).

2. The integrated production device for heat-sealing packaging of thin films according to claim 1, wherein the bagging processing mechanism (12) comprises a film sucking drum (121) and two groups of heating plates (122), and the two groups of heating plates (122) are respectively positioned at two sides of the thin film winding roller (11);

the film (300) on the film roll (11) is pulled out and connected to the film sucking drum (121), the film sucking drum (121) is used for folding one end of the film (300) close to one side of the bottom plate (200), and the heating plate (122) is used for heat-sealing two sides of the folded part of the film (300) to form the bagging (310).

3. The integrated production device of film heat-seal packages according to claim 2, characterized in that said integrated production device (100) further comprises a bender (40), said bender (40) being slidably arranged on said first conveyor means (30), said bender (40) being switchable between a conductive state and a yielding state;

in the guiding state, the bender (40) can move above the first conveying device (30), the first conveying device (30) drives the bottom plate (200) to move to the bender (40), and the bender (40) is used for turning over the first wing plate (210) by a preset angle so that the bagging (310) is sleeved with the first wing plate (210);

in the yielding state, the bender (40) moves to the side of the first conveying device (30) so as to allow the first conveying device (30) to convey the bottom plate (200) to the next station.

4. An integrated production method of a film heat-seal package, characterized by comprising the following steps based on the integrated production equipment of any one of claims 1 to 3:

s1, providing a bottom plate (200), wherein the bottom plate (200) comprises a first wing plate (210), a bearing plate (220) and a second wing plate (230) which are sequentially connected;

S2, placing a product (400) on the bearing plate (220);

s3, providing a film roll (11), wherein the film (300) pulled out of the film roll (11) is covered on the bottom plate (200); -placing a product (400) between the film (300) and the carrier plate (220); processing a complete bag (310) at one end of the film (300) out of the film and sleeving the first wing plate (210); -fixing the other end of the film (300) to the second wing plate (230), and cutting the film (300) from the film roll (11);

s4, folding the first wing plate (210) and the second wing plate (230) towards the back of the bottom plate (200) so as to stretch the film (300) and press the product (400) on the bearing plate (220).

5. The integrated production method of a film heat-seal package according to claim 4, wherein S3 comprises:

s31, providing a film roll (11), wherein the film (300) pulled out of the film roll (11) is covered on the bottom plate (200); -placing a product (400) between the film (300) and the carrier plate (220); folding one end of the film (300) close to one side of the bottom plate (200), and heat-sealing two sides of the folded part of the film (300) to form the bagging (310), wherein the bagging (310) is sleeved with the first wing plate (210); the other end of the film (300) is fixed to the second wing plate (230), and the film (300) is cut off from the film roll (11).

6. The integrated production method of a film heat-seal package according to claim 5, wherein S31 comprises:

s311, providing a film roll (11), wherein the film (300) pulled out of the film roll (11) is covered on the bottom plate (200); -placing a product (400) between the film (300) and the carrier plate (220); folding one end of the film (300) close to one side of the bottom plate (200), and heat-sealing two sides of the folded part of the film (300) to form the bagging (310); turning the first wing plate (210) by a preset angle so that the bagging (310) is sleeved with the first wing plate (210); the other end of the film (300) is fixed to the second wing plate (230), and the film (300) is cut off from the film roll (11).

7. The integrated production method of a film heat-seal package according to claim 5, wherein S311 comprises:

s3111, providing a film roll (11), wherein the film (300) pulled out by the film roll (11) is covered on the bottom plate (200); -placing a product (400) between the film (300) and the carrier plate (220); folding one end of the film (300) close to one side of the bottom plate (200), and heat-sealing two sides of the folded part of the film (300) to form the bagging (310); moving a bender (40) in integrated production equipment onto a moving path of the bottom plate (200), and folding the first wing plate (210) by a preset angle by using the bender (40) so that the first wing plate (210) is sleeved by the bagging (310); -moving the bender (40) such that the bender (40) allows the base plate (200) to continue to move along the path of movement; the other end of the film (300) is fixed to the second wing plate (230), and the film (300) is cut off from the film roll (11).

8. The integrated production method of a film heat-seal package according to claim 7, wherein S3111 includes:

s31111 providing a film roll (11), wherein the film (300) pulled out by the film roll (11) is covered on the bottom plate (200); -placing a product (400) between the film (300) and the carrier plate (220); folding one end of the film (300) close to one side of the bottom plate (200), and heat-sealing two sides of the folded part of the film (300) to form the bagging (310); sliding a bender (40) in integrated production equipment onto a moving path of the bottom plate (200), and folding the first wing plate (210) by a preset angle by using the bender (40) so that the bagging (310) is sleeved with the first wing plate (210); sliding the bender (40) such that the bender (40) is clear of the path of travel of the base plate (200) to allow the base plate (200) to continue to move along the path of travel; the other end of the film (300) is fixed to the second wing plate (230), and the film (300) is cut off from the film roll (11).

9. The integrated production method of a film heat-seal package according to claim 4, wherein S3 comprises:

s32, providing a film roll (11), wherein the film (300) pulled out of the film roll (11) is covered on the bottom plate (200); -placing a product (400) between the film (300) and the carrier plate (220); processing a complete bag (310) at one end of the film (300) out of the film and sleeving the first wing plate (210); -fixing the other end of the film (300) to the second wing (230), and-naturally straightening the film (300) from the first wing (210) through the product (400) to the second wing (230), and-cutting the film (300) from the film roll (11).

10. The integrated production method of a film heat-seal package according to claim 4, wherein S3 comprises:

s33, gluing the first wing plate (210) and the second wing plate (230) to provide a film roll (11), wherein the film (300) pulled out of the film roll (11) is covered on the bottom plate (200); -placing a product (400) between the film (300) and the carrier plate (220); processing a complete bag (310) at one end of the film (300) out of the film and sleeving the first wing plate (210); and (3) hot-pressing and adhering the other end of the film (300) to the second wing plate (230), and cutting the film (300) from the film winding roller (11) at the same time of hot-pressing.

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