WO2017206836A1

WO2017206836A1 - Inflatable air cushioning member, air inflation device thereof, packaging container having same, and use thereof

Info

Publication number: WO2017206836A1
Application number: PCT/CN2017/086324
Authority: WO
Inventors: 康勇刚; 杨威; 姚根; 张嘉盈
Original assignee: 天津定创科技发展有限公司
Priority date: 2016-05-30
Filing date: 2017-05-27
Publication date: 2017-12-07

Abstract

Provided are a packaging container having an air cushioning function and air inflation device and method thereof. The packaging container comprises at least one packaging member (50) and at least one inflatable air cushioning member (60). The packaging member (50) can form an accommodation space. The inflatable air cushioning member (60) can be inflated to form a receiving space (601). The inflatable air cushioning member (60) is connected to an inner side or an outer side of the packaging member (50), or is positioned between two packaging members. After the inflatable air cushioning member has been inflated, the packaging member connected thereto can expand automatically, thereby enhancing convenience of use.

Description

Inflatable cushion body and its inflatable device and packaging container and application thereof

Technical field

The present invention relates to the field of packaging devices, and more particularly to an inflation cushioning body and an inflation device thereof, and an inflation method and a packaging container having air cushioning properties and applications thereof.

Background technique

In the modern logistics industry, the most widely used is the packaging box (packing box). However, this traditional packaging method does not provide anti-collision, anti-collision and anti-fall functions. That is to say, during the transportation or storage process, the box or the box will be thrown and thrown, which may easily cause deformation, which may result in damage or deformation of the packaged article. Therefore, for some items with high packaging requirements, such as electronic digital products, plastic ceramics, biochemical products, food and medicine, etc., it is necessary to provide a buffering effect on the packaged articles to prevent the packaged articles from being damaged during transportation and storage.

Existing solutions, such as conventional paper packaging, may be filled with a cushioning foam material inside the paper package to provide cushioning. However, when such a package and filled cushioning foam are transported to the packaging site, the cost of shipping and storage is very expensive. Moreover, the cushioning foam pollutes the environment and is not environmentally friendly.

Alternatively, the air cushioning material may be filled in the paper package, for example, after the packaged article is placed in the package, the air cushion bag is inserted into the package to provide a cushioning effect to the packaged article. However, such an air cushioning bag is transported separately from the package to the packaging site, and is pre-filled with air, and then placed in the package, which is inconvenient to use.

Further, in such a method of filling an air cushioning material in a paper package, since the air cushion bag is first filled with air and then placed in the paper package, the air cushion bag is The paper box is a split structure. After the article is placed in the air cushion bag, although the air cushion bag can provide a cushioning force for the article placed therein, since the air cushion bag and the paper package are separated structures, Therefore, the article may move arbitrarily in the paper package with the air cushion bag when subjected to an external force impact or the paper package is being moved. While the air cushioning bag is capable of providing a certain cushioning force for the items placed therein, such arbitrary movement may result in breakage or variation of the article, resulting in an increase in shipping costs. On the other hand, when the article is arbitrarily moved in the paper package with the air cushion bag, it may be in any position or form, when the user opens the paper package and opens it, What you see may be twisted or even messy items, which will also affect the user's experience of the beauty of the items being transported to a certain extent.

Indispensable in the process of inflation is the inflatable device. Existing air packaging materials, such as air-packing cushions or air-packing bags, are inflated in a manner that is inconvenient for continuous automated inflation using an inflatable device. Figure 45 is a method of inflating an air bag, the air bag forming a plurality of air chambers for storing air through the multilayer film, wherein at least two films are used to form a one-way valve, that is, The one-way valve formed by the two-layer film inflates each of the air chambers, and after the inflation is completed, the film forming the one-way valve is automatically fitted together due to the pressure in the air chamber to prevent air Reverse osmosis. The air bag generally forms an air inlet between the two layers of the film at the end, except for the air inlet, the other parts are sealed structures, and the air inlet is also suitable for installing the air nozzle of an inflatable device. And then charging air from the air inlet into each of the air storage chambers of the air package, and when the pressure in the air storage chamber is sufficient, the air nozzle is The air inlet is taken out and the air inlet does not need to be sealed, so that air is sealed in each of the air storage chambers, so that the packaged articles can be placed in the air packaging bag for storage and transportation.

It can be seen that in the existing inflation operation, the film forming the air inlet is preferably in close contact with the air nozzle, that is, the air nozzle needs to be inserted between the films, and then the film is tightly attached to the air nozzle to form a seal. In this way, the air needs to enter the air inlet between the two layers of the air packaging material, and then the air can enter the corresponding air storage chamber through the air inlet. However, if the air packaging material has a large size, it needs to have a larger In the case of deep inflating operation, this way of intake air through a single air inlet may also make the air storage chamber not be effectively and efficiently filled in time, that is, the required inflation air pressure may not be reached in the air storage chamber. For example, the air-packing bag of Fig. 45 described above includes a plurality of air plenums arranged side by side, but when inflated by the above-described conventional manner, each of the air-filled packaging materials can only be inflated one by one. Moreover, the air-filled packaging material in Fig. 45 has the air inlets at the ends, but both require an inflating device having a long tubular air nozzle to penetrate into the air inlet of the air-filled packaging material, the tubular air nozzle and the inflatable portion of the air-filled packaging material. There is inevitably a gap between them, and it is easy to cause gas source loss. Especially when using a high-pressure gas source for aeration, the lost gas source also indirectly increases the cost.

Some existing inflatable devices are inflated from both ends of the inflatable bag, and the air inlet of the inflatable bag is disposed at the end, and the inflatable device lacks positioning performance, so that the operator needs to manually position the inflatable bag for inflation and a single non-continuous inflation. Not conducive to improving work efficiency. In the inflation process of the conventional air bag, it is also excessively dependent on labor. For example, when using a small air pump, the operator needs to hold the pump in one hand, and the other hand holds the position of the air bag adjacent to the air port. Then perform an inflating operation or require two people to work together. For example, when switching to a high-pressure gas source, the operator needs to hold the inflatable bag with both hands, and then the gas nozzle of the inflatable device is placed in the inflation port of the inflatable bag to perform the inflation operation, and during the inflation operation, the operator needs to grip. The inflatable package prevents the inflatable bag from swaying due to inflation. Moreover, in conventional inflation operations, a single of the inflatable bags is essentially inflated, i.e., multiple inflatable bags cannot be continuously inflated, thereby eliminating the need for a continuous automated inflation protocol.

In addition, some existing inflatable devices are prone to produce defective products during the inflation process due to inaccurate positioning, that is, the inflation of the partial inflatable bag is not full or the air pressure in the bag is too large. After the defective product is taken out, the operator needs to re-adjust the calibration inflatable device, which is not conducive to improving efficiency. In order to achieve higher inflation quality requirements, some inflatable devices have a complicated structure, are inconvenient to operate, and are not easy to move, and also affect the main performance of the inflatable device itself.

It is worth mentioning that many pumps are commonly found in the market, which can be divided into hand-held, pedal-operated and standing. The pump generally includes a cylindrical pump body and a piston located inside the pump body, the piston being coupled to an operating unit such as a handle or a pedal. In addition, the pump further includes a nozzle for ejecting gas, and the air-packing device and the air-filled packaging bag are connected via the air nozzle, so that the piston moves to remove gas through operation of the operating unit. Compressed into the inflatable packaging device and the inflatable packaging bag. In addition, the pump may also include a hose for connecting to the air nozzle and the pump body to increase the operational convenience of use. However, the above-mentioned various inflators are not so convenient in use, which easily cause air leakage and are laborious and time consuming. Therefore, electric air cylinders also appear on the market, and their main application fields are automobile tires, magic wheels, bicycle tires, and rubber boats for inflation. However, in order to achieve high-efficiency operation, the electric air pump is usually used. There is a larger power motor, and it can be used when an external power source is connected. Such a device can be said to simply separate the inflatable packaging device and the inflatable device of the working platform of the airbag into a single product. Although it is also possible to charge the gas into the air-packing device or the air-filled bag using the electric air pump, it is not advantageous for carrying in use.

Summary of the invention

It is an object of the present invention to provide a packaging container having air cushioning properties, the inner layer comprising an inflatable body and the outer layer being a package body, the inflatable body being mounted with the package body to be effective in use The packaging container is prevented from being damaged or deformed by collision, and provides an air cushioning effect for the item to be packaged.

Another object of the present invention is to provide a packaging container having air cushioning properties because the inflatable body is fixed to the package body so that it can be transported together to the packaging site, and is convenient to store, thereby saving transportation and storage. the cost of.

Another object of the present invention is to provide a packaging container having air cushioning properties, the inflatable body may not be inflated during transportation and storage, and the package body and the inflatable body are compact or even Flatten the state to save space.

Another object of the present invention is to provide a packaging container having air cushioning properties that, when in use, inflates the inflatable body, the inflatable body expanding, automatically driving the outer or inner layer of the package The body forms the shape of the packaging container for ease of use.

Another object of the present invention is to provide a packaging container having air cushioning performance, which does not need to be added to the packaging body after being inflated, thereby saving packaging time.

Another object of the present invention is to provide a packaging container having air cushioning properties, in which an article to be packaged can be placed in the package, and then the inflatable body is inflated, such that the inflatable body Closely surrounding the article to be packaged, and the outer layer of the package applies pressure to the inflatable body, so that the package is more compact, and the article to be packaged can obtain a better cushioning effect.

Another object of the present invention is to provide a packaging container having air cushioning properties, which can be installed inside the package by various means, such as glue sticking, nylon buckle bonding, etc., package body The materials can be paper materials, cloth materials, cortical materials, plastic materials, composite materials, etc., and thus are widely used.

Another object of the present invention is to provide a packaging container having air cushioning properties, which is suitable for both retail and wholesale packaging of large quantities of articles to be packaged, and for e-commerce sales of smaller quantities of articles to be packaged. .

Another object of the present invention is to provide a packaging container having air cushioning properties, the inflatable body comprising an inflatable body, the inflatable body being adapted to surround the item to be packaged, thereby placing the item to be packaged The packaging container having the inflatable body can provide a cushioning effect to the article to be packaged after the packaging container having the air cushioning property is subjected to pressure from various directions, so that the article to be packaged does not Squeezed.

Another object of the present invention is to provide a packaging container having air cushioning properties, wherein the inflatable body has a structure such that the article to be packaged is suitable for being stably held within the packaging container having air cushioning properties. Therefore, the article to be packaged is not easily slid out of the packaging container having air cushioning properties.

Another object of the present invention is to provide a packaging container having air cushioning properties, wherein the packaging container having air cushioning properties is inflated into the packaging container having air cushioning performance by one or more one-way inflation valves. The inflation valve is automatically closed after reaching the predetermined air pressure in the inflatable body, thereby being convenient to use.

Another object of the present invention is to provide an inflatable device in which the inflatable device is capable of continuously and automatically inflating the inflation cushioning body, in which only a gas supply is required.

Another object of the present invention is to provide an inflatable device that is suitable for automatically performing an air cushioning body having a one-way valve Inflation, after the end of the inflation, the gas leakage is prevented because of the self-sealing property of the one-way valve.

Another object of the present invention is to provide an inflator that changes the air intake mode of the air cushion body, that is, the air intake mode of the air intake hole formed by superimposing two layers of film in the prior art. And the continuous inflation of the inflatable cushioning body of the sputum can be performed, thereby improving the charging efficiency.

Another object of the present invention is to provide an inflator device in which both ends of an inflation passage of the inflation cushion body are sealed and an upper surface forms an air inlet, and the inflation device passes through an upper surface of the inflation passage of the inflation cushion body The air inlet is inflated so as to be completely different from the prior art inflation mode.

Another object of the present invention is to provide an inflator device in which, when inflated, the gas enters the inflation passage in a direction perpendicular to the inflation cushion body, and then enters each air chamber, thereby being completely different. The prior art intake mode.

Another object of the present invention is to provide an aeration device wherein the inflation device is capable of reducing air source loss during a duty cycle.

Another object of the present invention is to provide an inflator device, wherein the inflating device can make the inflation cushion body fully inflated under the influence of factors such as balancing the positioning tool, the air pressure, the weight of the head, and the like in the working cycle. The position of the single-membrane perforated area on the inflation passage of the inflation port and the inflation cushion body, that is, the position of the intake port of the inflation buffer body, forms a relative seal, reduces air source loss, and maintains a relatively stable inflation pressure inside the inflation buffer body.

Another object of the present invention is to provide an inflatable device wherein the inflatable device is capable of improving the reliability of continuous operation by positioning and limiting the inflation cushion.

Another object of the present invention is to provide an inflation method capable of continuously and automatically inflating the inflation cushion body of the crucible, and only a gas source supply is required during the inflation process.

Another object of the present invention is to provide an inflator device in which the inflating device maintains the relative displacement of the inflated cushioning body during the working cycle by the restriction of the positioning tool, thereby improving the reliability of continuous operation.

Another object of the present invention is to provide an inflator device, wherein the inflator device passes through the self-gravity after completing the inflating operation of one of the inflating cushion bodies and after the inflating of the inflating cushion body is removed The lowering and inflating of the next inflatable cushioning body enables complete automatic inflation of the inflatable cushioning body.

Another object of the present invention is to provide an inflatable device which is capable of automatically descending due to gravity to contact the next one of the inflatable cushion bodies by providing a corresponding sliding fit structure, thereby being simple The mechanical structure achieves continuous automatic inflation of the formed inflatable cushioning body.

Another object of the present invention is to provide an inflator device in which, after the first one of the inflating cushions is inflated and removed, the positioning tool of the inflating device continues to be inserted downwardly as the nose is lowered. The inflatable cushioning body, thereby realizing dynamic positioning of the inflatable cushioning body by the positioning tool.

Another object of the present invention is to provide an inflator device in which the first one of the inflating cushions is inflated, and the positioning tool of the inflating device is inserted into at least one of the inflating cushions to be inflated, thereby When the inflation cushioning body is inflated and taken away, it does not cause the following uninflated next inflation cushioning body to not be displaced relative to the removal action of the previous one of the inflation cushioning bodies.

Another object of the present invention is to provide an inflatable device in which the first one of the inflatable cushioning bodies is inflated and after being taken away, the handpiece can be pressed against the next one of the inflatable cushioning bodies under the action of its own gravity, and The air inlet of the nose The air inlet of the next one of the air cushions can be aligned to automatically inflate the next one of the air cushions, thereby reducing the air loss.

Another object of the present invention is to provide an inflator device in which, by providing a limiting device for the inflatable cushioning body, it is ensured that the inflatable cushioning body of the crucible is restrained without being opposed to the loading platform. Displacement.

Another object of the present invention is to provide an inflatable device in which a defective product which is not accurately positioned in an air-filled cushioning body that has been loaded can be directly pulled out from the inflatable device, and the inflatable cushioning body is not affected after being pulled out. It can be used to inflate with conventional manual inflation without wasting material.

Another object of the present invention is to provide an inflatable device, wherein the inflatable device has a simple structure and can be formed into a customized model such as a desktop or a portable by industrial design means without affecting main performance.

Another object of the present invention is to provide an inflation cushioning body, wherein the side of the inflation passage of the inflation cushion body has an air inlet so as not to be inflated from both ends of the inflation passage, but from the side of the inflation passage Gas, thereby changing the manner in which the inflation cushion is inflated.

Another object of the present invention is to provide an inflation cushioning body in which a plurality of said inflation cushioning bodies are adapted for automated continuous inflation operation, thereby reducing manual participation.

Another object of the present invention is to provide an air cushioning body which changes the air intake mode of the air cushion body, that is, the air intake mode of the air intake hole which is formed by superimposing two layers of film in the prior art, and The inflatable cushioning body of the sputum can be continuously and automatically inflated, thereby improving the charging efficiency.

Another object of the present invention is to provide an inflation cushion body in which both ends of the inflation passage of the inflation cushion body are sealed and an upper surface forms the intake port, such that the inflation cushion body passes through the upper surface of the inflation passage The air inlet is inflated so as to be completely different from the prior art inflation mode.

Another object of the present invention is to provide an inflation cushion body, wherein when the inflation cushion body is inflated, gas enters the inflation passage in a direction perpendicular to the inflation buffer body, and then enters each air chamber, thereby completely Different from the prior art intake mode.

Another object of the present invention is to provide an inflation cushioning body, wherein when the inflation cushioning body is adapted to be continuously inflated by an inflation device, after the inflation operation of one of the inflation cushioning bodies is completed, and the inflation is completed by inflation After the buffer body is removed, the handpiece of the inflatable device descends by its own gravity and inflates the next one of the inflation buffers, thereby completing the continuous automatic inflation of the inflatable cushioning body and reducing the air source loss. .

Another object of the present invention is to provide an aeration cushioning body, wherein in some embodiments, the inflation cushioning body comprises one or more gas storage units formed by at least two layers of plenum membranes, and at least two layers of valve membranes are formed a valve, and an inflating unit formed by two inflating end portions integrally connected to the plurality of gas storage units, the inflation valve forming at least one intake passage that inflates the corresponding gas storage unit An inflation passage is formed between the two of the inflated ends to form an end seal, the inflation passage having an air inlet disposed in the one of the air chamber membranes.

Another object of the present invention is to provide an aeration cushioning body, wherein in some embodiments, the inflation cushioning body comprises one or more gas storage units formed by at least two layers of plenum membranes, and at least two layers of valve membranes are formed a valve, and an inflating unit formed by two inflating end portions integrally connected to the plurality of gas storage units, the inflation valve forming at least one intake passage that inflates the corresponding gas storage unit An inflation passage is formed between the two inflated ends to form an end seal, the inflation passage having an intake port disposed in one of the valve membranes.

Another object of the present invention is to provide an inflation cushioning body which is capable of satisfying the inflation cushioning body. The requirement for continuous automatic inflation forms the air inlet during the manufacturing process.

It is an object of the present invention to provide a portable inflatable device that is portable and can quickly and easily fill air to a situation where inflation is desired, such as an inflation cushioning device.

Another object of the present invention is to provide a portable inflatable device that is a hand-held inflatable device for ease of operation.

Another object of the present invention is to provide a portable inflatable device that is applied to, for example, an air-filled packaging device or an air-filled packaging bag to increase the utility of the air-filled packaging device or the air-filled packaging bag and to achieve convenience of storage.

Another object of the present invention is to provide a portable inflatable device including a motor unit for extracting air such that in the inflated mode, the air is filled into the air-filled packaging device or the inflated package via a gas nozzle. Internally, and after accommodating or packaging the item to be packaged using the air-packing device or the air-filled bag, the air-packing device or the air-filled bag may provide a cushioning function for protecting the item to be packaged And it is possible to avoid damage to the articles in the air-packing device or the air-filled bag.

Another object of the present invention is to provide a portable inflatable device including a solenoid valve and a piston for pumping the air such that in the inflation mode, the air is filled into the air-filled package via a gas nozzle. The inside of the device or the inflated package, and after the inflatable package or the inflatable package is used to receive or package the item to be packaged, the inflatable package or the inflatable package may provide a cushioning function for The article to be packaged is protected and articles damaged in the air-packing device or the air-filled bag can be avoided.

Another object of the present invention is to provide a portable inflatable device including a housing that houses the pump body, the solenoid valve unit, the piston, the control unit, the power supply unit, and the air nozzle, A compact structure for facilitating the portable inflatable device to be formed.

In order to achieve the above object, the present invention provides a packaging container having an air cushioning property, comprising at least one package that is foldable and at least one inflatable packaging cushion, wherein the package is capable of forming an accommodation space, The inflatable package cushion body can form an accommodating space after being inflated, the inflatable package cushioning body is connected to the inner side or the outer side of the package body, and when the inflatable package cushion body is in an uninflated state, the package body is at In the folded state, the package can be deployed when the inflatable package cushion is inflated.

According to another aspect of the present invention, the present invention provides a packaging container having air cushioning properties, comprising a first package, a second package, and at least one inflatable package cushion, wherein the first package is capable of Forming a first accommodating space, the second package body is configured to form a second accommodating space, and the first package body is disposed in the second accommodating space of the second package body, An inflatable packaging cushion is disposed between the first package and the second package.

Therefore, the packaging container with air cushioning property according to the present invention can not only be adapted to packages of different specifications, but also can determine the specific shape and structure of the inflatable packaging bag according to the nature of the articles to be transported, among other things. The packaging container with air cushioning performance according to the present invention not only facilitates storage and transportation, but also saves the opening step in use, thereby saving the opening time and improving the working efficiency of the user.

According to another aspect of the present invention, there is also provided an inflation apparatus for inflating at least one inflation cushion body, wherein the inflation cushion body includes at least one gas storage unit and an inflation unit connected thereto, the inflation passage Having an inflation passage, each of the gas storage units has at least one gas storage chamber that is inflated through the inflation passage, the gasification unit surface is provided with an air inlet, and the inflatable device includes a machine head including an inflation An aeration nozzle of the mouth, wherein the inflation nozzle is adapted to be press-fitted to the inflation unit, and when there is a supply of gas, a gas is adapted to pass through the inflation port of the inflation nozzle Entering the air inlet, entering each of the air storage chambers through the inflation passage to complete an inflation operation of the air cushion body.

According to another aspect of the present invention, the present invention also provides an inflation method for inflating at least one inflation buffer, wherein the inflation cushion includes at least one gas storage unit and an inflation unit connected thereto. The inflation passage has an inflation passage, and each of the gas storage units has at least one gas storage chamber that is inflated through the inflation passage, and the gasification unit surface is provided with an air inlet, and the inflation method includes the following steps:

(A) an inflation port of a gas nozzle of a handpiece is aligned with the position of the air inlet of the gas cushion body;

(B) At the supply of the gas source, the gas enters the intake port via the inflation port, and then enters each of the gas storage chambers via the inflation passage to complete the inflation operation of the inflation cushion body.

According to another aspect of the present invention, there is also provided an inflation cushioning body, wherein the inflation cushion body comprises one or more gas storage units formed by at least two layers of gas chamber membranes and mutually connected to the gas storage unit An inflatable unit formed by the two inflated end portions, wherein a surface of one of the inflated ends of the inflating unit has an air inlet, and a gas is adapted to enter the inflation passage through the inflation port, and Entering the corresponding gas storage unit through the intake passage.

According to still another aspect of the present invention, there is provided a method of manufacturing an aerated cushion body, the method of manufacturing comprising the steps of:

a first plenum membrane is perforated for forming an air inlet of the plenum; and

Arranging the first plenum membrane and a second plenum membrane and an inflation valve in a superposed manner, and forming the inflatable buffer body having at least one gas storage unit and at least one gasification unit through a series of heat seals, wherein The air inlet is formed in the airing unit, wherein when inflating, gas enters an inflation passage of the airing unit from the air inlet, and enters each of the gas storage units from the inflation passage via the inflation valve And the gas reverse osmosis is prevented by the one-way backstop function of the inflation valve.

According to another aspect of the present invention, there is provided a method of manufacturing an aerated cushion body comprising the steps of:

a first valve membrane is perforated for forming an air inlet of the inflation cushioning body;

Arranging the first valve film and a second valve film, and the first and second plenum films in a superposed manner, and forming the at least one gas storage unit and the at least one gas-filling unit via a series of heat seals An inflation cushioning body, wherein the valve film and the first and second plenum membranes have a convex portion to form the inflation unit, wherein the air inlet is formed in the inflation unit, wherein inflating At the time, gas enters the inflation passage of the inflation unit from the intake port, and further enters each of the gas storage units from the inflation passage via the inflation valve.

According to another aspect of the present invention, the present invention provides a method of inflating an inflation cushioning body, wherein the inflation cushioning body includes at least one gas storage unit and an inflation unit connected, the inflation passage having an inflation passage, each of which The gas storage unit has at least one gas storage chamber that is inflated through the gas passage, and the gasification unit surface is provided with an air inlet, wherein the gas filling method comprises: when the gas source is supplied, the gas enters through the gas inlet The air inlet is then introduced into each of the air storage chambers via the inflation passage to complete the inflation operation of the air cushion body.

According to another aspect of the present invention, there is also provided a portable inflatable device for inflating at least one device to be inflated, comprising:

At least one pump body;

At least one motor unit, the motor unit being disposed on the pump body for drawing the gas into the pump body when the motor unit is in operation;

At least one control unit coupled to the motor unit, the control unit controlling adjustment of the motor unit and being capable of switching the motor unit to at least one charge mode;

At least one gas nozzle connected to the pump body, and when the control unit manipulates the motor unit in the inflation mode, the gas reaches the gas nozzle via the pump body for performing inflation operating.

According to another aspect of the present invention, there is also provided a portable inflatable device for inflating at least one device to be inflated, comprising: at least one gas nozzle, at least one pump body, at least one solenoid valve unit, at least one piston, and at least one a control unit, wherein the piston is disposed inside the pump body and connected to the solenoid valve unit, and the control unit controls the solenoid valve unit to drive the piston to move inside the pump body to generate at least one pressure Poor, wherein the gas nozzle is connected to the pump body, and when in the inflation mode, gas is filled through the gas nozzle to the device to be inflated via the pressure difference.

According to another aspect of the present invention, there is also provided a method of inflating a portable inflatable device for rapidly inflating at least one device to be inflated, the device to be inflated being formed of at least two layers of air chamber membranes, including at least one one-way The valve has at least one inflation inlet, characterized in that the inflation method of the portable inflatable device comprises the following steps:

Activating at least one motor unit to allow gas outside the portable inflatable device to enter the portable inflatable device;

Directing gas to at least one gas nozzle via at least one gas cylinder of at least one pump body;

The gas is introduced into the device to be inflated via the gas inlet of the device to be inflated through the gas nozzle, wherein the one-way valve is automatically closed at the end of the inflation.

DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic exploded view of a packaging container having air cushioning properties in accordance with the present invention.

Figure 2 is a schematic view showing the structure of the inflatable packaging cushion in the packaging container having air cushioning performance taken along line A-A of Figure 1 according to the present invention.

Figure 3 is a schematic view showing the structure of the bag portion of the inflatable package cushion in the packaging container having air cushioning properties when placed on the outside.

Figure 4 is a side cross-sectional structural view of the inflatable packaging cushion in a packaging container having air cushioning properties in accordance with the present invention.

Figure 5 is a schematic illustration of the structure of the inflatable packaging cushion in a packaging container having air cushioning properties when uninflated and planarly deployed in accordance with the present invention.

Figure 6 is a cross-sectional structural view of the inflatable packaging cushion in a packaging container having air cushioning properties in accordance with the present invention.

Figure 7 is a front elevational view of the first embodiment of the packaging container with air cushioning properties of the present invention in a non-use state.

Figure 8 is a perspective view showing the first embodiment of the packaging container having air cushioning performance according to the present invention.

Figure 9 is a partially enlarged schematic view showing the first embodiment of the packaging container having air cushioning performance according to the present invention.

FIG. 10A is a schematic perspective view showing the first embodiment of the packaging container having air cushioning performance after the package is folded.

FIG. 10B is a schematic view showing the connection structure of the package body and the inflatable package cushion body in the first embodiment of the packaging container with air cushioning performance according to the present invention.

Figure 11 is a front elevational view showing the second embodiment of the packaging container having air cushioning performance in a non-use state.

Figure 12 is a perspective view showing the structure of a second embodiment of the packaging container having air cushioning performance according to the present invention.

Figure 13 is a partially enlarged schematic view showing the second embodiment of the packaging container having air cushioning performance according to the present invention.

Figure 14 is a perspective view showing the structure of the second embodiment of the packaging container having air cushioning performance after the package is folded.

Figure 15 is a front elevational view showing the third embodiment of the packaging container having air cushioning performance in a non-use state.

Figure 16 is a perspective view showing the third embodiment of the packaging container having air cushioning performance according to the present invention.

Figure 17 is a perspective view showing the three-dimensional structure of the packaging container having air cushioning performance after the package is folded.

Figure 18 is a front elevational view showing the fourth embodiment of the packaging container having air cushioning performance in a non-use state.

Figure 19 is a perspective view showing the structure of a fourth embodiment of the packaging container having air cushioning performance according to the present invention.

Figure 20 is a perspective view showing the structure of the fourth embodiment of the packaging container having air cushioning properties after the package is folded.

21A is a perspective view showing the structure of a fifth embodiment of a packaging container having air cushioning performance according to the present invention.

21B is still another perspective structural view of a fifth embodiment of a packaging container having air cushioning performance according to the present invention.

Fig. 22 is a development view showing the fifth embodiment of the packaging container having air cushioning performance in a non-use state according to the present invention.

Figure 23 is a schematic view showing the structure of the inflatable packaging cushion body in the fifth embodiment of the packaging container having air cushioning performance according to the present invention.

Figure 24 is a schematic view showing the structure of the inflatable package cushion body in the fifth embodiment of the packaging container having air cushioning performance according to the present invention.

Figure 25 is a perspective view showing the three-dimensional structure of the packaging container having the air cushioning performance according to the present invention.

Figure 26 is a perspective view showing the structure of a sixth embodiment of the packaging container having air cushioning performance according to the present invention.

Figure 27 is a schematic exploded view showing the sixth embodiment of the packaging container having air cushioning performance in a non-use state.

Figure 28 is a schematic view showing the structure of the inflatable packaging cushion body in the sixth embodiment of the packaging container having air cushioning performance according to the present invention.

Figure 29 is a perspective view showing the three-dimensional structure of the packaging container having air cushioning performance after the package is folded.

Figure 30 is a cross-sectional structural view showing a sixth embodiment of a packaging container having air cushioning performance according to the present invention.

Figure 31 is a schematic view showing the structure of the seventh embodiment of the packaging container having air cushioning performance in a non-use state according to the present invention.

Figure 32 is a perspective view showing a modified embodiment of the first to seventh embodiments of the packaging container having air cushioning performance according to the present invention.

Figure 33 is a schematic exploded view of the above-described modified embodiment of the first to seventh embodiments of the packaging container having air cushioning performance according to the present invention.

Figure 34 is a view showing another modified embodiment of the first to seventh embodiments of the packaging container having air cushioning properties according to the present invention.

Figure 35 is an exploded perspective view showing the above-described another modified embodiment of the first to seventh embodiments of the packaging container having air cushioning performance according to the present invention.

Figure 36 is a perspective view of an inflatable device in accordance with an embodiment of the present invention.

Figure 37A is a schematic view showing the structure of the inflation cushion body when it is not inflated according to the above embodiment of the present invention.

Figure 37B is a cross-sectional view taken along line B-B of the inflation cushioning body according to the above embodiment of the present invention.

Figure 38 is a perspective view showing the restriction of a limiting device of the inflatable device according to the above embodiment of the present invention.

Figure 39 is a perspective view of an inflatable device in accordance with the above-described embodiment of the present invention, illustrating an inflation cushioning body inflated to an expanded state.

Figure 40 is an enlarged schematic view showing a head of a pneumatic device mounted on a slide rail according to the above embodiment of the present invention.

Figure 41 is a perspective view showing the structure of a loading platform of the inflatable device according to the above embodiment of the present invention.

Figure 42 is an enlarged schematic view showing the side of the head of the inflatable device according to the above embodiment of the present invention.

Figure 43 is a schematic enlarged plan view showing the bottom of a handpiece of an inflatable device according to the above embodiment of the present invention.

Figure 44 is a partially enlarged schematic view of a portion of Figure 42.

Figure 45 is a schematic view showing the inflation of an air bag having a one-way valve and an intake hole at the end in the prior art.

Figure 46A is a schematic exploded view of an inflation cushioning body in an uninflated state, in accordance with an embodiment of the present invention.

Figure 46B is a perspective view showing the structure of the inflatable cushioning body in accordance with one embodiment of the present invention.

Figure 47 is a cross-sectional structural view showing an inflation cushioning body according to the above embodiment of the present invention.

Figure 48 is a schematic view showing the structure of a modified embodiment of the inflation cushioning body according to the above embodiment of the present invention.

Figure 49 is a cross-sectional structural view showing a gas cushion body according to the above embodiment of the present invention.

Figure 50 is a schematic view showing the structure of another modified embodiment of the inflation cushioning body according to the above embodiment of the present invention.

Figure 51 is a cross-sectional structural view showing an inflation cushioning body according to the above embodiment of the present invention.

Figure 52A is a plan view showing a planar development of another modified embodiment of an inflation cushioning body in an uninflated state, which is folded and three-dimensionally molded to form an inflatable three-dimensional packaging bag, in accordance with an embodiment of the present invention.

Figure 52B is a perspective view showing the structure of the above-described modified embodiment of an inflation cushion body in an inflated state according to the present invention.

Figure 53A is a plan development view of another modified embodiment of an inflation cushioning body in an uninflated state, in accordance with an embodiment of the present invention.

Figure 53B is a perspective view showing the above-described modified embodiment of an inflation cushioning body in an inflated state according to the present invention.

54A is another modified embodiment of an inflation cushioning body in an uninflated state, in accordance with an embodiment of the present invention. A schematic diagram of the plane unfolding.

Figure 54B is a perspective view showing the above-described modified embodiment of an inflation cushioning body in an inflated state according to the present invention.

Figure 55 is a schematic view showing the structure of another modified embodiment of the inflation cushioning body according to the above embodiment of the present invention.

Figure 56 is a cross-sectional structural view showing the inflation cushion body according to the above embodiment of the present invention.

Figure 57 is a schematic view showing the structure of another modified embodiment of the inflation cushioning body according to the above embodiment of the present invention.

Figure 58 is a cross-sectional structural view showing the inflation cushion body according to the above embodiment of the present invention.

Figure 59 is a schematic view showing the structure of another modified embodiment of the inflation cushioning body according to the above embodiment of the present invention.

Figure 60 is a schematic view showing the structure of another modified embodiment of the inflation cushioning body according to the above embodiment of the present invention.

Figure 61 is a schematic view showing the structure of an inflatable device of a sputum inflatable cushioning body according to the above embodiment of the present invention.

Figure 62 is a schematic view showing the structure of a positioning tool of an inflation device of an inflatable cushioning body according to the above embodiment of the present invention.

Fig. 63 is a schematic view showing the state in which the inflatable cushioning body according to the above embodiment of the present invention is inflated by the above-described inflation apparatus.

Figure 64 is a schematic illustration of a portable inflatable device in accordance with one embodiment of the present invention.

Figure 65 is a schematic illustration of a portable inflator in an inflated mode or an exhaust mode, in accordance with an embodiment of the present invention.

Figure 66 is a circuit schematic diagram of a portable inflatable device in accordance with an embodiment of the present invention.

Figure 67 is a schematic illustration of a nozzle of a portable inflatable device connected to a hose in accordance with an embodiment of the present invention.

Figure 68 is a schematic illustration of a portable inflatable device including a heat sealing unit in accordance with an embodiment of the present invention.

Figure 69 is a schematic illustration of different aspects of a portable inflatable device in accordance with an embodiment of the present invention.

Figure 70 is a schematic illustration of a portable inflatable device in accordance with another embodiment of the present invention.

71 and 72 are schematic illustrations of an inflation mode of a portable inflatable device in accordance with an embodiment of the present invention.

Figure 73 is a circuit schematic diagram of a portable inflatable device in accordance with an embodiment of the present invention.

Figure 74 is a schematic illustration of a nozzle of a portable inflatable device connected to a hose in accordance with an embodiment of the present invention.

Figure 75 is a schematic illustration of a portable inflatable device including a heat sealing unit in accordance with an embodiment of the present invention.

Figure 76 is an air-filled packaging device suitable for inflating using the portable inflatable device described above, in accordance with the above-described embodiments of the present invention.

Figure 77 is a cross-sectional view of an air-packing device suitable for inflation using the above-described portable inflatable device to illustrate the structure of its check valve in accordance with the above-described embodiment of the present invention.

detailed description

The following description is presented to disclose the invention to enable those skilled in the art to practice the invention. The preferred embodiments in the following description are by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention as defined in the following description may be applied to other embodiments, modifications, improvements, equivalents, and other embodiments without departing from the spirit and scope of the invention.

It should be understood by those skilled in the art that in the disclosure of the present invention, the terms "longitudinal", "transverse", "upper", "lower", "front", "back", "left", "right", " The orientation or positional relationship of the indications of "upright", "horizontal", "top", "bottom", "inside", "outside", etc. is based on the orientation or positional relationship shown in the drawings, which is merely for convenience of description of the present invention and Simplify the description, not the instructions or hints The above-mentioned terminology must be constructed and operated in a particular orientation, and the above terms are not to be construed as limiting the invention.

It will be understood that the term "a" is understood to mean "at least one" or "one or more", that is, in one embodiment, the number of one element may be one, and in other embodiments, the element The number can be multiple, and the term "a" cannot be construed as limiting the quantity.

As shown in FIG. 1 to FIG. 10B, the packaging container with air cushioning property according to the present invention comprises at least one package 50 and at least one inflatable packaging cushion 60 disposed inside the package 50, the inflatable The package cushion 60 can form a receiving space 601 after being inflated for holding a transported article and the inflatable package cushion 60 is fixedly coupled to the inner side of the package 50 to ensure that the transported article is in the The interior of the package 50 is fixed together with the inflatable package cushion 60 during transport to maintain a consistent relative positional relationship with the package 50. It will be appreciated that the inflatable package cushion 60 is preferably an inflatable package in which the packaged items may be stored.

1 to 6 are an inflatable package cushion 60 in a first preferred embodiment of a packaging container having air cushioning properties according to the present invention, which has an inflatable structure to allow for each after inflation Packaged articles such as electronic products, food, medical products, chemical raw materials, biological materials, plastic ceramics, fast-moving consumer goods, etc. provide gas buffering effect, and when not in use, can be stored and transported without being inflated, and then inflated on site. So that it is very convenient to use.

In this preferred embodiment of the invention, the inflatable packaging cushion 60 in the packaging container having air cushioning properties can be embodied as an air cushioning material, i.e., the charged gas is exemplified by air, although it will be understood by those skilled in the art. Yes, other gases may be used as needed in the application. In this preferred embodiment, it can be formed into a three-dimensional package after inflation to provide an air cushioning effect for a packaged item.

In this preferred embodiment, the inflatable packaging cushion 60 in the packaging container having air cushioning properties includes at least one inflation cushioning body 10, that is, a three-dimensional packaging bag or a plurality of containers formed by one of the inflatable cushioning bodies 10. The inflatable cushion body 10 is formed into a three-dimensional packaging bag by a plastic sealing connection such as bonding or heat sealing. In the example shown in Figs. 1 to 6 of the present invention, it is formed by one of the inflation cushion bodies 10. More specifically, referring to FIG. 6, the inflatable cushion body 10 includes at least two layers of

plenum films

11 and 12 formed by a series of planar molding seams 30 and three-dimensional molding slits 40 including one or more connected gas storage units 13. In the three-dimensional packaging bag, a gas storage chamber 14 for storing gas is formed in each of the gas storage units 13.

It will be understood by those skilled in the art that the planar molding seam 30 is used to plastically form a multilayer film to form a planar cushioning material as shown in FIG. 5, and the three-dimensional plastic sealing slit 40 is used for further molding the above-mentioned planar cushioning material. The inflatable package cushion 60 in the packaging container having air cushioning properties is formed into the three-dimensional packaging device having a spatial three-dimensional configuration and capable of accommodating the packaged article, as shown in FIG. The planar molding seam 30 and the three-dimensional molding seam 40 may join the multilayer films together by bonding or heat sealing, preferably, in this embodiment, the planar molding seam 30 and the three-dimensional The molding seams 40 can all be implemented to be formed by a heat sealing process.

More specifically, the planar molding slit 30 includes a plurality of rows of slits 31 that divide the two layers of the

chamber films

11 and 12 into a plurality of the gas storage units 13. That is, preferably, each of the slits 31 is formed by a heat sealing process which heat seals the two layers of the

gas chamber films

11 and 12 such that a column is formed between the adjacent two gas storage units 13 Sew 31. The partition slit 31 may be a continuous heat seal line such that a plurality of the gas storage units 13 are independent of each other. It can be understood that, as shown in FIG. 5, a row of the slits 31 on the top side and the bottom side can respectively become the top side boundary seams of the gas cushion body 10 and Bottom side boundary seam. The partitioning slit 31 may also be an intermittent heat sealing line such that a plurality of the gas storage units 13 communicate with each other. The gas storage unit 13 may be in various shapes such as a strip shape, a circular shape, a polygonal shape or other irregular shape, etc., as shown in FIGS. 1 to 6, the inflation cushion body 10 of the present invention may include a plurality of Inflatable columns arranged side by side, but this party is not limited in this regard.

In this preferred embodiment, referring to Fig. 6, the gas cushion body 10 further includes an inflation valve 20 formed of at least two layers of

valve membranes

21 and 22, the

valve membranes

21 and 22 of the inflation valve 20 being The plenum membranes 11 and 12 are disposed superposed on each other, and an intake passage 23 for inflating the plenum 14 is formed between the

valve membranes

21 and 22. It is to be understood that the lengths of the

valve films

21 and 22 are shorter than the

plenum films

11 and 12. When the air reservoir 14 is inflated through the intake passage 23 and the air pressure in the air reservoir 14 reaches a predetermined requirement, the air pressure in the air reservoir 14 acts on the

valve membranes

21 and 22 Upper, so that the

valve films

21 and 22 are attached to one of the plenum membranes, thereby closing the intake passage 23, so that the inflation valve 20 functions as a one-way valve. When at least one of the intake passages 23 is formed in each of the gas storage units 13, and each of the gas storage units 13 is independent of each other, when one of the gas storage units 13 is damaged and leaks, other places are The gas storage unit 13 is not affected and continues to have an air cushioning effect.

It can be understood that the

plenum films

11 and 12 of the gas cushion body 10 and the

valve films

21 and 22 of the gas filling valve 20 can be made of various suitable film materials, such as polyethylene film. The polypropylene film, the polyvinyl chloride film, the polyester film, the polystyrene film or the composite film, etc., are also not limited in this respect as long as they are suitable flexible films. It is worth mentioning that, in order to increase the one-way sealing effect, the

valve films

21 and 22 of the inflation valve 20 may also be self-adhesive films modified by adding chemical components to the above-mentioned film.

The gas cushion body 10 further includes a main channel unit 15 connected to each of the gas storage units 13, preferably integrally extending from each of the gas storage units 13. More specifically, in this preferred embodiment, the main channel unit 15 is perpendicular to the direction in which the gas storage unit 13 extends. For example, in this embodiment, each of the gas storage units 13 extends in a lateral direction, and the main channel unit 15 extends in the longitudinal direction. The main passage unit 15 forms a main passage 151, and the main passage 151 has an inflation port 152. When the position of the inflation port 152 is provided with an inflation nozzle and an inflation operation is performed, gas flows along the inflation port 152. Entering the main passage 151 in the longitudinal direction, and entering each of the gas storage units 13 in the lateral direction, and the valve film of the inflation valve 20 after reaching a predetermined gas pressure in each of the gas storage chambers 14 21 and 22 are attached to one of the

air chamber films

11 or 12 to achieve self-closing to prevent the charged gas from being reverse osmosis into the main passage 151.

It is worth mentioning that it can be understood that the main channel unit 15 may be formed by two layers of the

plenum films

11 and 12, or may be formed by two layers of the

valve films

21 and 22, or one of the layers. The

gas chamber film

11 or 12 and one of the

valve films

21 or 22 are formed.

As shown in FIG. 5, the planar molding seam 30 further includes a continuous sealed one side seal 32 on the left and right sides of the inflatable cushion body 10 and a continuous sealed main passage sealing slit 33 on the left side, The main passage 151 is formed between the side seal 32 on the left side and the main passage seal slit 33. It can be understood that the edge seal 32 is formed by a plastic sealing process such as bonding or heat sealing and sealingly connects two layers of the

gas chamber films

11 and 12, which are sealed by a molding process such as bonding or Heat sealing is formed and two layers of the

plenum films

11 and 12 and the two layers of the

valve films

21 and 22 are respectively joined together at a position corresponding to the air inlet of the intake passage 23, as shown in FIG. For example, the main passage sealing slits 33 on the upper and lower sides formed by one heat sealing process respectively correspond to the positions of the air inlets of the intake passage 23 The plenum membrane 11 and the valve membrane 21 are heat-sealed, and the plenum membrane 12 and the valve membrane 22 are heat-sealed, and the other locations further enclose the plenum membrane and the valve membrane. The main passage sealing slit 33 divides the inflation cushion body 10 into the main passage unit 15 and the gas storage unit 13.

As shown in FIG. 5, each of the gas storage units 13 includes two rows of mutually spaced air guiding slits 34 at a position adjacent to the main passage 151, which are connected by heat sealing to the

gas chamber films

11 and 12 and The valve membranes 21 and 22 are formed, and the intake passages 23 formed by the

valve membranes

21 and 22 are located between the two rows of the air guiding slits 34.

Referring to FIG. 6, the

valve films

21 and 22 are further heat-sealed to the gas chamber film 11 through a plurality of joint slits 35, such that when a predetermined gas pressure is reached in the gas storage chamber 14, gas pressure acts on the gas chamber The

valve films

21 and 22 are simultaneously pressed toward the plenum film 11 and finally attached to the plenum film 11 because of the arrangement of the joint slits 35, thereby closing the intake passage 23. That is, the joint slit 35 is heat-sealed to connect the two layers of the

valve films

21 and 22 and one layer of the gas chamber film 11. Further, as shown in Fig. 5, the shape of each of the joint slits 35 is designed such that it further functions to prevent backflow of gas, that is, when the gas in the gas storage chamber 14 is intended to be reflowed. It will be blocked by the joint seam 35 and cannot be easily reverse osmosis into the main passage 151.

In addition, when the flat molding slits 30 are formed by heat sealing, the inlet passages 23 of the

valve films

21 and 22 of the inflation valve 20 may be formed by providing a heat-resistant barrier device, after the heat sealing process, The heat resistant barrier device is taken out. In the preferred embodiment, a heat-resistant layer 24 is disposed between the

valve films

21 and 22 of the inflation valve 20, as shown in FIGS. 5 and 6, for example, may be a heat-resistant ink attached to One of the inner surfaces of the

valve film

21 or 22, such that when the main passage sealing slit 33 is heat-sealed, the two layers of the

valve films

21 and 22 are not heat-sealed, so that the intake passage 23 is enabled to communicate with the main passage 151 without closing its inlet port due to heat sealing.

In the preferred embodiment, the main passage 151 is formed by two layers of the

plenum films

11 and 12, each of the heat-resistant layer 24 and the

valve films

21 and 22 having an extension into the main passage 151. The planar molding seam 30 further includes an array of mutually spaced apart seams 36 arranged in the longitudinal direction corresponding to the positions of the extensions of the heat-resistant layer 24, which are provided because of the arrangement of the heat-resistant layer 24. Two layers of the

gas chamber films

11 and 12 and two layers of the

valve films

21 and 22 are respectively joined together, and the two layers of the

valve films

21 and 22 are not heat-sealed, and the joints 36 are arranged such that When the inflation cushion body 10 is inflated, after the gas enters the main passage 151, the

adjacent valve membranes

21 and 22 can be expanded together with the correspondingly connected

chamber membranes

11 and 12 to open the corresponding said Air passage 23.

The planar molding seam 30 further includes a plurality of rows of intermittently heat-sealed bending seams 37. The inflated cushioning body 10 is adapted to be bent along the bending seams 37, so that the inflation cushioning body 10 is A plurality of side walls are formed. More specifically, the bending slits 37 divide each of the gas storage units 13 into a plurality of sub-gas storage units 131, and the bending slits 37 may be located at a middle position of the gas storage unit 13, and one side is respectively formed on the two sides. The passages 132 are connected such that the adjacent sub-gas storage units 131 are connected to each other as shown in FIG. It can be understood that the bending slits 37 can also be located at two sides of the gas storage unit 13 , and the communication passages 132 are located at a middle position of the gas storage unit 13 . Accordingly, it will be understood that each of the plurality of bends 37 is heat sealed to join the two layers of the

chamber films

11 and 12.

As shown in FIG. 5, in the first embodiment of the packaging container for air cushioning properties according to the present invention, the inflatable package cushion 60 may also be provided as an inflatable packaging cushion 60 having a multi-stage cushioning effect. The planar molding seam 30 further includes an array of gas barriers 38, which are a plurality of the gas storage units 13 on the top side of the gas cushioning body 10, as shown in the three gas storage units 13 shown in the figure. The inlet passage 23 is sealed, that is, disposed adjacent to the tail of the intake passage 23, and the two layers of the

chamber membranes

11 and 12 and the two layers of the

valve membranes

21 and 22 are heat-sealed. Thus each The gas storage unit 13 cannot be inflated to form an uninflated gas column.

Correspondingly, a plurality of the laterally extending gas storage units 13 are divided into a plurality of inflatable gas storage units 13a and a plurality of non-inflatable gas storage units 13b arranged in the longitudinal direction by the arrangement of the gas barriers 38. . For example, as shown in Fig. 5, the three gas storage units 13b on the upper side cannot be inflated, in this embodiment of the invention, for forming an inner bag portion 10b, and the four inflating portions on the bottom side. The unit 13a can be inflated to form an outer bag portion 10a. That is, in this preferred embodiment of the invention, the multi-stage cushioning effect can be provided by the inflatable outer bag portion 10a and the non-inflated inner bag portion 10b.

It can be understood that the inner bag portion 10b is merely an example, and in other embodiments, the inner bag portion 10b may not be provided.

As shown in FIG. 7 to FIG. 10, in the first embodiment of the packaging container having air cushioning performance according to the present invention, the packaging container having air cushioning performance includes a package body 50 and an inflatable packaging cushion body 60. The inflatable package cushion 60 is fixedly disposed inside the package 50 and the bottom of the inflatable package cushion 60 is pre-sealed. Wherein, the inflatable package cushion body 60 is made of the air cushion body 10, and the package body 50 is used for packaging the inflatable package cushion body 60, the inflatable package cushion body 60 and the package body. 50 fixedly connected to ensure that the articles to be transported are fixed to the inside of the package 50 together with the inflatable package cushion 60 during transportation without arbitrarily moving, thereby improving the safety of the articles to be transported. And aesthetics. Moreover, when used in the field, the inflatable package cushion 60 can automatically open the package 50 when inflated, thereby facilitating use.

As shown in FIG. 7, the package body 50 is a foldable rectangular parallelepiped paper package, and the ratio of length to width of the rectangular paper package is about 4:4:1, as shown in FIG. 7 and FIG. Shown are respectively a schematic three-dimensional structure of the package body 50 before and after folding. It can be understood that the package 50 can also have more than six sides, such as an octahedron or the like. The material can be paper or plastic or composite. The invention is not limited in this respect. The above ratio of length to width is also by way of example only and not limiting of the invention. Similarly, the materials, and ratios of the medium packages of the various embodiments mentioned hereinafter are also by way of example only and not limiting of the invention.

As shown in FIG. 7, in the first embodiment of the present invention, the package body 50 can be overlapped into a double-layer cardboard before being folded, which is very space-saving and convenient for storage, storage and transportation when not in use. After folding, it becomes a packaging container with air cushioning performance according to the present invention, which can provide double-layer cushioning protection for the articles to be transported. The inflatable package cushion 60 is adhered to the inside of the package 50, and the bottom of the inflatable package cushion 60 has been pre-sealed, and after inflation, a receiving space for accommodating the transported article can be formed. 601.

In detail, as shown in FIG. 8, the package body 50 includes a first side 501, a second side 502, a third side 503, and a fourth side 504. The inflatable package cushion body The gas storage unit 13 in the air cushion body 10 in 60 is laterally disposed to coincide with the opening direction of the package 50. In other words, the gas storage unit 13 in the air cushion body 10 included in the inflatable package cushion body 60 and the first side of the package body 50 when the package body 50 is opened 501, the second side 502, the third side 503 and the fourth side 504 form an annular direction.

It should be noted that the first side 501, the second side 502, the third side 503, and the fourth side 504 of the package body 50 may be integrally formed into a ring shape, which is formed by folding. The first side 501, the second side 502, the third side 503, and the fourth side 504 of the package 50 may also be formed by stitching a sheet of paper to form the annular shape. Folding into the first side 501, the second side 502, and the third side of the package 50 503 and fourth side 504. If the paper package 50 is formed by stitching a paper sheet, the side wall of the package 50 may have a seam 51 for stitching both ends of the paper sheet, such as Stitching by thumb stitching or other means. If the first side 501, the second side 502, the third side 503, and the fourth side 504 of the package 50 are the ring shape formed by sewing and folding a piece of paper. Then, preferably, the stitches 51 at both ends of the paper plate are left with overlapping edges 52 to ensure the firmness of the package 50.

Alternatively, the seam 51 of the package 50 can be anywhere in the package 50. Preferably, the stitching portion 51 of the package body 50 is located at the intersection of the first side 501, the second side 502, the third side 503, and the fourth side 504 of the package body 50. That is, the stitching portion 51 of the package body 50 is located at the edge of the package body 50, so that the appearance of the package body 50 is more beautiful. More preferably, the overlapping edge 52 formed by the stitching portion 51 is located inside the package body 50, thereby further improving the aesthetic appearance of the package body 50.

As shown in FIGS. 7 to 9, since the inflatable package cushion 60 is fixedly coupled to the inner side of the package body 50, the inflatable container is in a non-use state when the air cushioning performance packaging container is in a non-use state. The packaging cushion 60 is also in a non-inflated state, that is, the gas storage unit 13 in the inflatable packaging cushion 60 is not filled with gas, but only two layers of the

chamber films

11 and 12 which overlap each other, so the whole The inflatable packaging cushion 60 can be flattened, has a very small volume, and does not occupy a space, so that the packaging container with air cushioning property of the present invention is very convenient for storage and storage when not in use.

As shown in FIG. 8, it is noted that in the first embodiment of the packaging container having air cushioning properties according to the present invention, the inflatable cushioning body 60 formed by the air cushioning body 10 includes at least Two pairs of obliquely shaped plastic seams 41. The inflatable cushioning body 60 formed by the air cushion body 10 has an opening 61 and four bending slits 37 corresponding to the height direction of the package body 50, and the oblique plastic sealing slit 41 is formed in the air. Any two opposite sides of the cushion body 10, and the oblique plastic sealing seam 41 is located between the bending seam 37 and the top end of the inflatable packaging cushion body 60 formed by the air cushion body 10, and The height of the starting point of the oblique plastic sealing slit 41 on the bending seam 37 to the bottom surface of the inflatable packaging cushion body 60 is less than or equal to the height of the packaging body 50.

In the first embodiment of the present invention, the oblique plastic sealing seam 41 on either side of the air cushion body 10 includes a first oblique plastic sealing slit 411 and a second oblique plastic sealing slit 412. The first oblique plastic sealing slit 411 and the second oblique plastic sealing slit 412 intersect at the top end of the inflatable packaging cushion 60 formed by the air cushion body 10. In other words, the first oblique plastic sealing slit 411 and the second oblique plastic sealing slit 412 are formed on the one surface of the air buffer body with two plastic sealing slits which are obliquely disposed without intersecting, thereby making the air The inflatable package cushion 60 formed by the buffer body 10 can be folded and sealed along the first oblique plastic sealing slit 411 and the second oblique plastic sealing slit 412, thereby making the inflatable packaging cushion body 60 a An inflatable packaging cushion 60 having a three-dimensional shape and capable of sealing.

It is to be noted that, in the first embodiment of the present invention, the inflatable package cushion body 60 includes two pairs of the oblique plastic sealing slits 41, and each pair of the oblique plastic sealing slits 41 respectively includes the first An obliquely-shaped plastic sealing slit 411 and a second oblique plastic sealing slit 412 are respectively disposed on two opposite sides of the inflatable packaging cushion body 60, as shown in FIG. In the first embodiment of the present invention, the oblique plastic sealing slits 41 are respectively disposed on the first side 501 and the third side 503, and then joined by the second side 502 and the fourth adjacent thereto. The slits 31 on the side edges 504 together fold the lid 61 of the inflatable package cushion 60 to form a top cover to provide further detail to the articles being transported therein. Air cushioning effect.

As a variation of the first embodiment of the present invention, those skilled in the art can determine the tilt according to actual conditions. The shape and position of the plastic sealing seam 41, such as the oblique plastic sealing seam 41, is disposed on the other two opposite sides of the inflatable packaging cushion body 60, that is, the person skilled in the art can choose to use the oblique plastic sealing seam 41 is disposed on the two longitudinal sides of the inflatable packaging cushion 60 or the oblique plastic sealing slits 41 are disposed on the two widthwise sides of the inflatable packaging cushion 60. Further, the slope of the oblique plastic sealing slit 41 may also be determined according to the specific size of the article to be transported as long as the object to be transported can be accommodated and can be accommodated by the package 50. In addition, a person skilled in the art can also improve the buffering effect of the inflatable packaging cushion 60 on the transported article by other means, such as sealing the inflatable packaging cushion 60 by strapping or the like. In other words, as long as the technical solution identical or similar to the present invention is adopted, the technical problem that is the same as or similar to the present invention is solved, and the technical effects identical or similar to those of the present invention are achieved, and are all within the scope of protection of the present invention. The specific embodiments of the present invention are not limited thereto.

The inflatable package cushion body 60 formed by the air cushion body 10 includes a margin 62 for the air cushion body 10 to form the inflatable package cushion body through the three-dimensional plastic sealing seam 40. The margin formed by 60 o'clock. In other words, when the air cushion body 10 is formed into a three-dimensional shape having the opening 61 through the three-dimensional plastic sealing slit 40 in a planar shape, the air cushioning body 10 is mutually lapped and molded by the three-dimensional plastic sealing seam 40. The place 62 will be formed. Furthermore, the margin 62 is the side formed when the air cushion body 10 is in a planar state through the three-dimensional plastic sealing slit 40. Since the margin 62 is outside the inflatable package cushion 60 formed by the air cushion body 10, the margin 62 generally does not have an air cushioning effect, that is, the margin 62 is also The

plenum films

11 and 12 are composed, but the rim 62 cannot be inflated because of the three-dimensional squeezing seam 40, so the rim 62 is a planar film.

In a first embodiment of the packaging container having air cushioning properties according to the present invention, the inflatable packaging cushion 60 can be fixedly coupled to the package 50 in any orientation, such as in the inflatable package. The bottom of the buffer body 60 is fixed to the bottom of the package body 50, or is fixed on either side of the air package bag 60 and the side surface of the package body 50 in contact therewith, even in the air. All sides of the package 60 are fixed to all of the inner sides of the package 50 to achieve the effect of securing the inflatable package cushion 60 to the inside of the package 50.

As shown in FIGS. 8 to 10, it is worth noting that in the first embodiment of the packaging container having air cushioning properties according to the present invention, the package 50 is formed by sewing through a sheet of paper. The annular shape is further folded into the first side 501, the second side 502, the third side 503, and the fourth side 504 of the package 50, and has a top edge and a bottom edge. Thus, the package 50 retains the overlapping edge 52 where it is placed. The overlapping edge 52 is disposed on the inner side of the package body 50. Further, in the first embodiment of the present invention, the stitching portion 51 of the package body 50 is stitched by one or several nails 521, so the overlapping edge 52 of the package body 50 and the same The first side 501 of the package 50 that is coincident is stitched by the push pin 521. In other words, the overlapping edge 52 of the paper package 50 is re-bonded and fixed to the first side 501 by the push pin 521, so the overlapping side 52 and the first side coincident with it There is a gap 53 between the sides 501.

As a still further preferred embodiment of the present invention, in the first embodiment of the packaging container having air cushioning properties according to the present invention, the margin of the inflatable packaging cushion 60 formed by the air cushion body 10 62 is disposed between the overlapping edge 52 and the gap 53 between the first side 501 and fixed. A person skilled in the art can determine the manner of fixing the margin 62 of the inflatable packaging cushion 60 and the package 50 according to needs or actual conditions. Therefore, the margin 62 of the air-packing bag 60 is adhered between the overlapping edge 52 and the gap 53 between the first side 501 by glue or the like, or may be The push pin 521 directly fixes the front edge 62 of the air package bag 60 between the overlap edge 52 and the gap 53 between the first side edges 501. The technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the same or similar technical effects as the present invention are achieved, and the present invention is within the scope of the present invention. The specific implementation manner is not limited thereto.

The inflatable package cushion 60 can be fixedly connected to the inner side of the package body 50 in various ways, as shown in FIG. 10B, which is the inflatable package cushion body 60 and the first embodiment of the present invention. Another way of connecting the package 50 is described. As shown in FIG. 10B, in the connection mode, the inflatable package cushion 60 and the case are realized by fixing the outer bottom of the inflatable package cushion 60 to the inner bottom of the case 50. The fixation of the body 50.

Specifically, in this embodiment, a glue layer 200 is applied to the outer bottom of the inflatable package cushion 60, and a glue layer 200 is applied to a corresponding portion of the inner bottom of the package 50, The inflatable package cushion 60 is thereby fixed to the inside of the package 50. However, the scope of protection of the present invention is not limited to the specific embodiment, and those skilled in the art may also set the connection manner of the inflatable packaging cushion 60 to the package 50 according to actual conditions or customer requirements, such as by other means. The inflatable packaging cushion 60 is fixedly coupled to the inner bottom of the package 50, such as by being adhesively attached or detachable to the bottom edge 62 of the inflatable packaging cushion 60. The inner bottom of the side 502 of the body 50, wherein the bottom margin 62 is the non-inflated film portion of the bottommost side of the inflatable packaging cushion 60, or may be a gas storage unit, but by heat sealing or Bonding or the like causes the corresponding air chamber not to be inflated, thereby forming such a bottom margin 602, which is convenient for connection with the package 50. Of course, the bottom margin 602 is connected to the package 50. The location can also be an inflatable gas storage unit. Alternatively, the inflatable package cushion body 60 and the package body 50 are provided in a detachable fixed connection manner, such as by providing a buckle, a push pin, etc., as long as the same or similar technical solutions as the present invention are adopted. The technical problems that are the same as or similar to the present invention are solved, and the technical effects that are the same as or similar to the present invention are all within the scope of the present invention, and the specific embodiments of the present invention are not limited thereto.

Specifically, in the first embodiment of the packaging container having air cushioning performance according to the present invention, the package body 50 is embodied as a paper package having a folding length of 305 mm, a width of 305 mm, and a height of 140 mm. The box can carry items within 3 kilograms, that is, the safe weight of the articles to be transported does not exceed 3 kilograms. As an improvement of the present invention, a person skilled in the art can determine the specific size of the package 50 according to the specific size of the article to be transported. If the volume and weight of the article to be transported are small, the package 50 is small. The size of the package can also be scaled or otherwise reduced. Similarly, if the volume and weight of the article to be transported are large, the size of the package 50 is also scaled up or scaled to Adapt to the needs of the item being transported. In other words, the technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the technical effects identical or similar to those of the present invention are achieved, and are within the protection scope of the present invention. The specific embodiments of the present invention are not limited thereto.

Next, a method of manufacturing and using the first embodiment of the packaging container having air cushioning property according to the present invention will be further briefly described with reference to FIGS. 7 to 10.

The manufacturing method of the first embodiment of the packaging container having air cushioning performance is:

Setting a package body 50 having a length, width and height ratio of about 4:4:1;

An inflatable package cushion 60 is disposed, and the bottom of the inflatable package cushion 60 is pre-sealed;

Providing at least two pairs of oblique plastic sealing slits 41 at the opening of the inflatable packaging cushion 60;

The inflatable package cushion 60 is fixed to the inside of the package 50.

Among them, those skilled in the art can interchange the manufacturing steps of the package 50 and the manufacturing steps of the inflatable package cushion 60 according to actual conditions. The technical problem of the same or similar to the present invention is solved as long as the technical solution is the same as or similar to the present invention, and the same or similar technical effects as the present invention are achieved, and are all within the scope of the present invention. The specific embodiments are not limited thereto.

The first embodiment of the packaging container having air cushioning performance is used to inflate the inflatable packaging cushion 60, and the inflated packaging cushion 60 can expand the package 50, And forming a receiving space 601;

A transported article is placed in the accommodating space 601 of the inflatable package cushion 60; the package 50 is sealed.

As shown in FIG. 11, in a second embodiment of the packaging container having air cushioning performance according to the present invention, the packaging container having air cushioning performance includes a package body 50A and an inflatable package cushioning body 60A. The inflatable package cushion 60A is fixedly disposed inside the package 50A and the bottom of the inflatable package cushion 60A is pre-sealed and can form an accommodation space 601A after being inflated for holding the transported article. Wherein, the inflatable package cushion body 60A is made of the air cushion body 10, and the package body 50A is used for packaging the inflatable package cushion body 60A, the inflatable package cushion body 60A and the package body. The inner side of the 50A is fixedly coupled to ensure that the article to be transported is fixed to the inside of the package 50A together with the inflatable package cushion 60A during transportation without arbitrarily moving, thereby improving the transported article. Safety and aesthetics. Moreover, when used in the field, the inflatable package cushion body 60A can automatically open the package book 50A when inflated, thereby being convenient to use.

As shown in FIG. 12, the package body 50A is a rectangular parallelepiped paper package, and the ratio of length to width of the rectangular paper package is about 3.5:2.5:1, as shown in FIG. 11 and FIG. FIG. 14 is a schematic perspective view showing the three-dimensional structure of the package body 50A before and after folding. FIG. 14 is a schematic perspective view of the package body 50A after sealing.

As shown in FIG. 11 and FIG. 12, in the second embodiment of the present invention, the package body 50A can be overlapped into a double-layer cardboard before folding, which is very space-saving and convenient for storage, storage and transportation when not in use. And after folding, it becomes a packaging container with air cushioning property according to the present invention, which can provide double-layer cushioning protection for the articles to be transported. The inflatable package cushion 60A is adhered to the inside of the package 50A, and the bottom of the inflatable package cushion 60A has been pre-sealed, and after inflation, a receiving space for accommodating the transported article can be formed. 601A.

In detail, as shown in FIG. 12 and FIG. 13, the package body 50A includes a first side 501A, a second side 502A, a third side 503A and a fourth side 504A, and a top and bottom. In the sealing structure, the gas storage unit 13 in the air cushion body 10 in the inflatable package cushion body 60A is disposed laterally, in conformity with the opening direction of the package body 50A. In other words, the gas storage unit 13 in the air cushion body 10 included in the inflatable package cushion body 60A and the first side of the package body 50A when the package body 50A is opened The annular direction formed by the 501A, the second side 502A, the third side 503A, and the fourth side 504A coincide.

It is worth mentioning that the first side 501A, the second side 502A, the third side 503A and the fourth side 504A of the package body 50A may be integrally formed into a ring shape, and The first side 501A, the second side 502A, the third side 503A, and the fourth side 504A of the package 50A may also be passed by a piece of paper. The annular shape formed by stitching is further folded into the first side 501A, the second side 502A, the third side 503A, and the fourth side 504A of the package 50A. If the paper package 50A is formed by stitching a paper plate, the side wall of the package 50A may have a seam 51A for stitching both ends of the paper plate, such as Stitching by thumb stitching or other means. If the first side 501A, the second side 502A, the third side 503A, and the fourth side 504A of the package 50A are the ring shape formed by sewing and folding a piece of paper. Preferably, then, the stitches 51A at both ends of the paper sheet are left with overlapping edges 52A to ensure the firmness of the package 50A.

Further, the stitching portion 51A of the package body 50A may be at any position of the package body 50A. Preferably, the stitching portion 51A of the package body 50A is located at the intersection of the first side 501A, the second side 502A, the third side 503A, and the fourth side 504A of the package body 50A. That is, the stitching portion 51A of the package body 50A is located at the edge of the package body 50A, thereby making the appearance of the package body 50A more beautiful. More preferably, the overlapping side 52A formed by the stitching portion 51A is located inside the package body 50A, thereby further improving the aesthetic appearance of the package body 50A.

As shown in FIG. 13, since the inflatable package cushion body 60A is fixedly coupled to the inner side of the package body 50A, the inflatable package cushion body is when the package container having air cushioning performance is in a non-use state. 60A is also in a non-inflated state, that is, the gas storage unit 13 in the inflatable package cushion 60A is not filled with gas, but only two layers of

air chamber films

11 and 12 overlapping each other, so the entire The air-filled packaging cushion 60A can be flattened, has a very small volume, and does not occupy a space, so that the packaging container with air cushioning property according to the present invention is very convenient for storage and storage when not in use.

It should be noted that, as a modification of the second embodiment of the present invention, the first side 501A, the second side 502A, the third side 503A, and the fourth side 504A of the package 50A may also be The inflatable packaging cushion 60A is fixed to the inner side of the package 50A by being integrally formed into the ring shape. Accordingly, in the second embodiment of the present invention, the outer middle portion of the air package bag 60A and the inner side of the package body 50A are positioned to each other. In other words, the positioning point of the air-packing bag 60A and the package body 50A is located between the outer side of the air-packing bag 60A and the inner side of the package body 50A, and is fixed by bonding.

As a preferred embodiment of the second embodiment of the packaging container having air cushioning properties according to the present invention, the inflatable packaging cushion 60A may also be fixedly coupled to the package 50A in any orientation, for example, in the The bottom of the inflatable package cushion 60A is fixed to the bottom of the package 50A, or is fixed on either side of the air package 60A and the side of the package 50A in contact therewith, and may even be All the side faces of the air-packaging bag 60A are fixed to all the inner side faces of the package body 50A, thereby achieving the effect of fixing the inflatable package cushioning body 60A to the inner side of the package body 50A.

Preferably, in the second embodiment of the present invention, the inflatable package cushion body 60A formed by the air cushion body 10 also includes at least two pairs of diagonally-shaped plastic sealing seams 41A formed by the air cushion body 10. The inflatable package cushion body 60A has an opening 61A and four bending slits 37 which are aligned with the height direction of the package body 50A, and the oblique plastic sealing slits 41A are formed on any two opposite sides of the air cushion body 10. a side surface, and the oblique plastic sealing seam 41A is located between the bending seam 37 and the top end of the inflatable packaging cushion body 60A formed by the air cushion body 10, and the oblique plastic sealing seam 41A is The height from the starting point on the bending seam 37 to the bottom surface of the inflatable packaging cushion body 60A is less than or equal to the height of the package body 50A, so that the inflatable packaging cushion body 60A can be folded by the package. The housing 50A is housed.

Correspondingly, in the second embodiment of the present invention, the oblique plastic sealing seams 41A on either side of the air cushion body 10 include a first oblique plastic sealing slit 411A and a second oblique plastic sealing slit 412A. The first oblique plastic sealing slit 411A and the second oblique plastic sealing slit 412A intersect at the top end of the inflatable packaging cushion body 60A formed by the air cushion body 10. In other words, the first oblique plastic sealing slit 411A and the second oblique plastic sealing slit 412A are formed on the one surface of the air buffer body by two plastic slits which are obliquely disposed without intersecting, thereby making the air The inflatable package cushion 60 formed by the buffer body 10 can be folded and sealed along the first oblique plastic sealing slit 411A and the second oblique plastic sealing slit 412A, thereby making the inflatable packaging cushion body 60A a An inflatable packaging cushion 60A having a three-dimensional shape and capable of sealing.

It is to be noted that, in the second embodiment of the present invention, the two pairs of oblique plastic sealing slits 41A are respectively disposed on two opposite side walls of the inflatable packaging cushion body 60A, such as in the On one side 501A and third side 503A, or on the second side 502A and the fourth side 504A, by joining the other two

sides

502A and 504A or the quilts on 501A and 503A 31. The opening 61A of the inflatable package cushion 60A is folded together to provide a further air cushioning effect for the articles being transported therein.

In addition, a person skilled in the art can determine the shape and position of the oblique plastic sealing seam 41A according to actual conditions, for example, the oblique plastic sealing seam 41A is disposed on the other two opposite sides of the inflatable packaging cushion body 60A. And the person skilled in the art can choose to arrange the oblique plastic sealing seam 41A on the two lengthwise sides of the inflatable packaging cushion body 60A or to set the oblique plastic sealing seam 41A to the inflatable. The two sides of the packaging buffer 60A are oriented in the width direction. Further, the slope of the oblique plastic sealing slit 41A may be determined according to the specific size of the article to be transported as long as it can accommodate the transported article and can be accommodated by the package 50A. In addition, a person skilled in the art can also improve the buffering effect of the inflatable packaging cushion body 60A on the transported article by other means, such as sealing the inflatable packaging cushion body 60A by means of strapping or the like. In other words, as long as the technical solution identical or similar to the present invention is adopted, the technical problem that is the same as or similar to the present invention is solved, and the technical effects identical or similar to those of the present invention are achieved, and are all within the scope of protection of the present invention. The specific embodiments of the present invention are not limited thereto.

The inflatable package cushion body 60A formed by the air cushion body 10 includes a margin 62A for the air cushion body 10 to form the inflatable package cushion body 60A through the three-dimensional plastic sealing seam 40. The margin formed by the time. In other words, when the air cushion body 10 is formed into a three-dimensional shape having the opening 61A through the three-dimensional plastic sealing slit 40 in a planar shape, the air cushioning body 10 is mutually lapped and molded by the three-dimensional plastic sealing seam 40. The place will form the margin 62A. Furthermore, the margin 62A is the side formed when the air cushion body 10 is in a planar state through the three-dimensional plastic sealing slit 40. Since the margin 62A is outside the inflatable package cushion 60A formed by the air cushion body 10, the margin 62A generally does not have an air cushioning effect, that is, the margin 62A is also The

plenum films

11 and 12 are composed, but the rim 62A cannot be inflated because of the three-dimensional squeezing slit 40, so the rim 62A is a planar film.

As shown in FIGS. 12 to 14, in the second embodiment of the present invention, since the package body 50A is formed by stitching by using a paper plate, the ring shape is formed by folding. The side wall of the package 50A, and thus the package 50A, retains the overlapping side 52A at the seam 51A. The overlapping side 52A is disposed inside the package body 50A. Further, in the first embodiment of the present invention, the package body The suture 51A of 50A is sewn by one or several push pins 521A, so that the overlapping side 52A of the package 50A is sewn to the first side 501A of the package 50A with which it is superposed. In other words, the overlapping side 52A of the paper package 50A is re-fixed and fixed with the first side 501A by the push pin 521A, so the overlapping side 52A and the first side coincident with it There is a gap 53A between the sides 501A.

Therefore, the margin 62A of the inflatable package cushion 60A formed by the air cushion body 10 is disposed between the gap 53A between the overlapping side 52A and the first side 501A and fixed. A person skilled in the art can determine the manner of fixing the margin 62A of the inflatable packaging cushion 60A and the package 50A according to needs or actual conditions, which may be described by glue or the like. The remaining edge 62A is adhered between the gap 53A between the overlapping edge 52A and the first side edge 501A, and the margin of the air package bag 60A may be directly directly passed through the push pin 521A. A 62A engagement is fixed between the gap 53A between the overlapping side 52A and the first side 501A. The technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the same or similar technical effects as the present invention are achieved, and the present invention is within the scope of the present invention. The specific implementation manner is not limited thereto.

As with the first embodiment, the inflatable package cushion 60A can be fixedly attached to the inner side of the package body 50A in various ways, such as shown in FIG. 10B, by applying glue or the like to the inflatable package. The bottom outer surface of the buffer body 60A or the bottom inner surface of the package body 50A, thereby fixing the inflatable package cushion body 60A to the inner side of the package body 50A, or the inflatable package cushion body 60A The bottom edge of the bottom portion is fixed to the inner side of the bottom of the package body 50A, or is a detachable fixed connection manner, such as by fixing a connection between the inflatable package cushion body 60A and the package body by providing a buckle, a pin or the like. 50A, if the same or similar technical solutions as the present invention are adopted, the technical problems that are the same as or similar to the present invention are solved, and the technical effects that are the same as or similar to the present invention are all within the protection scope of the present invention. The specific embodiments of the present invention are not limited thereto. Specifically, in the second embodiment of the packaging container having air cushioning performance according to the present invention, the package body 50A is embodied as a paper package having a length of 279 mm, a width of 216 mm, and a height of 140 mm. The box can carry items within 1.5 kilograms, that is, the safe weight of the articles to be transported does not exceed 1.5 kilograms. As an improvement of the present invention, a person skilled in the art can determine the specific size of the package body 50A according to the specific size of the article to be transported, and if the volume and weight of the article to be transported are small, the package body 50A The size of the package can also be scaled or otherwise reduced. Similarly, if the volume and weight of the article to be transported are large, the size of the package 50A is also scaled up or scaled to Adapt to the needs of the item being transported. In other words, the technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the technical effects identical or similar to those of the present invention are achieved, and are within the protection scope of the present invention. The specific embodiments of the present invention are not limited thereto.

In addition, the mermaid of the present invention can determine the specific connection manner of the second embodiment of the packaging container with air cushioning performance according to the present invention and the specific manufacturing method of the package body 50A according to the actual situation, as long as the present invention is adopted. The same or similar technical solutions of the second embodiment solve the technical problems that are the same or similar to the present invention, and achieve the same or similar technical effects as the present invention, which are all within the protection scope of the present invention, and the specifics of the present invention The implementation is not limited to this.

Next, a method of manufacturing and using the second embodiment of the packaging container having air cushioning property according to the present invention will be further briefly described with reference to Figs. 11 to 14 .

The manufacturing method of the second embodiment of the packaging container having air cushioning performance is:

Setting a package body 50A having a length, width and height ratio of about 3.5:2.5:1;

An inflatable package cushion 60A is disposed, and the bottom of the inflatable package cushion 60A is pre-sealed;

The inflatable package cushion 60A is fixed to the inside of the package 50A.

Among them, those skilled in the art can interchange the manufacturing steps of the package 50A and the manufacturing steps of the inflatable package cushion 60A according to actual conditions. The technical problem of the same or similar to the present invention is solved as long as the technical solution is the same as or similar to the present invention, and the same or similar technical effects as the present invention are achieved, and are all within the scope of the present invention. The specific embodiments are not limited thereto.

The second embodiment of the packaging container having air cushioning performance is used to inflate the inflatable packaging cushion 60A, and the inflated packaging cushion 60A can open the package 50A. And forming a receiving space 601A;

Put a transported item into the accommodating space 601A of the inflatable packaging cushion 60A;

Sealing the inflatable packaging cushion 60A;

The package 50A is sealed.

As shown in FIG. 15, a third embodiment of the packaging container having air cushioning performance according to the present invention includes the packaging body 50B and an inflatable packaging cushion body 60B. The inflatable package cushion body 60B is fixedly disposed inside the package body 50B and the bottom of the inflatable package cushion body 60B is pre-sealed and can form an accommodation space 601B after being inflated for placing the transported article. Wherein, the inflatable package cushion body 60B is made of the air cushion body 10, and the package body 50B is used for packaging the inflatable package cushion body 60B, the inflatable package cushion body 60B and the package body. The inner side of the 50B is fixedly coupled to ensure that the article to be transported is fixed to the inside of the package 50B together with the inflatable package cushion 60B during transportation without arbitrarily moving, thereby improving the transported article. Safety and aesthetics.

As shown in FIG. 15 to FIG. 18, the package body 50B is a rectangular parallelepiped paper package, and the ratio of the length to the width of the rectangular paper package is about 5:1:5, as shown in FIG. 15 and FIG. The three-dimensional structure diagram of the package body 50B before and after folding is respectively shown, and FIG. 17 is a schematic perspective view of the package body 50B after sealing.

As shown in FIG. 15, in the third embodiment of the present invention, the package body 50B can be overlapped into a double-layer cardboard before being folded, which is very space-saving and convenient for storage, storage and transportation when not in use. After folding, it becomes a packaging container with air cushioning performance according to the present invention, which can provide double-layer cushioning protection for the articles to be transported. The inflatable package cushion 60B is adhered to the inside of the package 50B, and the bottom of the inflatable package cushion 60B has been pre-sealed, and after inflation, a receiving space for accommodating the transported article can be formed. 601B.

In detail, as shown in FIG. 16, the package body 50B includes a first side 501B, a second side 502B, a third side 503B and a fourth side 504B, and a top and bottom sealing structure. The gas storage unit 13 in the air cushion body 10 in the inflatable package cushion body 60B is disposed laterally, in conformity with the opening direction of the package body 50B. In other words, the gas storage unit 13 in the air cushion body 10 included in the inflatable package cushion body 60B and the first side of the package body 50B when the package body 50B is opened The annular direction formed by the 501B, the second side 502B, the third side 503B, and the fourth side 504B is uniform.

It should be noted that the first side 501B, the second side 502B, the third side 503B, and the fourth side 504B of the package 50B may be integrally formed into a ring shape, and the The first side of the package 50B The side 501B, the second side 502B, the third side 503B, and the fourth side 504B may be formed by stitching a sheet of paper into a circular shape, and then folded into the package 50B. The first side 501B, the second side 502B, the third side 503B, and the fourth side 504B are described. If the paper package 50B is formed by stitching a paper plate, the side wall of the package 50B may have a seam where the ends of the paper plate are stitched (with The sutures 51 in one embodiment are identical in structure, the same as below, such as by suture stitching or other means. If the first side 501B, the second side 502B, the third side 503B, and the fourth side 504B of the package 50B are the ring shape formed by sewing and folding a piece of paper. Preferably, the stitches at both ends of the paper sheet are left with overlapping edges (the same structure as the coincident side 52 in the first embodiment, the same below) to ensure the firmness of the package 50B.

Further, the stitching of the package body 50B may be at any position of the package body 50B. Preferably, the stitching portion of the package body 50B is located at the intersection of the first side 501B, the second side 502B, the third side 503B, and the fourth side 504B of the package body 50B, that is, The stitching portion of the package body 50B is located at the edge of the package body 50B, thereby making the appearance of the package body 50B more beautiful. More preferably, the overlapping side formed by the stitching is located inside the package body 50B, thereby further improving the aesthetic appearance of the package body 50B.

As shown in FIGS. 15 and 16, since the inflatable package cushion body 60B is fixedly coupled to the inner side of the package body 50B, the inflatable container is in a non-use state when the air cushioning performance packaging container is in a non-use state. The package cushion 60B is also in a non-inflated state, that is, the gas storage unit 13 in the inflatable package cushion 60B is not filled with gas, but only two layers of the

chamber films

11 and 12 overlapping each other, so the whole The inflatable packaging cushion body 60B can be flattened, has a very small volume, and does not occupy a space, so that the packaging container with air cushioning property of the present invention is very convenient for storage and storage when not in use.

As shown in FIG. 15, it is noted that in the third embodiment of the present invention, the first side 501B, the second side 502B, the third side 503B, and the fourth side of the package 50B. The side 504B is integrally formed into a ring shape, and the inflatable package cushion body 60B is fixed to the inner side of the package body 50B. Specifically, in the third embodiment of the present invention, the outer middle portion of the air package bag 60B and the inner side of the package body 50B are positioned to each other. In other words, the positioning point of the air-packing bag 60B and the package body 50B is located between the outer side of the air-packing bag 60B and the inner side of the package body 50B, and is fixed by bonding.

As a preferred embodiment of the third embodiment of the packaging container having air cushioning properties according to the present invention, the inflatable packaging cushion 60B can also be fixedly connected to the package 50B in any orientation, for example, in the The bottom of the inflatable packaging cushion 60B is fixed to the bottom of the package 50B, or is fixed on either side of the air bag 60B and the side of the package 50B in contact therewith, and may even be All the side faces of the air-packing bag 60B are fixed to all the inner side faces of the package body 50B, thereby achieving the effect of fixing the inflatable package cushioning body 60B to the inner side of the package body 50B.

As a variant of the third embodiment of the packaging container with air cushioning properties according to the present invention, the inflatable packaging cushion 60B formed by the air cushioning body 10 may also include at least two pairs of diagonally shaped plastic seals. The slit is the same as the structure of the oblique plastic sealing slit 41 described in the first embodiment, hereinafter, the same.

Similarly, the inflatable cushioning body 60B formed by the air cushion body 10 has an opening 61B and four bending slits 37 corresponding to the height direction of the package body 50B, and the oblique plastic sealing seam is formed in the same Any two opposite sides of the air cushion body 10, and the oblique plastic sealing seam is located at the bending seam 37 and the air buffer body 10 Forming between the top ends of the inflatable package cushioning body 60B, and the height of the oblique plastic sealing slit on the bending seam 37 to the bottom surface of the inflatable packaging cushion body 60B is less than or equal to the height The height of the package 50B is such that the inflatable package cushion 60B can be accommodated by the package 50B after being folded.

The inflatable package cushion body 60B formed by the air cushion body 10 includes a margin 62B through which the air cushion body 10 forms the inflatable package cushion body through the three-dimensional plastic sealing seam 40. The remaining side formed by 60B. In other words, when the air cushion body 10 is formed into a three-dimensional shape having the opening 61B through the three-dimensional plastic sealing slit 40 in a planar shape, the air cushioning body 10 is mutually lapped and molded by the three-dimensional plastic sealing seam 40. The place will form the margin 62B. Furthermore, the margin 62B is a side formed when the air cushion body 10 is in a planar state through the three-dimensional plastic sealing slit 40. Since the margin 62B is outside the inflatable package cushion 60B formed by the air cushion body 10, the margin 62B generally does not have an air cushioning effect, that is, the margin 62B is also The

plenum films

11 and 12 are composed, but the rim 62B cannot be inflated because of the three-dimensional squeezing seam 40, so the rim 62B is a planar film. In this embodiment, unlike the above embodiment, the margin 62B is not fixed to the edge of the package 50B, but is fixed to the side 504B, which may be the side 504B. The middle position can also be other areas except the edges.

Specifically, in the third embodiment of the packaging container having air cushioning performance according to the present invention, the package body 50B is embodied as a paper packaging box having a length of 302 mm, a width of 86 mm, and a height of 346 mm. It can carry items within 1.5 kilograms, that is, the safe weight of the articles to be transported does not exceed 1.5 kilograms. As an improvement of the present invention, a person skilled in the art can determine the specific size of the package body 50B according to the specific size of the article to be transported, and if the volume and weight of the article to be transported are small, the package body 50B The size of the package can also be scaled or otherwise reduced. Similarly, if the volume and weight of the article to be transported are large, the size of the package 50B is also scaled up or scaled to Adapt to the needs of the item being transported. In other words, the technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the technical effects identical or similar to those of the present invention are achieved, and are within the protection scope of the present invention. The specific embodiments of the present invention are not limited thereto.

In addition, the mermaid of the present invention can determine the specific connection manner of the third embodiment of the packaging container with air cushioning performance according to the present invention and the specific manufacturing method of the package body 50B according to the actual situation, as long as the present invention is adopted. The same or similar technical solutions of the third embodiment solve the technical problems that are the same or similar to the present invention, and achieve the same or similar technical effects as the present invention, which are all within the protection scope of the present invention, and the specifics of the present invention The implementation is not limited to this.

Next, a method of manufacturing and using the third embodiment of the packaging container having air cushioning property according to the present invention will be further briefly described with reference to Figs. 15 to 17 .

The manufacturing method of the third embodiment of the packaging container having air cushioning performance is:

Setting a package body 50B having a length, width and height ratio of about 4:1:4;

An inflatable package cushion 60B is disposed, and the bottom of the inflatable package cushion 60B is pre-sealed;

The inflatable package cushion 60B is fixed to the inside of the package 50B.

Among them, those skilled in the art can interchange the manufacturing steps of the package 50B and the manufacturing steps of the inflatable package cushion 60B according to actual conditions. The technical problem of the same or similar to the present invention is solved and the technical effects identical or similar to those of the present invention are achieved, as long as the same or similar technical solutions as the present invention are employed, and all belong to the present invention. The specific embodiments of the present invention are not limited thereto.

The method of using the third embodiment of the packaging container having air cushioning properties is as follows:

Opening the bottom of the package body 50B;

The inflatable packaging cushion 60B is inflated, the inflated packaging cushion 60B will expand the package 50B, and form a receiving space 601B;

Put a transported item into the accommodating space 601B of the inflatable packaging cushion 60B;

Sealing the inflatable packaging cushion 60B;

The package 50B is sealed.

As shown in FIG. 18 to FIG. 20, in a fourth embodiment of the packaging container having air cushioning performance according to the present invention, the packaging container having air cushioning performance includes a package 50C and an inflatable packaging cushion 60C. The inflatable package cushion 60C is fixedly disposed inside the package 50C and the bottom of the inflatable package cushion 60C is pre-sealed and can form a receiving space 601A after being inflated for placing the transported article. Wherein, the inflatable package cushion body 60C is made of the air cushion body 10, and the package body 50C is used for packaging the inflatable package cushion body 60C, the inflatable package cushion body 60C and the package body. The inner side of the 50C is fixedly coupled to ensure that the article to be transported is fixed to the inside of the package 50C together with the inflatable package cushion 60C during transportation without arbitrarily moving, thereby improving the transported article. Safety and aesthetics.

As shown in FIG. 18 to FIG. 20, the package body 50C is a rectangular parallelepiped paper package, and the ratio of length to width of the rectangular paper package is about 3:1:5, as shown in FIG. 18 and FIG. The three-dimensional structure diagram of the package body 50C before and after folding is respectively shown in FIG. 20, and FIG. 20 is a schematic perspective view of the package body 50C after sealing.

As shown in FIG. 18 and FIG. 19, in the fourth embodiment of the present invention, the package body 50C can be overlapped into a double-layer cardboard before being folded, which is very space-saving and convenient for storage, storage and transportation when not in use. And after folding, it becomes a packaging container with air cushioning property according to the present invention, which can provide double-layer cushioning protection for the articles to be transported. The inflatable package cushion 60C is adhered to the inside of the package 50C, and the bottom of the inflatable package cushion 60C has been pre-sealed, and after inflation, a receiving space for accommodating the transported article can be formed. 601C.

In detail, as shown in FIG. 19, the package body 50C includes a first side 501C, a second side 502C, a third side 503C, and a fourth side 504C. The inflatable package cushion body The gas storage unit 13 in the air cushion body 10 in 60C is laterally disposed to coincide with the opening direction of the package body 50C. In other words, the gas storage unit 13 in the air cushion body 10 included in the inflatable package cushion body 60C and the first side of the package body 50C when the package body 50C is opened The annular direction formed by the 501C, the second side 502C, the third side 503C, and the fourth side 504C is uniform.

It should be noted that the first side 501C, the second side 502C, the third side 503C, and the fourth side 504C of the package 50C may be integrally formed into a ring shape, and the The first side 501C, the second side 502C, the third side 503C, and the fourth side 504C of the package 50C may also be formed by stitching a sheet of paper to form the annular shape. The first side 501C, the second side 502C, the third side 503C, and the fourth side 504C of the package 50C are folded. If the paper package 50C is formed by stitching a paper plate, the side wall of the package 50C may have a seam where the ends of the paper plate are stitched (with The sutures 51 in one embodiment are identical in structure, the same as below, such as by suture stitching or other means. If the first side 501C, the second side 502C, the third side 503C, and the fourth side of the package 50C The side 504C is the annular shape formed by stitching and folding a sheet of paper, and preferably, the two ends of the paper sheet are left with overlapping edges (with the overlapping side 52 in the first embodiment). The structure is the same, the same below, to ensure the firmness of the package 50C.

Further, the stitching of the package body 50C may be at any position of the package body 50C. Preferably, the stitching portion of the package body 50C is located at the intersection of the first side 501C, the second side 502C, the third side 503C, and the fourth side 504C of the package body 50C, that is, The stitching portion of the package body 50C is located at the edge of the package body 50C, thereby making the appearance of the package body 50C more beautiful. More preferably, the overlapping side formed by the stitching is located inside the package body 50C, thereby further improving the aesthetic appearance of the package body 50C.

As shown in FIG. 18, since the inflatable package cushion 60C is fixedly coupled to the inner side of the package body 50C, the inflatable package cushion body is when the package container having air cushioning performance is in a non-use state. 60C is also in a non-inflated state, that is, the gas storage unit 13 in the inflatable package cushion 60C is not filled with gas, but only two layers of

air chamber films

11 and 12 overlapping each other, so the entire The air-filled packaging cushion 60C can be flattened, has a very small volume, and does not occupy a space, so that the packaging container with air cushioning property of the present invention is very convenient for storage and storage when not in use.

As shown in FIG. 19, it is noted that in the fourth embodiment of the present invention, the first side 501C, the second side 502C, the third side 503C, and the fourth side of the package 50C. The side 504C is integrally formed into a ring shape, and the inflatable package cushioning body 60C is fixed to the inner side of the package body 50C. Specifically, in the fourth embodiment of the present invention, the outer middle portion of the air package bag 60C and the inner side of the package body 50C are positioned to each other. In other words, the positioning point of the air-packing bag 60C and the package body 50C is located between the outer side of the air-packing bag 60C and the inner side of the package body 50C, and is fixed by bonding.

As a preferred embodiment of the fourth embodiment of the packaging container having air cushioning properties according to the present invention, the inflatable packaging cushion 60C may also be fixedly coupled to the package 50C in any orientation, for example, in the The bottom of the inflatable package cushion 60C is fixed to the bottom of the package 50C, or is fixed on either side of the air package 60C and the side of the package 50C that is in contact therewith, and may even be All the side faces of the air-packaging bag 60C are fixed to all the inner side faces of the package body 50C, thereby achieving the effect of fixing the inflatable package cushioning body 60C to the inner side of the package body 50C.

In addition, the difference from the third embodiment described above is that, in the present invention, the bottom sealing structure 509C of the package body 50C is pre-completed, and the top sealing structure 508C is sealed after placing the packaged article. In the above third embodiment, the top side and the bottom side of the package body 50B are not pre-sealed, and when used in the field packaging, the corresponding sides are matched to make the top side and the bottom side sealed.

The inflatable package cushion body 60C formed by the air cushion body 10 includes a margin 62C for the air cushion body 10 to form the inflatable package cushion body through the three-dimensional plastic sealing seam 40. The margin formed by 60C. In other words, when the air cushion body 10 is formed into a three-dimensional shape having the opening 61C through the three-dimensional plastic sealing slit 40, the air cushioning body 10 is mutually lapped and molded by the three-dimensional plastic sealing seam 40. The place will form the margin 62C. Further, the margin 62C is a side formed when the air cushion body 10 is in a planar state through the three-dimensional plastic sealing slit 40. Since the margin 62C is outside the inflatable package cushion 60C formed by the air cushion body 10, the margin 62C generally does not have an air cushioning effect, that is, the margin 62C is also The

gas chamber films

11 and 12 are composed, but because of the three-dimensional plastic sealing seam 40 The reason is that the margin 62C cannot be inflated, so the margin 62C is a planar film.

As a further modification of the fourth embodiment of the present invention, the package body 50C may also be formed into a ring shape by sewing using a sheet of paper, and then folded into the package body 50C by folding. The side wall, therefore, the package body 50C describes the inner side of the package body 50C. Further, in the first embodiment of the present invention, the suture portion of the package body 50C (the same structure as the suture portion 51 in the first embodiment, the same below) is sutured by one or several pushpins. Therefore, the overlapping side of the package body 50C (having the same structure as the overlapping side 52 in the first embodiment, the same hereinafter) is sewn to the first side 501C of the package body 50C overlapping therewith. In other words, the overlapping edge of the paper package 50C is overlapped and fixed with the first side 501C by the pushpin, so the overlapping edge and the first side 501C coincident with it There is a gap between them (the same structure as the gap 53 in the first embodiment, the same below).

Therefore, the margin 62C of the inflatable package cushion 60C formed by the air cushion body 10 is disposed between the gap between the overlapping side and the first side 501C and fixed. A person skilled in the art can determine the manner in which the margin 62C of the inflatable packaging cushion 60C and the package 50C are fixed according to needs or actual conditions, which may be described by glue or the like. The remaining edge 62C is bonded between the gap between the overlapping edge and the first side 501C, and the front edge 62C of the air package bag 60C may be directly bound by the pushpin. Fixed between the overlapping edge and the gap between the first side 501C. The technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the same or similar technical effects as the present invention are achieved, and the present invention is within the scope of the present invention. The specific implementation manner is not limited thereto.

The inflatable package cushion 60C can be fixedly attached to the inner side of the package body 50C in various ways, such as shown in FIG. 10B, and is applied to the bottom outer surface of the inflatable package cushion body 60C by glue or the like. The bottom inner surface of the package 50C is configured to securely connect the inflatable package cushion 60C to the inner side of the package 50C, or to fix the bottom margin of the inflatable package cushion 60C to the package. The inner side of the bottom of the body 50C, or a detachable fixed connection, such as by fixing a connection between the inflatable package cushion 60C and the package 50C by providing a buckle, a pin or the like, as long as the same as the present invention is adopted. The technical solutions that are the same or similar to the present invention are solved by the same or similar technical solutions, and the technical effects that are the same as or similar to the present invention are all within the protection scope of the present invention, and the specific embodiments of the present invention are not This is limited.

Specifically, in the fourth embodiment of the packaging container having air cushioning performance according to the present invention, the package body 50C is embodied as a paper packaging box having a folding length of 137 mm, a width of 41 mm, and a height of 219 mm. It can carry items within 1.5 kilograms, that is, the safe weight of the articles to be transported does not exceed 1.5 kilograms. As an improvement of the present invention, a person skilled in the art can determine the specific size of the package 50C according to the specific size of the article to be transported, and if the volume and weight of the article to be transported are small, the package 50C The size of the package can also be scaled up or scaled down. Similarly, if the volume and weight of the article to be transported are large, the size of the package 50C is also scaled up or scaled to Adapt to the needs of the item being transported. In other words, the technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the technical effects identical or similar to those of the present invention are achieved, and are within the protection scope of the present invention. The specific embodiments of the present invention are not limited thereto.

In addition, the merman of the art can determine the packaging capacity of the present invention with air cushioning performance according to actual conditions. The specific connection manner of the fourth embodiment of the device and the specific manufacturing method of the package 50C therein are as long as the same or similar technical solutions as the fourth embodiment of the present invention are adopted, and the same or similar technical problems as the present invention are solved. The technical effects of the same or similar to the present invention are all within the scope of the present invention, and the specific embodiments of the present invention are not limited thereto.

Next, a method of manufacturing and using the fourth embodiment of the packaging container having air cushioning property according to the present invention will be further briefly described with reference to Figs. 18 to 20 .

The manufacturing method of the fourth embodiment of the packaging container having air cushioning performance is:

Setting a package 50C having a length, width and height ratio of about 3:1:5;

An inflatable package cushion 60C is disposed, and the bottom of the inflatable package cushion 60C is pre-sealed;

The inflatable package cushion 60C is fixed to the inside of the package 50C.

Among them, those skilled in the art can interchange the manufacturing steps of the package 50C and the manufacturing steps of the inflatable package cushion 60C according to actual conditions. The technical problem of the same or similar to the present invention is solved as long as the technical solution is the same as or similar to the present invention, and the same or similar technical effects as the present invention are achieved, and are all within the scope of the present invention. The specific embodiments are not limited thereto.

The fourth embodiment of the packaging container having air cushioning performance is used as follows:

The inflatable packaging cushion 60C is inflated, the inflated packaging cushion 60C will expand the package 50C, and form a receiving space 601C;

Put a transported item into the accommodating space 601C of the inflatable packaging cushion 60C;

Sealing the inflatable packaging cushion 60C;

The top of the package 50C is sealed.

As shown in FIG. 21A and FIG. 21B, in a fifth embodiment of the packaging container having air cushioning performance according to the present invention, the packaging container having air cushioning performance comprises a package body 50D and an inflatable packaging cushion body 60D. The inflatable package cushion 60D is fixedly disposed inside the package 50D. Wherein, the inflatable package cushion body 60D is made of the air cushion body 10, and the package body 50D is used for packaging the inflatable package cushion body 60D, the inflatable package cushion body 60D and the package body. The inner side of the 50D is fixedly coupled to ensure that the article to be transported is fixed to the inside of the package 50D together with the inflatable package cushion 60D during transportation without arbitrarily moving, thereby improving the transported article. Safety and aesthetics.

As shown in FIG. 21A to FIG. 25, the package body 50D is a rectangular parallelepiped paper package, and the ratio of length to width of the rectangular paper package is about 1:1:3, as shown in FIGS. 21A and 21B. FIG. 22 is a schematic perspective view showing the three-dimensional structure before and after the opening of the package 50D.

As shown in FIGS. 21A, 21B and 22, in the fifth embodiment of the present invention, the package body 50D is a paper sheet which is folded into the package body 50D, and the package body 50D is folded. The interior has an accommodating space 500D. The inflatable package cushioning body 60D is fixedly disposed in the accommodating space 500D to achieve a fixed connection with the package body 50D.

In detail, the package body 50D includes a first side 501D, a second side 502D, a third side 503D, a fourth side 504D, an upper bottom surface 506D and a lower bottom surface 507D. The side 501D, the second side 502D, the third side 503D, and the fourth side 504D form a side of the accommodating space 500D, and the upper bottom surface 506D and the lower bottom surface 507D are the accommodating space 500D. Upper and lower bottom surfaces. Wherein, the inflatable packaging cushion body 60D The direction of the arrangement coincides with the height direction of the package 50D, that is, the direction in which the inflatable package cushion 60D is disposed coincides with the standing direction of the article placed therein. And the direction of the gas storage unit 13 in the air cushion body 10 in the inflatable package cushion body 60D also coincides with the standing direction of the articles to be transported, in other words, because the articles to be transported are along The package body 50D is placed in the height direction, and the first side 501D, the second side 502D, the third side 503D, and the fourth side 504D of the package 50D are respectively along the package 50D. The height direction is surrounding, so that the gas storage unit 13 in the air cushion body 10 included in the inflatable package cushion body 60D and the first one of the package body 50D when the package body 50D is opened The annular direction formed by the side 501D, the second side 502D, the third side 503D, and the fourth side 504D is perpendicular.

As shown in FIG. 21A and FIG. 21B, it is worth mentioning that, in the fifth embodiment of the present invention, the package body 50D is disposed sideways, that is, the opening of the package body 50D is disposed in the package body 50D. The first side 501D, the second side 502D, the third side 503D, and the fourth side 504D forming the peripheral side of the package body 50D must be openable and closable. In other words, the first side 501D, the second side 502D, the third side 503D, and the fourth side 504D of the package body 50D are the side surfaces of the package body 50D formed by joining. Preferably, the package body 50D further includes a fifth side 505D, and a side surface of the package body 50D is formed by a coincidence connection of the fifth side 505D and the first side 501D. Further, in the fifth embodiment of the present invention, the fifth side 505D and the first side 501D are fixedly connected by magnetic means. Specifically, a first magnet 71 and a second magnet 72 are respectively disposed at the same position of the fifth side 505D and the first side 501D, and the fifth side 505D and the first When the side 501D is closed and overlapped, the first magnet 71 and the second magnet 72 are connected to each other because the fifth side 505D and the first side 501D are connected to each other, thereby realizing the package 50D. Close up. Similarly, since the magnetic attraction between the first magnet 71 and the second magnet 72 is limited, when it is necessary to open the package 50D, it is only necessary to apply a larger than the fifth side 505. When the force of the magnetic attraction between the first magnet 71 and the second magnet 72 is described, the package 50D can be opened.

Further, the first magnet 71 and the second magnet 72 may be located at any position of the first side 501D and the fifth side 505D, such as the fifth side 505D and the first The upper side, the middle side or the lower side of the side 501D, etc., as long as the first magnet 71 and the second magnet 72 are at the same position with each other such that when the fifth side 505D and the first side 501D are closed When superposed, the first magnet 71 and the second magnet 72 may overlap each other. In addition, the person skilled in the art can select the connection manner of the fifth side 505D and the first side 501D according to actual conditions, such as a detachable fixed connection manner, such as a snap connection or a Velcro. The technical problems that are the same as or similar to the present invention are solved as long as the technical solutions are the same as or similar to the present invention, and the same or similar technical effects as the present invention are achieved, and are all within the protection scope of the present invention. The specific embodiments of the invention are not limited thereto.

As shown in FIG. 22, since the inflatable package cushion 60D is fixedly coupled to the inner side of the package body 50D, the inflatable package cushion body is when the package container having air cushioning performance is in a non-use state. 60D is also in a non-inflated state, that is, the gas storage unit 13 in the inflatable package cushion 60D is not filled with gas, but only two layers of

air chamber films

11 and 12 overlapping each other, so the whole can be The air-filled packaging cushion body 60D can be flattened, has a very small volume, and does not occupy a space, so that the air-bubble-capable packaging container of the present invention is very convenient for storage and storage when not in use.

As shown in FIGS. 21A and 21B, when the packaging container having air cushioning properties according to the present invention is required to be used, The package body 50D is first folded into a predetermined contour and the accommodation space 500D is formed, and the inflatable package cushion body 60D is inflated. As shown in FIGS. 23 and 34, the inflatable package cushion 60D is inflated to form an air cushion body 10 including five portions, which are the first portion 101, the second portion 102, and the third portion, respectively. 103, a fourth portion 104 and a fifth portion 105, wherein the second portion 102, the third portion 103, and the fourth portion 104 are respectively fixed to an inner side of the package body 50D and form a for transporting the transported article An accommodating space 601D extending from a first end 1023 of the second portion 102, the fifth portion 105 extending from an end 1043 of the fourth portion 104, and the first portion 101 And the fifth portion 105 is in a free state, and can be folded with respect to the first portion 101 and the fourth portion 104 to seal the accommodation space 601D of the inflatable package cushion 60D, thereby further The articles to be transported provide cushioning force and increase safety performance.

In a fifth embodiment of the present invention, the second portion 102, the third portion 103, and the fourth portion 104 of the inflatable package cushion 60D are fixed to the package body 50D by adhesive bonding. In the accommodating space 500D formed, the adhesive may be disposed between the gas storage unit or the adjacent gas storage unit. A person skilled in the art may also fix the second portion 102, the third portion 103 and the fourth portion 104 of the inflatable package cushion 60D to the package body 50D according to actual conditions. In the accommodating space 500D, for example, a detachable fixed connection manner such as a snap connection or a velcro connection, if the same or similar technical solutions of the present invention are adopted, the same or similar technical problems as the present invention are solved, and The same or similar technical effects of the present invention are all within the scope of the present invention, and the specific embodiments of the present invention are not limited thereto.

As shown in FIGS. 24 and 26, as a further preferred embodiment of the fifth embodiment of the present invention, the air cushion body 10 forming the inflatable package cushion 60D further includes an extended side 100 extending from the extended side 100. A first end 1013 of the first portion 101 and the extended side 100 and the first portion 101 are in a non-vented state. In other words, the extended side 100 is a planar film formed by the

gas chamber films

11 and 12. The extended side 100 has a right side 1001 and a left side 1002, and the left side 1002 and the right side 1001 respectively extend to the left and right sides of the inflatable package cushion 60D. It should be noted that the first portion 101 has a right side 1011 and a left side 1012. The second portion 102 also has a right side 1021 and a left side 1012. The third part 103 is also Having a right side 1031 and a left side 1032, and the left side 1001 of the extended side 100 passes through the three-dimensional molding seam 40 and the left side 1011 and the second part 102 of the first portion 101 The left side 1021 and the left side 1031 of the third portion 103 are stitched, and the right side 1002 of the extended side 100 also passes through the three-dimensional plastic sealing seam 40 and the right side 1012 of the first portion 101. The right side 1022 of the second portion 102 and the right side 1032 of the third portion 103 are stitched such that the extended side 100 forms a top in the accommodation space 601D of the inflatable package cushion 60D. The chamber 6011D is accommodated. After the inflatable packaging cushion body 60D is inflated, the air storage unit 13 in the air cushion body 10 forming the inflatable packaging cushion body 60D will expand due to full air, and the gas storage unit 13 will correspondingly Compressing the extended edge 100 such that the top receiving cavity 6011D formed by the extended edge 100 is correspondingly reduced, thereby fixing a portion of the article to be transported by the top receiving cavity 6011D, thereby further enhancing the present invention. The safety of the packaging container with air cushioning properties during use and transportation.

Preferably, the left side 1032 and the right side 1031 of the third portion 103 are respectively sewn by the three-dimensional plastic sealing seam 40 to the left side 1002 and the right side 1001 of the extended side 100, depending on the length The length of the extended edge 100 is described. The object of the present invention can be achieved by ensuring that both ends of the opening of the top accommodating space 6011D are flush, and the person skilled in the art can also determine the left side 1032 and the right side of the third portion 103 according to customer needs or actual conditions. Side 1031 The length stitched by the three-dimensional plastic sealing seam 40 is the same or similar to the technical solution of the present invention, and the same or similar technical effects as the present invention are achieved, and the same or similar technical effects as the present invention are achieved. The specific embodiments of the present invention are not limited thereto.

It is further mentioned that, as a further preferred embodiment of the fifth embodiment of the present invention, the fourth portion 104 has a right side 1041 and a left side 1042, the fifth portion 105 having a right side 1051 and a left side edge 1032, and the left side edge 1042 of the fourth portion 104 is partially connected to the left side edge 1032 of the third portion 103 adjacent thereto by the three-dimensional plastic sealing slit 40 and the first portion The left side 1052 of the fifth portion 105, correspondingly, the right side 1041 of the fourth portion 104 is partially connected to the right side 1032 of the third portion 103 adjacent thereto by the three-dimensional plastic sealing seam 40, respectively. The right side 1051 of the fifth portion 105, so that the fourth portion 104 becomes the bottom of the accommodation space 601D, thereby further improving the stability of the accommodation space 601D, making it more suitable for the articles to be transported Placement. Similarly, the left side 1032 and the right side 1031 of the third portion 103 and the left side 1042 and the right side 1041 of the fourth portion 104 may be shaped by the three-dimensional plastic seal according to actual conditions. The slit 40 is sewn to the length of the left side edge 1042 and the right side edge 1041 of the fourth portion 104 as long as the accommodation space 601D can be stabilized. In other words, as long as the technical solution identical or similar to the present invention is adopted, the technical problem that is the same as or similar to the present invention is solved, and the technical effects identical or similar to those of the present invention are achieved, and are all within the scope of protection of the present invention. The specific embodiments of the present invention are not limited thereto.

Further, in the fifth embodiment of the present invention, the adhesive fixing of the inflatable package cushion body 60D and the package body 50D is by the air cushion body forming the inflatable package cushion body 60D. The outer surface of the back of the gas storage unit 13 of the second portion 102, the third portion 103, and the fourth portion 104 of 10 is coated with a glue such as bubble glue to achieve a fixed connection with the package 50D. As a variation of the fifth embodiment of the present invention, those skilled in the art can change the specific position of the adhesive packaging cushion 60D and the package 50D to be fixed, for example, by forming the inflatable package. The outer surface of the back portion of the partition portion 31 of the second portion 102, the third portion 103 and the fourth portion 104 of the air cushion body 10 of the buffer body 60D is coated with glue to achieve fixation with the package body 50D. Connection, etc. In addition, the size of the bonding area of the inflatable packaging cushion body 60D and the package body 50D may be determined by a person skilled in the art according to actual conditions or customer requirements, such as the second portion 102 and the third portion 103. And the entire back outer surface of the fourth portion 104 is coated with glue to achieve a fixed connection with the package 50D, or only the portions of the second portion 102, the third portion 103, and the fourth portion 104 are outside the back. The surface is coated with a glue to achieve a fixed connection with the package 50D. The technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the same or similar technical effects as the present invention are achieved, and the present invention is within the scope of the present invention. The specific implementation manner is not limited thereto.

As a modification of the fifth embodiment of the packaging container having air cushioning performance according to the present invention, those skilled in the art can also design the inflatable packaging cushion 60D formed by the air cushioning body 10 into other Type, such as directly designing the inflatable packaging cushion 60D as a bag with an opening, the transported article being placed into the inflatable packaging cushion 60D from the opening, or The inflatable package cushion 60D is designed as a closed bag with a zipper that can be placed into the inflatable package cushion 60D by opening the zipper, and the like. In other words, as long as the technical solutions identical or similar to those of the present invention are employed, the technical problems that are the same as or similar to the present invention are solved, and the same or similar technical effects as the present invention are achieved, which are all within the scope of protection of the present invention. The specific embodiments of the present invention are not limited thereto.

Specifically, in the fifth embodiment of the present invention, the packaging container having air cushioning performance is embodied as a package for holding a bottle such as a wine bottle, such as a liquid such as a liquor liquid or a beverage. . The package body 50D is designed to be side-opened to facilitate the opening of the package body 50D to display the overall appearance of the liquid bottle body, and to facilitate the access of the bottle body. Certainly, the specific application of the fifth embodiment of the packaging container with air cushioning performance of the present invention can be determined by a person skilled in the art according to the actual situation, and the specific embodiment of the present invention is not limited thereto.

Specifically, in the fifth embodiment of the packaging container having air cushioning performance according to the present invention, the package body 50D is embodied as a paper packaging box having a folding length of 145 mm, a width of 120 mm, and a height of 400 mm. It can carry items within 1.5 kilograms, that is, the safe weight of the articles to be transported does not exceed 1.5 kilograms. As an improvement of the present invention, a person skilled in the art can determine the specific size of the package body 50D according to the specific size of the article to be transported. If the volume and weight of the article to be transported are small, the package body 50D The size of the package can also be scaled up or scaled down. Similarly, if the volume and weight of the article to be transported are large, the size of the package 50D is also scaled up or scaled to Adapt to the needs of the item being transported. In other words, the technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the technical effects identical or similar to those of the present invention are achieved, and are within the protection scope of the present invention. The specific embodiments of the present invention are not limited thereto.

In addition, the mermaid of the present invention can determine the specific connection manner of the fifth embodiment of the packaging container with air cushioning performance according to the present invention and the specific manufacturing method of the package body 50D according to the actual situation, as long as the present invention is adopted. The same or similar technical solutions of the fifth embodiment solve the technical problems that are the same or similar to the present invention, and achieve the same or similar technical effects as the present invention, which are all within the protection scope of the present invention, and the specifics of the present invention The implementation is not limited to this.

Next, a method of manufacturing and using the fifth embodiment of the packaging container having air cushioning property according to the present invention will be further briefly described with reference to Figs. 21A to 25 .

The manufacturing method of the fifth embodiment of the packaging container having air cushioning performance is:

Setting a package body 50D having a length, width and height ratio of about 1:1:4;

An inflatable package cushion 60D is provided, the inflatable package cushion 60D can form a receiving space 601D;

The inflatable package cushion 60D is fixed to the inside of the package 50D.

Among them, those skilled in the art can interchange the manufacturing steps of the package 50D and the manufacturing steps of the inflatable package cushion 60D according to actual conditions. The technical problem of the same or similar to the present invention is solved as long as the technical solution is the same as or similar to the present invention, and the same or similar technical effects as the present invention are achieved, and are all within the scope of the present invention. The specific embodiments are not limited thereto.

The fifth embodiment of the packaging container having air cushioning performance is used to inflate the inflatable packaging cushion 60D, and the inflated packaging cushion 60D can expand the package 50D. The accommodating space 500D; the inflatable packaging cushion body 60D is bent to form a receiving space 601D;

Putting a transported item into the accommodating space 601D of the inflatable package cushion 60D;

The side of the package 50D is closed and sealed.

As shown in FIG. 27 to FIG. 30, in a sixth embodiment of the packaging container having air cushioning performance according to the present invention, the sixth embodiment of the present invention is substantially similar in structure, shape, and the like to the fifth embodiment of the present invention. The difference lies in the following points.

First, as shown in FIG. 27, in the sixth embodiment of the present invention, the capacity of the inflatable package cushion 60E Two or more of the liquid bottles can be placed in the nano space 601E. In other words, the volume of the air cushion body 10 forming the inflatable package cushion 60E becomes at least twice as large, and accordingly, the volume of the package 50E is at least doubled. In this embodiment, the air cushion body 10 forming the inflatable package cushion 60E is doubled in the lateral dimension (i.e., the length direction), and the package 50E is correspondingly in the lateral dimension (longitudinal direction). Increased twice, that is, the inflatable package cushion 60E includes a first inflatable package cushion 60E' and a second inflatable package cushion 60E", the package 50E includes a first package 50E 'and a second package 50E'.

Specifically, as shown in FIG. 28, two or more of the liquid bottle bodies may be simultaneously placed in the accommodation space 601E of the air package bag 60E as long as the package body 50E and the air cushion body 10 are The lateral dimension (length direction) may be simply doubled or more, that is, the first inflatable package cushion body 60E' and the second inflatable package cushion body 60E" may be integrated into one body; Then, the accommodating space 601E includes two portions, a first accommodating space 601E' and a second accommodating space 601E", and the first inflatable packaging buffer 60E' forms the first accommodating space 601E'. The second inflatable package cushion body 60E" forms the second accommodation space 601E", and the first accommodation space 601E' and a second accommodation space 601E" are separated by providing a heat fusion line. The first accommodation space 601E' and the second accommodation space 601E" may be completely separated or partially separated. The first package 50E' and the second package 50E" are connected as a single unit.

Secondly, since the air cushion body 10 and the package body 50E described in the sixth embodiment of the present invention are respectively increased in the lateral dimension (length direction) by two times, the second inflatable package cushion body 60E" is required. The second package 50E" is fixed to the second package 50E", and in this embodiment, the second inflatable package cushion 60E" and the second package 50E" are fixed by adhesion. Further, the fixing of the second inflatable package cushion body 60E" and the second package body 50E" is applied from top to bottom in the middle of the back outer surface of the second air bag 60E" The glue is thereby fixed to the second package 50E".

Specifically, in the sixth embodiment of the packaging container having air cushioning performance according to the present invention, the package body 50E is embodied as a paper packaging box having a length of 270 mm, a width of 120 mm, and a height of 400 mm. It can carry items within 3 kilograms, that is, the safe weight of the articles to be transported does not exceed 3 kilograms. As an improvement of the present invention, a person skilled in the art can determine the specific size of the package 50E according to the specific size of the article to be transported, and if the volume and weight of the article to be transported are small, the package 50E The size of the package can also be scaled or otherwise reduced. Similarly, if the volume and weight of the article to be transported are large, the size of the package 50E is also scaled up or scaled to Adapt to the needs of the item being transported. In other words, the technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the technical effects identical or similar to those of the present invention are achieved, and are within the protection scope of the present invention. The specific embodiments of the present invention are not limited thereto.

In addition, the mermaid of the art can determine the specific connection manner of the fifth embodiment of the packaging container with air cushioning performance according to the present invention and the specific manufacturing method of the package 50E, the package 50E and The connection between the inflatable package cushions 60E and the connection portions and the like, as long as the same or similar technical solutions as the fifth embodiment of the present invention are adopted, the same or similar technical problems as the present invention are solved and achieved. The technical effects of the same or similar to the present invention are all within the scope of the present invention, and the specific embodiments of the present invention are not limited thereto.

As shown in FIG. 31, in a seventh embodiment of the packaging container having air cushioning performance according to the present invention, the The air cushioning performance packaging container includes a package body 50F and an inflatable package cushioning body 60F, and the inflatable package cushioning body 60F is fixedly disposed inside the package body 50F. Wherein, the inflatable package cushion body 60F is made of the air cushion body 10, and the package body 50F is used for packaging the inflatable package cushion body 60F, the inflatable package cushion body 60F and the package body. The inner side of the 50F is fixedly coupled to ensure that the article to be transported is fixed to the inside of the package body 50F together with the inflatable package cushion body 60F during transportation without arbitrarily moving, thereby improving the transported article. Safety and aesthetics.

As shown in FIG. 31, the package body 50F is a rectangular parallelepiped paper packaging box, and the ratio of the length to the width of the rectangular rectangular paper packaging box is about 1:1:3, which is folded after the package 50F is folded. Schematic diagram of three-dimensional structure. When the packaging container having the air cushioning property according to the present invention needs to be used, the package body 50F is first folded into a predetermined contour and the accommodating space 500F is formed, and the inflatable packaging cushion body 60F is further used. It is inflated and forms an accommodation space 601F to provide space for storage of the articles to be transported.

In the seventh embodiment of the present invention, the package body 50F is a paper plate that is folded into the package body 50F, and the package body 50F has an accommodation space 500F inside the fold. The air-filled packaging cushion body 60F is fixedly disposed in the accommodating space 500F to achieve a fixed connection with the package body 50F.

In detail, the package body 50F includes a first side 501F, a second side 502F, a third side 503F and a fourth side 504F. The air in the inflatable package cushion 60F The gas storage unit 13 in the buffer body 10 is disposed laterally so as to coincide with the opening direction of the package body 50F. In other words, the gas storage unit 13 in the air cushion body 10 included in the inflatable package cushion body 60F and the first side of the package body 50F when the package body 50F is opened The annular direction formed by the 501F, the second side 502F, the third side 503F, and the fourth side 504F is uniform.

It should be noted that the first side 501F, the second side 502F, the third side 503F, and the fourth side 504F of the package 50F may be integrally formed into a ring shape, and the The first side 501F, the second side 502F, the third side 503F, and the fourth side 504F of the package 50F may also be formed by stitching a sheet of paper to form the annular shape. The first side 501F, the second side 502F, the third side 503F, and the fourth side 504F of the package 50F are folded. If the paper package 50F is formed by stitching a paper plate, the side wall of the package 50F may have a seam where the ends of the paper plate are stitched (with The sutures of an embodiment are identical in structure, the same as below, such as by suture stitching or other means of suturing. If the first side 501F, the second side 502F, the third side 503F, and the fourth side 504F of the package 50F are the ring shape formed by sewing and folding a piece of paper. Preferably, then, the stitches at both ends of the paper sheet are left with overlapping edges (consistent with the structure of the coincident side 52 in the first embodiment, the same below) to ensure the firmness of the package 50F.

Further, the stitching of the package body 50F may be at any position of the package body 50F. Preferably, the stitching portion of the package body 50F is located at the intersection of the first side 501F, the second side 502F, the third side 503F, and the fourth side 504F of the package body 50F, that is, The stitching of the package body 50F is located at the edge of the package body 50F, thereby making the appearance of the package body 50F more beautiful. More preferably, the overlapping side formed by the stitching is located inside the package body 50F, thereby further improving the aesthetic appearance of the package body 50F.

As shown in FIG. 31, since the inflatable package cushion 60F is fixedly coupled to the inner side of the package body 50F, the inflatable package cushion body is when the package container having air cushioning performance is in a non-use state. 60F is also In the non-inflated state, that is, the gas storage unit 13 in the inflatable package cushion 60F is not filled with gas, but only two layers of

air chamber films

11 and 12 overlapping each other, so the entire inflatable package The buffer body 60F can be flattened, has a very small volume, and does not occupy a space, so that the packaging container with air cushioning property according to the present invention is very convenient for storage and storage when not in use.

As shown in FIG. 31, it is noted that in the seventh embodiment of the present invention, the first side 501F, the second side 502F, the third side 503F, and the fourth side of the package 50F are The side 504F is integrally formed into a ring shape, and the inflatable package cushion 60F is fixed to the inner side of the package body 50F. Specifically, in the seventh embodiment of the present invention, the outer middle portion of the air package bag 60F and the inner side of the package body 50F are positioned to each other. In other words, the positioning point of the air-packing bag 60F and the package body 50F is located between the outer side of the air-packing bag 60F and the inner side of the package body 50F, and is fixed by bonding.

As a preferred embodiment of the seventh embodiment of the packaging container having air cushioning properties according to the present invention, the inflatable packaging cushion 60F can also be fixedly connected to the package 50F in any orientation, for example, in the The bottom of the inflatable package cushion 60F is fixed to the bottom of the package 50F, or is fixed on either side of the air package 60F and the side of the package 50F in contact therewith, and may even be All the side faces of the air-packaging bag 60F are fixed to all the inner side faces of the package body 50F, thereby achieving the effect of fixing the inflatable package cushioning body 60F to the inner side of the package body 50F. Further, in a modified embodiment of the seventh embodiment of the present invention, the inflatable package cushion 60F formed by the air cushion body 10 includes a margin 62F, and the margin 62F is the air cushion body. 10 is formed by the three-dimensional plastic sealing slit 40 when the inflatable packaging cushion 60F is formed. In other words, when the air cushion body 10 is formed into a three-dimensional shape having the opening 61F through the three-dimensional plastic sealing slit 40, the air cushioning body 10 is mutually lapped and molded by the three-dimensional plastic sealing seam 40. The place will form the margin 62F. Furthermore, the margin 62F is a side formed when the air cushion body 10 is in a planar state through the three-dimensional plastic sealing slit 40. Since the margin 62F is outside the inflatable package cushion 60F formed by the air cushion body 10, the margin 62F generally does not have air cushioning performance, that is, the margin 62F is also The

plenum films

11 and 12 are composed, but the rim 62F cannot be inflated because of the three-dimensional squeezing seam 40, so the rim 62F is a planar film.

In the modified embodiment of the seventh embodiment of the present invention, the margin 62F of the inflatable package cushion 60F formed by the air cushion body 10 is disposed on the overlapping side and the first side. Between the sides 501F and fixed. A person skilled in the art can determine the manner of fixing the margin 62F of the inflatable package cushion body 60F and the package body 50F according to needs or actual conditions, which may be described by glue or the like. The remaining edge 62F is adhered between the overlapped edge and the gap between the first side 501F, and the remaining edge 62F of the air package bag 60F may be directly fixed by the pushpin. The overlapping edge is between the first side 501F. The technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the same or similar technical effects as the present invention are achieved, and the present invention is within the scope of the present invention. The specific implementation manner is not limited thereto.

The inflatable package cushion 60F can be fixedly attached to the inner side of the package body 50F in various ways, such as shown in FIG. 10B, and is applied to the bottom outer surface of the inflatable package cushion body 60F by glue such as glue. Or the bottom inner surface of the package body 50F, thereby fixing the inflatable package cushion body 60F to the inner side of the package body 50F, or fixing the bottom edge of the inflatable package cushion body 60F to the bottom of the package body 50F. Inside the bottom of the package 50F The side, or the detachable fixed connection manner, for example, by fixing the inflatable package cushion body 60F and the package body 50F by providing a buckle, a pin or the like, as long as the same or similar technique as the present invention is employed. The technical problems that are the same as or similar to the present invention are solved, and the technical effects that are the same as or similar to the present invention are all within the scope of the present invention, and the specific embodiments of the present invention are not limited thereto.

Specifically, in the seventh embodiment of the packaging container having air cushioning performance according to the present invention, the package body 50F is embodied as a paper packaging box having a length of 110 mm, a width of 140 mm, and a height of 400 mm. It can carry items within 1.5 kilograms, that is, the safe weight of the articles to be transported does not exceed 1.5 kilograms. As an improvement of the present invention, a person skilled in the art can determine the specific size of the package body 50F according to the specific size of the article to be transported. If the volume and weight of the article to be transported are small, the package body 50F The size of the package can also be scaled up or scaled down. Similarly, if the volume and weight of the article being transported are large, the size of the package 50F is also scaled up or scaled to Adapt to the needs of the item being transported. In other words, the technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the technical effects identical or similar to those of the present invention are achieved, and are within the protection scope of the present invention. The specific embodiments of the present invention are not limited thereto.

In addition, the mermaid of the present invention can determine the specific connection manner of the seventh embodiment of the packaging container having air cushioning performance according to the present invention, and the specific manufacturing method of the package body 50F, the package body 50F and The connection method, the connection position, and the like of the inflatable package cushioning body 60F are the same or similar technical solutions as the seventh embodiment of the present invention, and the same or similar technical problems as the present invention are solved, and the present invention is achieved. The same or similar technical effects of the invention are all within the scope of the invention, and the specific embodiments of the invention are not limited thereto.

Next, a method of manufacturing and using the seventh embodiment of the packaging container having air cushioning property according to the present invention will be further briefly described with reference to FIG.

The manufacturing method of the seventh embodiment of the package having air cushioning performance is:

Setting a package body 50F having a length, width and height ratio of about 1:1:3;

An inflatable package cushion 60F is disposed, and the bottom of the inflatable package cushion 60F is pre-sealed;

The inflatable package cushion 60F is fixed to the inside of the package 50F.

Among them, those skilled in the art can interchange the manufacturing steps of the package 50F and the manufacturing steps of the inflatable package cushion 60F according to actual conditions. The technical problem of the same or similar to the present invention is solved as long as the technical solution is the same as or similar to the present invention, and the same or similar technical effects as the present invention are achieved, and are all within the scope of the present invention. The specific embodiments are not limited thereto.

The seventh embodiment of the package having air cushioning performance is used to inflate the inflatable package cushion 60F, and the inflated package cushion 60F can expand the package 50F. And forming a receiving space 601F;

Putting a transported item into the accommodating space 601F of the inflatable package cushion 60F;

The package 50F is sealed.

In summary, the packaging container with air cushioning performance according to the present invention can not only be suitable for packaging bodies of different specifications, but also can determine the specific shape and structure of the inflatable packaging bag according to the nature of the articles to be transported. In addition, the packaging container with air cushioning performance according to the present invention not only facilitates storage and transportation, but also saves the opening step in use, thereby saving opening time and improving user work efficiency.

Further, as a modified embodiment of the above first to seventh embodiments of the present invention, as shown in FIG. 32, the packaging container having air cushioning performance includes a package 50G and an inflatable package cushion 60G. The inflatable package cushion 60G is fixedly disposed outside the package 50G and the bottom of the inflatable package cushion 60G is pre-sealed, that is, a package having a top opening and a bottom end closed, of course, in some embodiments. In the middle, it may be just a ring shape and open at both ends. The inflatable package cushion body 60G is made of the air cushion body 10, and the package body 50G is used for packaging a transported object, and the inflatable package cushion body 60G is fixedly connected with the package body 50G, It is ensured that the articles to be transported are fixed together with the package body 50G inside the inflatable package cushion 60G during transportation without arbitrarily moving, thereby improving the safety and aesthetics of the articles to be transported. In other words, the eighth embodiment is different from the above-described first to seventh embodiments in that the inflatable package is fixed to the outside of the package, and further to the articles to be transported inside the package. A cushioning force is provided to increase the safety of the item being transported.

Specifically, in the modified embodiment, the shape, size, and deformation manner of the package body 50G are the same as or similar to those of the above-described first to seventh embodiments, and the inflatable package cushion body 60G is The shape, the size, and the manner of its deformation are the same as or similar to those of the above-described first to seventh embodiments, and the connection relationship between the package 50G and the inflatable package cushion 60G is also the same as described above. The connection relationship between the package in the first to seventh embodiments and the inflatable bag is the same or similar. In other words, on the basis of the package body and the inflatable bag disclosed in the above first to seventh embodiments, it is within the protection scope of the present invention as long as the inflatable bag is placed outside the package. The specific embodiments of the present invention are not limited thereto.

The package body 50G and the inflatable package cushion body 60G are in a folded state when not in use, that is, the package body 50G is also a foldable container, and when the inflatable package cushion body 60G is inflated, it is automatically opened. The package 50G, such that the item to be packaged can be placed in the package 50G, and the package 50G and the inflatable package cushion 60G provide multiple layers of cushioning protection. The inflatable package cushion 60G may be fixed to the outer surface of the package 50G, such as a side surface or a rib, through a partition between the gas storage unit or the adjacent gas storage unit, or the outer edge of the package 50G.

As shown in Fig. 33, there is shown another modified embodiment of the first to seventh embodiments of the present invention. As shown, the packaging container having air cushioning performance includes a first package body 50H, a second package body 50H', and an inflatable package cushioning body 60H. The first package body 50H is disposed on the first package body 50H. The inside of the two package 50H' is disposed between the first package body 50H and the second package body 50H', wherein the first package body 50H is used for packaging For transporting the object, the inflatable packaging cushion 60H is made for the air cushioning body 10 to provide a cushioning force for the transported article during transportation. In other words, in the other modified embodiment, the first to seventh embodiments are different in that the inflatable package cushion 60H is disposed in the first package 50H and the first Between the two packages 50H'.

Specifically, in the modified embodiment, the shape, size, and deformation manner of the first package body 50H and the second package body 50H' are the same as those of the first to seventh embodiments described above or Similarly, as long as the first package 50H can be placed inside the second package 50H', the shape, size and deformation manner of the inflatable package cushion 60H are the same as the first to The inflatable package in the seventh embodiment is the same or similar, and the connection relationship between the first package 50H, the second package 50H' and the inflatable package cushion 60H is also the first The connection relationship to the package of the seventh embodiment to the inflatable bag is the same or similar. In other words, on On the basis of the package body and the inflatable packaging bag disclosed in the first to seventh embodiments, as long as two packages are provided, and the inflatable package bag is between the two packages, the present invention is The specific embodiments of the present invention are not limited thereto.

It can be understood that the first package body 50H is disposed inside the second package body 50H', and can be fixedly connected to the second package body 50H' without being used with the first package body. 50H phase connection; or the inflatable package cushion body 60H is fixedly connected to the first package body 50H without being fixedly connected to the second package body 50H'; or the inflatable package cushion body 60H and the Both the first package 50H and the second package 50H' are fixedly connected. Thus, the inflatable package cushion 60H serves as an interlayer, and when it is inflated, the

package

50H or 50H' to which it is attached can be opened to facilitate use.

In addition, the first package body 50H not connected to the inflatable package cushion body 60H may be placed in the inflatable package cushion body 60H before inflation, or may be placed after inflation. The inflatable package cushion 60H after inflation. The second package 50H' not connected to the inflatable package cushion 60H may be placed outside the inflatable package cushion 60H before inflation, or may be inflated before inflation. The inflated packaging cushion 60H after inflation is placed in the second package 50H'. It should be emphasized that in all the above embodiments of the present invention, the specific form of the package is not limited to the regular hexahedron shape of the box body, the box body, etc., but also includes any irregular shape capable of forming a receiving space. Moreover, the package may be made of not only paper but also plastic or composite material. The technical problem that is the same as or similar to the present invention is solved by the same or similar technical solutions as the present invention, and the technical effects that are the same as or similar to the present invention are achieved, and are all within the scope of the present invention. The specific implementation manner is not limited thereto.

An embodiment of an inflator according to the present invention is shown in Figs. 36 to 44 for continuously inflating an inflation cushioning body 10c to form a three-dimensional inflatable cushioning body. The inflatable device includes a bracket 30c, a head 40c, and a platform 50c. The head 40c is disposed on the bracket 30c, and the bracket 30c is disposed on the platform 50c. In this embodiment of the present invention, the handpiece 40c is slidably disposed on the bracket 30c, which is freely slid by gravity, and is always pressed against the air cushion body 10c. The airing device includes a positioning structure to It is ensured that the inflation cushion body 10c during operation does not undergo relative displacement. It will be understood by those skilled in the art that the size and size of the inflatable cushion body 10c is adapted to the weight of the handpiece 40c. The inflation device is capable of automatically and continuously inflating the inflation cushion body 10c of various specifications and sizes, and the present invention is not limited thereto.

In this embodiment of the invention, the inflator of the present invention is capable of inflating one or more of the inflated cushioning bodies 10c arranged in a superposed manner, i.e., inflating the inflated cushioning body 10c. operating. Each of the aerated buffer bodies 10c includes at least two layers of

gas chamber films

11c and 12c subjected to a sealing process such as a heat sealing process or a bonding process, and the present invention is preferably one or more connected gas storage units 13c formed by a heat sealing process. . As shown in Figs. 37A and 37B, a gas storage chamber 14c capable of storing air is formed in each of the gas storage units 13c. In the single charging operation of the inflation cushioning device 10c, the gas storage unit 13c of one of the inflation cushioning bodies 10c may be inflated.

More specifically, the two-

layer plenum films

11c and 12c are partitioned into a plurality of the gas storage units 13c by a plurality of rows of slits 101c, that is, the slits 101c of the respective columns may be formed by a heat sealing process, and the heat seal is connected to the two layers. The

gas chamber films

11c and 12c are formed such that a column of the slits 101c is formed between two adjacent gas storage units 13c. The partitioning slit 101c may be a continuous heat sealing line such that a plurality of the gas storage units 13c are independent of each other. The partitioning slit 101c may also be an intermittent heat sealing line so that the plurality of the gas storage units 13c communicate with each other. The gas storage unit 13c may be in various shapes such as a strip shape, a circular shape, The inflatable cushion body 10c of the present invention may include a plurality of inflatable columns arranged side by side, such as a polygon or other irregular shape, etc., but the present invention is not limited in this respect.

In this embodiment, the inflation cushioning body 10c further includes a gas valve which is a valve structure which can realize one-way backstopting. In this embodiment of the invention, it is composed of at least two layers of the valve film 21c. And an inflation valve 20c formed by 22c, the

valve films

21c and 22c of the inflation valve 20c being disposed superposed on each other with the

gas chamber films

11c and 12c, and formed between the

valve films

21c and 22c for An intake passage 23c that inflates the air reservoir 14c. When the air in the air reservoir 14c is inflated through the intake passage 23c and the air pressure in the air reservoir 14c reaches a predetermined requirement, air pressure in the air reservoir 14c acts on the

valve films

21c and 22c Upper, so that the

valve films

21c and 22c are attached to one of the plenum membranes, thereby closing the intake passage 23c, so that the inflation valve 20c functions as a one-way valve. When at least one of the intake passages 23c is formed in each of the gas storage units 13c, and each of the gas storage units 13c is independent of each other, when one of the gas storage units 13c is damaged and leaks, other places are The gas storage unit 13c is not affected and can also have an air cushioning effect.

The inflation cushioning body 10c further includes an inflation unit 15c coupled to each of the gas storage units 13c, preferably integrally extending to each of the gas storage units 13c. More specifically, in this embodiment, the

plenum films

11c and 12c form the plenum membrane

main body portions

111c and 121c, respectively, and the inflation end portions 151c integrally extending to the plenum membrane

main body portions

111c and 121c, respectively. 152c, the plenum membrane

main portions

111c and 121c are used to form the gas storage unit 13c by a heat sealing process, and the portions of the

plenum films

11c and 12c adjacent to the inflating side respectively form the portion of the inflating unit 15c. The inflation ends 151c and 152c are described. The inflatable ends 151c and 152c overlap each other and are interconnected at their

end edges

1511c and 1521c by an edge heat seal seam 102c, that is, the edge heat seal seam 102c is formed by a heat sealing process that sealingly heat seals the joint The

edges

1511c and 1521c of the inflatable ends 151c and 152c.

As shown in Fig. 37B, at the positions where the

plenum membrane portions

111c and 121c of the

plenum films

11c and 12c are respectively connected to the

inflation end portions

151c and 152c, the gas is sealed by the inflation passage heat seal 103c. The

chamber membranes

11c and 12c are interconnected with the

valve membranes

21c and 22c, respectively, as the inflation passage heat seal slits 103c are formed by a four-layer membrane through a heat sealing process, which is hermetically sealed to the gas chamber membrane 11c and The valve film 21c, and sealingly heat-sealing the gas chamber film 12c and the valve film 22c, but the

valve films

21c and 22c are not hermetically sealed by heat sealing, so that the

valve films

21c and 22c are An intake passage 23c that can inflate the gas storage unit 13c is formed.

It is worth mentioning that when the heat sealing process forms the inflation channel heat seal slit 103c, a heat resistant barrier may be placed between the

valve films

21c and 22c, so that the

valve films

21c and 22c are not heat sealed. Together. In this embodiment, a plurality of heat-resistant layers 24c, such as high-temperature resistant inks and the like, may be disposed between the

valve films

21c and 22c, which are spaced apart from each other corresponding to the intake passage 23c, and are attached to the The

valve membranes

21c and 22c are one of the inner surfaces of the valve film, so that the heat-resistant layer 24c can prevent the

valve films

21c and 22c from being heat-sealed by the inflation passage heat seal 103c in the heat sealing process. While connected together, the intake passage 23c which can be formed therebetween is communicated with the inflation passage 153c in the inflation unit 15c.

More specifically, the inflation unit 15c of the inflation cushion body 10c forms the inflation passage 153c between the edge heat seal slit 102c and the inflation passage heat seal slit 103c. As shown in Fig. 37A, in this example, for convenience of description, the gas storage units 13c are arranged in the longitudinal direction, and the inflation passages 153c are arranged in the lateral direction, that is, the longitudinally arranged gas storage units before being inflated. 13c may be communicated to the same laterally aligned inflation passage 153c through the corresponding intake passage 13c. It can also be said that the inflation passage 153c extends in the width direction of the inflation cushion body 10c. And connected to the respective gas storage units 13c arranged along the length direction thereof.

In particular, in the prior art, the inflation passage 153c has at least one end opening due to heat sealing of the edge heat seal line 102c and the inflation passage heat seal line 103c, which is formed on two layers. Between the membranes, however, the inflation is effected by the end openings between such membranes. However, this approach is not conducive to the automated continuous inflation scheme of the inflatable cushioning body shown in the present invention. Therefore, in this embodiment of the invention, both ends of the inflation passage 153c of the inflation cushion body are each closed by an inflation passage end seal 1030c. That is, the

inflation end portions

151c and 152c are overlapped with each other and the two side openings left after heat sealing by the edge heat seal slit 102c and the inflation passage heat seal line 103c are the end of the inflation passage end. After the seal 1030c is closed, the inflation passage 15c which is externally closed but communicates with each of the intake passages 23c is formed. The inflation channel end seal 1030c may be formed by a sealing process such as a heat sealing or bonding process that seals both ends of the inflation channel 153c.

It is worth mentioning that the partition slit 101c at both ends of the air cushion body 10c forms the outermost boundary slit of the air cushion body, and the air passage end seal 1030c may be the outermost partition slit 101c. Formed integrally, that is, formed in the same heat sealing process, it is also possible that the gas-filled channel end seals 1030c are separate and formed at both ends of the gas-filling unit 15c by an additional heat sealing process.

In order to realize the inflation operation of the inflation cushion body by the inflation device, the air source is facilitated to enter the inflation passage, and the inflation end portion 151c has an air inlet 150c so that the air can be inflated through the air inlet 150c. The cushion body 10c is inflated. That is, in the production process of the inflation cushion body 10c, the inflation end portion 151c is perforated by the punching device to form the air inlet 150c, and then the inflation end portion 151c is stacked with other films. Combine and seal.

In the present invention, a certain film forming the inflating unit 15c is perforated. For example, in this embodiment, the inflating unit 15c has an air inlet 150c which is embodied as an upper film port. Thus, the gas is adapted to enter the inflation passage 153c from the intake port 150c in a direction perpendicular to the plane of the inflation passage 153c, and then enter each of the respective intake passages 13c through the inflation valve 20c. The air reservoir 14c is described to complete the inflation operation.

That is, in the present invention, the inflator unit 15c is not similar to the intake air through the end portion in the prior art, but the upper upper surface. The air intake holes in the prior art are disposed between the two layers of film, and the air inlet 150c of the present invention is disposed on one layer of the gas chamber film.

It can be understood that, in this example, the inflator unit 15c is formed by the

gas chamber membranes

11c and 12c, and in other possible embodiments, it may also be the

valve membranes

21c and 22c of the inflation valve 20c. Formed, or formed by a layer of plenum film and a layer of valve film, the invention is not limited in this regard.

Further, the

plenum films

11c and 12c of the gas cushion body 10c and the

valve films

21c and 22c of the gas filling valve 20c may be made of various suitable film materials, such as polyethylene film, polypropylene, respectively. The present invention is not limited in this respect as a film, a polyvinyl chloride film, a polyester film, a polystyrene film or a composite film, and the like, as long as it is a suitable flexible film. It is worth mentioning that, in order to increase the one-way sealing effect, the

valve films

21c and 22c of the inflation valve 20c may also be self-adhesive films modified by adding chemical components to the above-mentioned film.

In the present invention, the gas cushioning body 10c forms a plurality of the gas storage chambers 14c capable of storing gas through a multilayer film, wherein at least two film layers are used to form the one-way gas filling valve 20c. When the intake port 150c is intakeed, gas enters the inflation passage 153c, and then the one-way inflation valve 20c formed by the two layers of film is inflated to each of the gas storage chambers 14c, and after the inflation is completed, the formation is completed. The film of the check valve 20c is automatically fitted together due to the pressure in the gas storage chamber to prevent back bleed of the air.

It should be noted that the inflatable cushion body 10c of the present invention may form a cushion after being inflated, which may be placed in other inflatable boxes to serve as a cushioning material, or may form a plurality of inflatable side walls after being inflated. And having an internal receiving space to form an inflatable packaging bag, the articles to be packaged can be stored in the inner receiving space, such that the inflatable packaging bag provides cushioning protection to the article through a plurality of the inflatable side walls.

Specifically, in this embodiment of the invention, the platform 50c is implemented to include an aerated cushion loading platform 50c. The platform 50c is capable of placing one or more of the inflatable cushions 10c of the opposite stack. The bracket 30c includes a vertical strut 31c and a lateral pedestal 32c coupled to the vertical strut 31c as an operating platform. The platform 50c is disposed on the lateral pedestal 32c. The handpiece 40c is disposed on the vertical strut 31c. The bracket 30c further includes a slide rail 34c disposed on the vertical strut 31c. The head 40c includes a slider 41c having a sliding slot that can slide along the sliding rail 34c on the vertical strut 31c, so that the head 40c can have upper and lower Slide displacement function.

It can be understood that the slide rail 34c can also be disposed on the handpiece 40c, and correspondingly, the bracket 30c has a slider with a sliding groove matched with the slide rail 34c. The platform 50c may be provided separately or as a working table, and the bracket 30c assembled with the head 40c is mounted on an environmental surface such that the environmental surface is provided on the air cushion body 10c. Material platform.

Further, the handpiece 40c further has an air source inlet and an air inlet 430c as a gas source outlet and inflating the air cushion body 10c. The air source inlet is connected to an air intake pipe 60c for providing an external air supply device for supplying a gas source, and the air source enters the handpiece 40c from the air intake pipe 60c through the air source inlet, and from the air intake The port 430c inflates the inflation cushion body 10c.

During the inflation operation of the inflatable device, in order to avoid the relative displacement of the inflatable cushion body 10c, which affects the continuity of the work and the yield of the finished product, the handpiece 40c further includes a positioning device, The platform 50c is also provided with a limit structure, such as one or more limit devices 55c. The air cushion body 10c of the same size is placed on the platform 50c, and each of the air cushion bodies 10c is placed in a relatively overlapping state by the stopper device 55c provided on the platform 50c. That is, the outer side of the outermost partition slit 101c of the air cushion body 10c has a notch 107c that matches the side shape of the stopper 55c. The number of the limiting devices 55c may be one or more, and correspondingly, the notches 107c may also be one or more. It can be understood that it may also be a positioning hole, and the limiting device 55c is sleeved on the positioning hole. In this embodiment of the present invention, as shown in FIG. 41, each of the limiting devices 55c includes a limiting connecting portion 552c and a limiting cap 551c extending from the limiting connecting portion 552c. The limiting connecting portion 552c is connected to the bracket 32c. In other embodiments, the limiting connecting portion 552c may also be disposed at a side of the platform 50c. The length of the limit connecting portion 552c can be adjusted according to the thickness of the inflatable cushioning body. The limiting cap 551c extends from the limiting connecting portion 552c and protrudes outward, and is larger in size than the notch 107c, so that when the inflation cushioning body 10c is inflated The position cap 551c is further restrained from above the platform 50c to avoid air source loss caused by the displacement of the inflation nozzle 43c and the air inlet 150c caused by the displacement of the inflation cushion body during inflation. Case.

Of course, those skilled in the art can understand that in other embodiments, the limiting device 55c can also be implemented as a limiting device of a limiting rod, a limiting plate and the like. The invention is not limited by this. It is worth mentioning that the platform 50c can also have a number of grooves 107c matching the limiting device 55c, so that the position of the inflatable cushion body in the platform 50c can be better adjusted. Further, it is more advantageous to implement the limit function of the limiting device 55c. This hair In this embodiment, the engagement of the notch 107c and the limiting device 55c serves as a limiting function, and it is also convenient to horizontally pull out the inflated cushioning body 10c.

The bracket 30c further includes a locking device 35c coupled to the vertical strut 31c to limit the head 40c to the vertical strut 31c. In this embodiment of the invention, the locking device 35c includes a fixing portion 351c and a locking portion 352c fixedly disposed on the vertical strut 31c, the fixing portion 351c and the locking The portion 352c is coupled by a bolt 353c, and the locking portion 352c is capable of pivotal movement with the bolt 353c as a central axis. That is, when the locking portion 352c is pivoted to the lower side of the handpiece 40c, the bottom of the handpiece 40c can be blocked by the top of the locking portion 352c, stopping relative displacement downward, thereby The inoperative state of the inflator provides an operational space for the inflator 10c that is mounted in a crucible.

Further, the positioning device of the handpiece 40c is implemented as a positioning tool 44c in this embodiment of the invention. That is, the handpiece 40c further includes a body 42c coupled to the slider 41c, the positioning tool 44c disposed at the bottom of the body 42c, and an inflation coupled to the bottom of the body 42c. a nozzle 43c having the inflation port 430c, it being understood that the inflation nozzle 43c may be integrally formed on the handpiece 40c or a separate air nozzle device mounted to the handpiece 40c . In this embodiment, in order to better conform to the air inlet 150c of the air cushion body 10c, the air nozzle 43c is a cylindrical type air nozzle made of a silicone material, so that the air inlet 430c can be very good. Matching the air inlet 150c to reduce air source loss during inflation. Of course, the aeration nozzle 43c may also be made of other materials such as metal or organic materials, and the invention is not limited in this respect.

It is worth mentioning that the positioning tool 44c comprises one or more blades which, in this embodiment of the invention, are more easily positioned for positioning the inflatable cushioning body in a double blade configuration. Specifically, as shown in FIG. 44, the positioning cutter 44c is a two-blade structure, and each blade includes a supporting portion 441c and a positioning tip portion 442c extending integrally from the supporting portion 441c, the supporting portion 441c Located in the body 42c, the positioning tip 442c protrudes outside the body 42c. It will of course be understood that the entire blade may also be disposed entirely outside of the fuselage 42c, and the invention is not limited in this respect. Due to the gravity of the handpiece 40c itself, the positioning tip portion 442c can smoothly pierce a plurality of the inflation cushioning bodies 10c at the tip end of the inflatable cushioning body, and does not affect the inflation of the inflation cushioning body 10c. The sealing of the passage 153c.

It can be understood that the outer side of the inflation channel end seal 1030c and the outermost slit 101c of each of the inflatable cushion bodies 10c define a margin region 17c, and the positioning cutter 44c pierces the remaining The side regions 17c, such as the margin regions 17c of at least two of the gas cushioning bodies 10c, do not affect the sealing properties of the respective gas storage units 13c and the gas cells 15c.

When the inflation process is performed, the locking device 35c is in an unlocked state, and the slider 41c of the handpiece 40c cooperates with the slide rail 34c connected to the vertical strut 31c, through the handpiece The self-gravity of 40c allows the handpiece 40c to freely fall along the slide rail 34c to come into contact with the inflatable cushioning body 10c. At this time, the positioning tool 44c on the handpiece 40c is vertically inserted into the inflation cushion body 10c until it is free to stand in a balanced state.

Further, the external air source device may be turned on, for example, by an air pump, enters the air nozzle 43c of the handpiece 40c via the air intake pipe 60c, and then enters from the air inlet 430c of the air nozzle 43c. The inflation passage 153c expands to open the inflation valve 20c to inflate each of the air reservoirs 14c. After the air source device is opened, air passes through the internal mechanism of the handpiece 40c, and air flows through the air source inlet connecting the air tube 60c and the inflation port 430c of the air nozzle 43c to form a downward high-pressure airflow. The top of the inflatable cushioning body The single-film inlet port 150c of the inflation cushion body 10c enters the inflation passage 153c to inflate the inflation cushion body 10c. At the same time, the inflation passage 153c is expanded to cause the air inlet 150c of the upper film forming the inflation passage 153c to be in contact with the inflation port 430c of the handpiece 40c. After the air pressure reaches a certain range, the pressure is sufficient to make The single film is in close contact with the inflation nozzle 43c of the handpiece 40c, that is, the inflation port 430c is capable of closely contacting the air inlet 150c, the inflation nozzle 43c and the inflation passage 95c. The upper film forms a relatively closed environment to maintain the inflation pressure.

When the inflation cushion body 10c of the topmost layer of the inflation cushion body is inflated, the inflation cushion body 10c that has been inflated can be pulled horizontally. Since the positioning tool 44c is always vertically inserted into the inflation cushion body, the pulled inflation cushion body 10c is cut at the positioning position of the positioning tool 44c in conformity with the pulling locus. Due to the gravity of the handpiece 40c and the positioning of the positioning tool 44c, the uppermost air cushion body 10c is pulled out without causing displacement of the under-inflated cushion body, and can continue to be maintained as a gas-filled cushioning body. Coincident state.

After the first inflation cushion body is pulled out, the head 40c is automatically moved down by the restriction of the slide rail 34c and the weight of the head 40c itself, and the second inflation cushion body is exposed to the inflation of the raft. The uppermost portion of the buffer body is similarly formed by the inflation port forming the upper film of the inflation passage 95c, the inflation cushion body 10c is inflated, pulled out after the inflation is completed, and so on, forming a work cycle The gas source device is turned off after the entire inflation cushion is inflated. It is worth mentioning that the positioning accuracy of the inflatable device is affected due to the excessive number of the inflatable cushioning bodies 10c, that is, the thickness of the entire raft is relatively large in value. Therefore, preferably, the number of the inflation cushioning bodies 10c placed on the platform 50c each time is optimally adjusted in accordance with the weight of the handpiece 40c.

When the handpiece 40c is lifted and the locking device 35c is in the locked state, the handpiece 40c cannot fall. At this point, it is possible to continue to place the new inflatable cushioning body 10c, which is inflated, on the platform 10c, thereby continuing the previous inflation step. During the inflation process, each of the inflation buffers of the crucible is relatively overlapped by the limiting device 55, and the locking device 35c is placed in an unlocked state, and the head 40c is slowly dropped due to the influence of gravity. The positioning cutter 44c is inserted into the inflatable cushion body 10c. The air source is turned on again, and the newly added adult inflatable cushioning body continues to be inflated. The first inflatable cushioning body 10c starts to be inflated, and after the inflation is completed, an automatic sealing is formed with the inflatable cushioning body 10c. When it is taken off, the second inflation cushion body 10c starts to be inflated, and the cycle is repeated until all of the inflation cushion bodies 10c are inflated. Only the air supply is required throughout the process. Thus, the inflator device forms a duty cycle that enables continuous automatic inflation of the inflatable cushioning body 10c, providing a continuously automated inflation scheme. And when one of the air cushions needs to be replenished, it can also be further inflated through the air inlet 150c by a hand pump.

It will be understood by those skilled in the art that the inflatable device has a simple structure and can be adapted to different inflation buffers by adjusting the relative positions of the handpiece and the loading platform and the various specifications of the loading platform. The body is inflated and can be formed into a custom model such as a tabletop, portable, etc. without affecting the main performance of the inflatable device, and the present invention is not limited thereto.

According to another aspect of the present invention, an inflation method of an inflatable device for inflating an inflation cushioning body is disclosed, the inflation method comprising the steps of:

(a) the inflatable cushion body 10 of the same size that is placed on a platform 50c of the inflatable device is restrained by the one or more limiting devices 55c of the inflatable device and is in a superposed state;

(b) the bottom of a head 40c of the inflator is attached to the top of the inflator 10c by its own gravity, and a positioning tool 44c of the head 40c is vertically inserted into the inflator 10c. Surrounding area 17c, until the free standing is in equilibrium;

(c) an air source enters the air intake port 150c of the air cushion body 10c via an air inlet 430c of an air nozzle 43c of the handpiece 40c, and then passes through the air intake port 150c. The port 150c enters an inflation passage 153c and finally enters each of the air reservoirs 14c of the air cushion body 10c, wherein the inflation port 430c of the handpiece 40c corresponds to the position of the air inlet 150c and the air nozzle 43c Contacting a surrounding area of the air inlet 150c of the airing unit 15c to form a relatively closed environment;

(d) the first inflation cushioning body 10c of the top layer of the inflatable cushioning body is taken out after being inflated, and at the same time, the positioning cutter 44c cuts the uninflated air of the first inflation cushioning body 10c in accordance with the pulling locus. The margin region 17c, the inflation port 430c of the handpiece 40c is separated from the air inlet 150c of the first inflation buffer body 10c;

(e) the handpiece 40c automatically moves down due to its own gravity, and continues to inflate the second inflation cushioning body 10c that is in contact with the bottom of the handpiece 40c;

(f) The inflating device repeatedly performs the steps (c) to (f) until the air supply is closed after the inflation of the inflation cushion is completed.

As shown in Figures 46A through 47, an inflatable cushioning body in accordance with one embodiment of the present invention. The aerated cushioning body 10d is formed of a two-layer or multi-layer flexible film by a sealing process such as a bonding or heat-sealing process to form a gas-storable air cushioning material, which in this embodiment is preferably formed by a heat sealing process. More specifically, in this embodiment, the gas cushioning body 10d includes one or more connected gas storage units 13d formed by at least two

gas chamber films

11d and 12d formed by a sealing process such as a bonding or heat sealing process. . As shown in Fig. 46 and Fig. 47, a gas storage chamber 14d capable of storing air is formed in each of the gas storage units 13d.

More specifically, the two-layered

gas chamber films

11d and 12d are partitioned into a plurality of the gas storage units 13d by a plurality of rows of slits 101d, that is, the respective slits 101d are formed by a heat sealing process, and the heat seal is connected to the two layers. The

gas chamber films

11d and 12d are formed such that a row of the slits 101d is formed between two adjacent gas storage units 13d. The partition 101d may be a continuous heat seal line such that the plurality of gas storage units 13d are independent of each other. The partitioning slit 101d may also be an intermittent heat sealing line such that a plurality of the gas storage units 13d communicate with each other. The gas storage unit 13d may be in various shapes, such as a strip shape, a circular shape, a polygonal shape or other irregular shapes. The inflatable cushion body 10d of the present invention may include a plurality of inflatable columns arranged side by side, but the present invention There is no limit in this regard.

In this embodiment, the inflation cushioning body 10d further includes a one-way check valve which can realize various structures capable of automatically sealing against air leakage after the inflation cushion body 10d is inflated. For example, in this embodiment, it is an inflation valve 20d formed of at least two layers of

valve films

21d and 22d, and the

valve films

21d and 22d of the inflation valve 20d and the

plenum films

11d and 12d overlap each other. An intake passage 23d for inflating the gas storage chamber 14d is formed between the

valve films

21d and 22d. When the air in the air reservoir 14d is inflated through the intake passage 23d and the air pressure in the air reservoir 14d reaches a predetermined requirement, the air pressure in the air reservoir 14d acts on the

valve membranes

21d and 22d. Upper, so that the

valve films

21d and 22d are attached to one of the plenum membranes, thereby closing the intake passage 23d, so that the inflation valve 20d functions as a one-way valve. When at least one of the intake passages 23d is formed in each of the gas storage units 13d, and each of the gas storage units 13d is independent of each other, when one of the gas storage units 13d is damaged and leaks, other places are The gas storage unit 13d is not affected and can also have an air cushioning effect.

The gas cushion body 10d further includes an inflator unit 15d connected to each of the gas storage units 13d, preferably integrally extending to each of the gas storage units 13d. More specifically, in this embodiment, the

plenum films

11d and 12d form the plenum membrane

main body portions

111d and 121d, respectively, and integrally extend to the plenum membrane main body portion 111d, respectively. And the

inflated end portions

151d and 152d of 121d for forming the gas storage unit 13d by a heat sealing process, and the portions of the

gas chamber films

11d and 12d adjacent to the inflating side are respectively The

inflation end portions

151d and 152d of the inflation unit 15d are formed. The inflatable ends 151d and 152d are superposed on each other and are interconnected at their

end edges

1511d and 1521d by an edge heat seal seam 102d, that is, the edge heat seal seam 102d is formed by a heat sealing process, which sealingly heat seals the joint The

edges

1511d and 1521d of the inflatable ends 151d and 152d.

As shown in Fig. 47, at the positions where the

plenum membrane portions

111d and 121d of the

plenum membranes

11d and 12d are respectively connected to the

inflation end portions

151d and 152d, the gas is sealed by the inflation passage heat seal slit 103d. The

chamber membranes

11d and 12d are respectively connected to the

valve membranes

21d and 22d, and the inflatable membrane heat seal slits 103d are formed by a four-layer membrane by a heat sealing process, which is hermetically sealed to the gas chamber membrane 11d and The valve film 21d is sealingly heat-sealed to connect the gas chamber film 12d and the valve film 22d, but the

valve films

21d and 22d are not hermetically sealed by heat sealing, so that the

valve films

21d and 22d are An intake passage 23d that can inflate the gas storage unit 13d is formed.

It is worth mentioning that when the heat sealing process forms the inflation channel heat seal slit 103d, a heat resistant barrier may be placed between the

valve films

21d and 22d, so that the

valve films

21d and 22d are not heat sealed. Together. In this embodiment, a plurality of heat-resistant layers 24d, such as high-temperature resistant inks and the like, may be disposed between the

valve films

21d and 22d, which are spaced apart from each other corresponding to the intake passage 23, and attached to the The

valve membranes

21d and 22d are one of the inner surfaces of the valve film, so that the heat-resistant layer 24d can prevent the

valve films

21d and 22d from being heat-sealed by the inflation passage heat seal 103d in the heat sealing process. While connected together, the intake passage 23d which can be formed therebetween is communicated with the inflation passage 153d in the inflation unit 15d.

More specifically, the inflation unit 15d of the inflation cushion body 10d forms the inflation passage 153d between the edge heat seal seam 102d and the inflation passage heat seal slit 103d. As shown in Fig. 46A, in this example, for convenience of description, the gas storage units 13d are arranged in the longitudinal direction, and the inflation passages 153d are arranged in the lateral direction, that is, the longitudinally arranged gas storage units before being inflated. 13d may be connected to the same laterally aligned inflation passage 153d through the corresponding intake passage 13d. It can also be said that the inflation passage 153d extends in the width direction of the inflation cushion body 10d and communicates with the respective gas storage units 13d arranged along the longitudinal direction thereof.

It is specifically proposed that, in this embodiment of the invention, the inflation passage 153d retains two side openings due to heat sealing of the edge heat seal line 102d and the inflation passage heat seal line 103d, and is inflated. In the cushion body, the side opening is implemented as a gas source inlet, and the inflation cushion body is inflated from the side by an inflation device. That is to say, in some of the prior art air cushioning bodies, in order to facilitate inflation, some of the heat seals are open on one side, leaving only the other side of the open air, and some sides of the air passage of the air cushion body The openings are all imported as a gas source, and the air intake device is simultaneously used to increase the air supply speed. However, both of these approaches are detrimental to the automated continuous inflation scheme of the inflatable cushioning device utilizing the inflatable device as shown in Figure 46B. Therefore, in this embodiment of the invention, the two side openings of the inflation passage 153d of the inflation cushion are each closed by an inflation passage end seal 1030d. That is, the

inflation end portions

151d and 152d are overlapped with each other and the two side openings left after heat sealing by the edge heat seal slit 102d and the inflation passage heat seal line 103d are the end of the inflation passage end. After the sealing seam 1030d is closed, the inflation passage 15d which is externally closed but communicates internally with each of the intake passages 23d is formed. That is, the gas-filled channel end seal 1030d is formed by a heat sealing process which is sealingly heat-sealed to form a film forming the gas-filled passage 153d, that is, in the present embodiment, the heat-sealed joint is composed of two gas-

chamber films

11d and 12d. The inflatable ends 151d and 152d are formed at the ends. It can be understood that the two ends of the inflation passage 153d of the inflation buffer body 10d may not be closed, but in the inflation process, a pressing device is required to connect the two ends of the inflation buffer body 10d. Pressing to achieve closure.

In order to realize the inflating operation of the inflation buffer body by using the inflation device, the air source is convenient to enter the inflation passage, and the surface of the inflation end portion 151d has an air inlet 150d through which the inflation nozzle of the external inflation air source can pass. The air port 150d inflates the air cushion body 10d. That is, in the production process of the inflation cushion body 10d, the inflation end portion 151d is perforated by the punching device to form the air inlet 150d, and then the inflation end portion 151d is stacked with other films. Hehe heat seal. Accordingly, the intake port 150d may also be disposed at the inflation end portion 152d, and the inflation end portion 151d may not have the intake port 150d. That is, the inflation passage 153d is in a sealed state except that the air inlet 150d facilitates the entry of the air source into the inflation passage 153d, and the interior is connected to each of the intake passages 23d, thereby, the external inflation device The air source can only enter the air inlet passage 153d through the air inlet 150d and then enter the air storage unit 13d through the communicating air inlet passages 23d, and the air cushioning body is due to the air source. Enter and inflate. It is worth mentioning that, in the production process, the air inlet port 150d may be formed on the gas-filling

end portion

151d or 152d after forming the gas-filled buffer body 10d, and the present invention is not limited thereto. .

It is worth mentioning that the sealing of the opening on both sides of the inflation channel 153d may not be an additional separate sealing, but in the production process of the inflation cushion body, through the most edge of the inflatable buffer body Two of the slits 101d extend to the edge heat seal line 102d to be sealed. That is, the inflation passage end seal 1030d for sealing the both side openings of the inflation passage 153d is formed to extend from the partition slit 101d. This also simplifies the production process of the aerated cushion body, and is advantageous for improving production efficiency. It can be understood by those skilled in the art that the formation of the gas-filled channel end seal 1030d of the present invention is not limited to the above two embodiments, and other embodiments for sealing the opening of both sides of the gas-filled passage 153d can also be implemented. The invention is not limited by this.

Further, more specifically, the

valve films

21d and 22d are respectively divided into the proximal end portions 211d and 221d and the

distal end portions

212d and 222d which integrally extend along the length thereof through the inflation passage heat seal slits 103d. The proximal ends 211d and 221d of the

valve membranes

21d and 22d extend into the inflation passage 153d of the inflation unit 15d, and the distal ends 212d and 222d of the

valve membranes

21d and 22d overlap each other and The gas storage chamber 14d is extended to form the intake passage 23d. At a suitable position below the top of the heat-resistant layer 24d, the gas-filled ends 151d and 152d of the gas-filling unit 15d are heat-sealed to the proximal ends 211 and 221 of the

valve films

21d and 22d, respectively, through joint seams 104d. Thus, when inflated, the proximal ends 211d and 221d of the

valve membranes

21d and 22d respectively expand in synchronization with the

inflation end portions

151d and 152d of the inflation unit 15d, that is, the end portions of the

plenum films

11d and 12d. The formed inflatable ends are expanded together to facilitate opening the passage between the

valve membranes

21d and 22d. Similarly, due to the presence of the heat-resistant layer 24d, in the process of heat-sealing the four-layer film, the gas-filled end portion 151d and the proximal end portion 211d of the valve film 21d are heat-sealed, the gas-filled end The portion 152d and the proximal end portion 221d of the valve film 22d are heat-sealed to form the joint slit 104d, and the proximal ends 211d and 221d of the

valve films

21d and 22d are not heat-sealed. connected. In this embodiment, the plurality of joint seams 104d are intermittent heat seal points and are arranged along the direction in which the gas passages 153d of the gas unit 15d extend, so as to be suitable for pulling apart during the inflation process. Air chamber membrane and valve membrane.

The distal ends 212d and 222d of the

valve membranes

21d and 22d are further provided with a plurality of barrier slits 105d which are coupled to the

distal end portions

212d and 222d of the

valve membranes

21d and 22d by a heat sealing process. The gas chamber film 11d is formed by heat sealing connection, that is, the barrier slit 105d is heat-sealed to connect the three-layer film, and the shape and size arrangement thereof does not affect the air intake effect of the intake passage 23d, but may be after the inflation is completed. The air in the gas storage chamber 14d blocking the gas storage unit 13d is reverse osmosis into the inflation passage 153d. Moreover, since the barrier slit 105d is heat-sealed to connect the three-layer film, the gas storage unit After the predetermined gas pressure is reached in the gas storage chamber 14d of 13d, the

distal end portions

212d and 222d of the

valve films

21d and 22d may expand in synchronization with the gas chamber film 11d, thereby finally adhering to the gas chamber. The membrane 11d is for sealing the intake passage 23d.

Further, the

plenum films

11d and 12d of the gas cushion body 10d and the

valve films

21d and 22d of the gas filling valve 20d may be made of various suitable film materials, such as polyethylene film, polypropylene, respectively. The present invention is not limited in this respect as a film, a polyvinyl chloride film, a polyester film, a polystyrene film or a composite film, and the like, as long as it is a suitable flexible film. It is worth mentioning that, in order to increase the one-way sealing effect, the

valve films

21d and 22d of the inflation valve 20d may also be self-adhesive films modified by adding chemical components to the above-mentioned film.

It is worth mentioning that the present invention also discloses a method of manufacturing the gas cushion body, and the manufacturing method comprises the following steps:

(a) an end of a first plenum membrane 11d is perforated for forming an air inlet 150 of the plenum; and

(b) arranging the first plenum film 11d and a second plenum film 12d and an inflation valve 20d in a superposed manner, and forming at least one gas storage unit 13d and at least one gasification unit 15d through a series of heat seals. The inflation cushion body, wherein the air inlet 150d is formed in the inflation unit 15d, wherein when inflated, gas enters the inflation passage 153d of the inflation unit 15d from the air inlet 150d, and from the inflation The passage 153d enters each of the gas storage units 13d via the inflation valve 20d.

Wherein, the inflation passage 153d is formed by the first and the second plenum membranes being sealed and sealed by an inflation passage edge slit 103d, an edge heat seal seam 102d and two inflation passage end seals 1030d.

Wherein, the inflation passage 153d may also be connected to the inflation passage by the first or the second plenum membrane via an inflation passage edge slit 103d, an edge heat seal seam 102d and the most edge two slits 101d. An edge slit 103d and the edge heat seal seam 102d are formed.

It should be noted that in other embodiments, the inflation channel may also be formed by other embodiments as long as the air inlet is disposed in the first or second air chamber membrane, and the air source can only be The intake port 150d enters the inflation passage 153d to enter each of the intake passages 23d, and the present invention is not limited thereto.

As shown in FIG. 48 and FIG. 49, in another modified embodiment, the two layers of the gas chamber films 11AA and 12AA may also be formed by folding a whole film along the fold line 106AA, that is, two layers of the gas chamber film. 11AA and 12AA are integrally extended, wherein the inflating unit 15AA is correspondingly also composed of two inflated ends 151AA and 152AA integrally connected in a folded manner. Thus, the inflation passage 153AA is formed between the pair of fold lines 106AA and the inflation passage heat seal slits 103AA. That is, in the examples shown in Figs. 48 and 49, the edge heat seal seam 102d in the above embodiment is not required.

It is specifically proposed that in this embodiment of the invention, the two side openings of the inflation channel 153AA of the inflatable cushion are each closed by an inflation channel end seal 1030AA. That is, the inflation ends 151AA and 152AA overlap each other and the two side openings left after heat sealing through the inflation channel heat seal line 103AA are closed by the inflation channel end seal 1030AA to form an external seal. However, the inflation passage 15AA is internally communicated with each of the intake passages 23AA. That is, the inflation channel end seal 1030AA is formed by a heat sealing process that sealingly heat seals the inflation passage 153AA.

In order to realize the inflating operation of the inflation buffer body by the inflation device, the air source is convenient to enter the inflation passage, and the surface of the inflation end portion 151AA has an air inlet 150AA through which the inflation nozzle of the external inflation air source can pass. The air port 150AA inflates the air cushion body 10AA. That is, the production of the aeration cushion body 10AA has been In the process, the inflation end portion 151AA is perforated by the punching device to form the air inlet 150AA, and then the inflation end portion 151AA is superposed and heat sealed with other films. Accordingly, the air inlet 150AA may also be disposed at the inflation end 152AA, and the inflation end 151AA may not have the air inlet 150AA. That is, the inflation passage 153AA is in a sealed state except that the air inlet 150AA facilitates the entry of the air source into the inflation passage 153AA, and the interior is connected to each of the intake passages 23AA, thereby, the external inflation device The air source can only enter the air inlet passage 153AA through the air inlet 150AA, and then enters each of the air storage units 13AA through the communicating air inlet passages 23AA, and the air cushioning body is due to the air source. Enter and inflate. It is worth mentioning that, in the production process, the air cushioning body 10AA may be formed first and then the air inlet port 151AA or 152AA is bored to form the air inlet 150AA. The present invention is not limited thereto. .

Correspondingly, the sealing of the opening of the two sides of the inflation channel 153AA may also be extended by the two edges of the two sides of the inflatable buffer body during the production process of the inflatable cushion body. The folded line 106AA is described as being sealed. That is, the inflation channel end seal 1030AA for sealing the both side openings of the inflation passage 153AA is formed by the extension slit 101AA. This also simplifies the production process of the aerated cushion body, and is advantageous for improving production efficiency. It can be understood by those skilled in the art that the formation of the inflation channel end seal 1030AA of the present invention is not limited to the above two implementations, and other embodiments for sealing the opening at both sides of the inflation channel 153AA can also be implemented. The invention is not limited by this.

(A) a whole air chamber membrane is perforated by a punching device for an air inlet 150AA of the inflatable buffer body;

(B) the entire plenum film is folded in a pair of fold lines to form first and second plenum films 11AA and 12AA;

(C) arranging the first and second plenum films 11AA and 12AA and an inflation valve 20AA in a superposed manner, and forming the aerated buffer body through a series of heat seals and forming at least one gas storage unit through a series of heat seals 13A and the inflation cushioning body of the at least one inflation unit 15AA, wherein the air inlet 150AA is formed in the inflation unit 15AA, wherein when inflated, gas enters the inflation passage of the inflation unit 15AA from the air inlet 150AA 153AA, and each of the gas storage units 13AA is entered from the inflation passage 153AA via the inflation valve 20AA.

Accordingly, preferably, the inflation valve 20AA is formed of at least two layers of valve films, so that in the step (C), the first and second plenum films 11AA and 12AA and the two layers of the valve film are required to be superposed and passed through. A series of heat seals.

Further modified embodiments of the inflation cushioning body 10d are further described below.

As shown in Figs. 50 and 51, similarly, each of the inflation cushion bodies 10d includes a plurality of gas storage units 13d and an inflation unit 15d. A heat-resistant layer 24BB is disposed between the

valve films

21d and 22d, and is attachable to an inner surface of any one of the valve films. The heat-resistant layer 24BB includes a heat-resistant layer body section 241BB and a plurality of heat-resistant layer branch sections 242BB extending from the heat-resistant layer body 241BB at intervals. The heat-resistant layer body section 241BB integrally extends in the direction of the inflation passage 153d, and each of the heat-resistant layer branch sections 242BB extends into each of the gas storage units 13d to ensure the formation of the intake passage 23d.

The

gas chamber films

11d and 12d are further heat-sealed to the

valve films

21d and 22d, respectively, through continuous joint seams 104BB, respectively, because the heat-resistant layer body segments 241BB are present, and the

valve films

21d and 22d are The gaps are not heat-sealed by the joint slits 104BB, so that the

valve films

21d and 22d can be expanded in synchronization with the

gas chamber films

11d and 12d, respectively, to facilitate opening of each of the intake passages 23d.

Similarly, in this modified embodiment of the present invention, the upper surface of the inflation end portion 151BB has an air inlet 150BB through which the inflation nozzle of the external inflation air source can be pressed and passed through the air inlet. The inflatable cushion body 10BB is inflated by 150BB. That is, in the production process of the inflation cushion body 10BB, the inflation end portion 151BB is perforated by the punching device to form the air inlet 150BB, and then the inflation end portion 151BB is superposed on other films. And heat sealed.

It is worth mentioning that, in the above embodiment, the inflation cushion body forms a cushion after inflation, and the cushion is suitable for being placed in a packaging container as a cushioning filling material.

52A to 54B are further modified embodiments of the inflatable cushioning body 10d, and the inflated structure is shown in the figure, which can be implemented as a three-dimensional air packaging material having a receiving cavity 16CC, that is, a three-dimensional packaging. A bag, wherein the packaged article is adapted to be packaged in the receiving cavity 16CC. Specifically, as shown in FIGS. 52A and 52B, the inflatable cushion body 10CC of the planar cushioning material formed by one-time thermoplastic sealing with respect to the above embodiment further includes a three-dimensional plastic seal in this embodiment. The slit 107CC, that is, the inflation cushion body 10CC is formed into the package by a primary thermoplastic sealing step and a secondary thermoplastic sealing step. The primary thermoplastic sealing step is used to form a planar cushioning material, and the three-dimensional plastic sealing seam 107CC forms a plurality of side walls after the planar cushioning material is bent, thereby forming a three-dimensional packaging bag having a receiving cavity 16CC. In the example shown in Figs. 52A and 52B, the three-dimensional molding slits 107CC are respectively formed on both sides of the planar cushioning material and finally obtain a substantially U-shaped three-dimensional packaging bag.

It is worth mentioning that, in addition to the manner in which the inflatable cushioning body 10d of the sputum in Fig. 46B is superposed and continuously inflated, as shown in Figs. 52A and 52B, an adjacent two of the inflatable cushioning bodies 10CC are formed. There is a slit 17CC to form the inflatable cushion body 10CC having the two accommodation chambers 16CC so that the two packaged articles can be packaged. That is to say, a plurality of the air cushioning bodies are commonly inflated by the same inflating unit 15CC, and are inflated and used as one body for packaging two or more packaged articles. In addition, a plurality of the inflatable cushioning bodies may not be integrated, that is, after the inflation is completed, they may be separately sprinkled into independent inflatable packaging bags. Wherein, before the tearing, the inflation operation is first performed, that is, the air source enters each of the intake passages through the intake port 150CC of the inflating unit 15CC, and each of the inflating cushion bodies 10CC is inflated. After each of the inflatable cushioning bodies 10CC of the continuous inflation cushioning body 100CC is inflated, it can be torn off by a tearing line disposed along the position of the spacing slit 17CC.

In FIGS. 53A to 54B, the plurality of gas storage units 13DD and 13EE are further bent such that the plurality of side walls are formed in a C-shaped bag having an opening in the middle instead of being at the top after being three-dimensionally molded. The inflation cushion body 10DD or the inflation cushion body 10DD which is an O-shaped bag. It will be understood by those skilled in the art that the configuration of the above-mentioned three-dimensional bag is merely an example and does not limit the present invention, and the inflation process of the present invention can also be applied to a three-dimensional packaging bag of other configurations.

As shown in FIGS. 55 and 56, in this modified embodiment, the inflator 10FF includes a plurality of gas storage units 13FF and an inflator unit 15FF, wherein the inflator unit 15FF and the two layers of the valve membranes 21FF and 22FF The integral connection is formed, that is, the inflator unit 15FF is formed by two integrally extending outer extensions of the valve films 21FF and 22FF.

Specifically, the inflator unit 15FF includes two inflating end portions 151FF and 152FF which integrally extend integrally with the valve films 21FF and 22FF, and the air chamber films 11FF and 12FF extend only to the inflating passage heat seal seam 103FF. a position such that upon inflation, the gas in the inflation tube 32d directly enters the inflation passage 153FF defined between the inflation ends 151FF and 152FF formed by the outer ends of the two layers of the valve membranes 21FF and 22FF. Thereby, it is possible to smoothly further enter each of the intake passages 23FF.

It is specifically proposed that in this embodiment of the invention, the two layers of the valve films 21FF and 22FF form the charge The inflation passage 153FF of the gas unit 15FF leaves two side openings due to heat sealing of the edge heat seal line 102FF and the inflation passage heat seal line 103FF, and the inflation passage 153FF of the gas cushion body The two side openings are each closed by an inflation channel end seal 1030FF. That is, the inflation end portions 151FF and 152FF are overlapped with each other and the two side openings left after heat sealing by the edge heat seal slits 102FF and the inflation passage heat seal line 103FF are the end of the inflation passage end. After the seal 1030FF is closed, the inflation passage 15FF which is externally closed but communicates with each of the intake passages 23FF is formed. That is, the inflation channel end seal 1030FF is formed by a heat sealing process that sealingly heat seals the inflation passage 153FF.

In order to realize the inflating operation of the inflation buffer body by using the inflation device, the air source is convenient to enter the inflation passage, the surface of the inflation end portion 151FF has an air inlet 150FF, and the inflation nozzle of the external inflation air source can be pressed into the air inlet. The inflator unit 15FF and the inflator 10FF are inflated through the air inlet 150FF. That is, in the production process of the inflation cushion body 10d, the inflation end portion 151FF is perforated by the punching device to form the air inlet 150FF, and then the inflation end portion 151FF is stacked with another film. Hehe heat seal. Accordingly, the intake port 150FF may also be disposed at the inflation end portion 152FF, and the inflation end portion 151d may not have the intake port 150FF. That is, the inflation passage 153FF is in a sealed state except that the air inlet 150FF facilitates the entry of the air source into the inflation passage 153FF, and the interior is connected to each of the intake passages 23FF, thereby, the external inflation device The air source can only enter the air inflating channel 153FF through the air inlet 150FF and then enter the air storage unit 13FF through the communicating air inlet passages 23FF, and the air cushioning body is due to the air source. Enter and inflate. It is to be noted that, in the production process, the air inlet 150F may be formed on the outer end of the valve film 21FF or 22FF after forming the air cushion body 10FF, and the present invention does not Subject to this restriction.

It is worth mentioning that the sealing of the opening on both sides of the inflation channel 153FF may also be two slits 101FF passing through the most edge of the two sides of the inflation buffer body during the production process of the inflation buffer body. The edge heat seal line 102FF is extended to form a seal. That is, the inflation passage end seal 1030F for sealing the both side openings of the inflation passage 153FF is formed by the extension slit 101FF. This also simplifies the production process of the aerated cushion body, and is advantageous for improving production efficiency. It can be understood by those skilled in the art that the formation of the inflation channel end seal 1030FF of the present invention is not limited to the above two implementations, and other embodiments for sealing the opening at both sides of the inflation passage 153FF may also be implemented. The invention is not limited by this.

(i) an end of a first valve film 21FF is perforated by a punching device for forming an air inlet of the gas cushioning body;

(ii) arranging the first valve film 21FF and a second valve film 22FF, and the first and second plenum films 11FF and 12FF in a superposed manner, and forming at least one gas storage unit 13FF via a series of heat seals And the gas-filled buffer body of at least one gas-filling unit 15FF, wherein the valve films 21FF and 22FF have convex portions with respect to the first and second gas-chamber films 11FF and 12FF to form the gas-filling unit 15FF, wherein The air inlet 150FF is formed in the airing unit 15FF, wherein when inflated, gas enters the inflation passage 153FF of the airing unit 15FF from the air inlet 150FF, and further from the inflation passage 153FF via the inflation valve 20FF Each of the gas storage units 13FF is entered.

Additionally, in this variant embodiment, the two layers of the inflatable ends 151FF and 152FF may be formed as separate two layers of film and heat sealed by a continuous edge heat seal 102FF. And as shown in Figures 57 and 28, the two layers are described. The inflatable ends 151GG and 152GG may also be formed from a film along the fold line 106GG so that there is no need to heat seal the connection through the continuous edge heat seal 102FF described above.

It is worth mentioning that, correspondingly, the present invention also discloses a method for inflating the inflation cushion body, wherein the inflation buffer body comprises at least one gas storage unit and an inflation unit connected to each other, and the inflation passage has an inflation Channels, each of the gas storage units has at least one gas storage chamber that is inflated through the gas passage, and the gasification unit surface is provided with an air inlet, through which gas enters the air inlet The port then enters each of the gas storage chambers via the inflation passage to complete the inflation operation of the inflation cushion body.

In the present invention, the inflation cushioning body further includes a one-way inflation valve formed of at least two layers of valve membranes, so that after the inflation is completed, the one-way inflation valve is automatically closed to prevent the respective gas storage chambers from being The gas is reverse osmosis to the inflation passage.

And in this embodiment, the gas-filling passages are closed at both ends, and communicate with the outside only through the gas inlet of the surface of the gas-filling unit, and the gas enters the gas-filling passage in a direction perpendicular to the surface of the gas-filling unit.

It can be understood that the inflating unit may be formed by overlapping two layers of the air chamber film at a portion corresponding to the inflation passage, or a two-layer valve film may be formed by overlapping portions corresponding to the inflation passages.

Further, when a plurality of the air cushions are arranged superposed on each other to form the air cushion body, the next one of the air cushions is inflated and taken away, the next one of the air cushions The buffer body becomes the topmost side of the inflation cushion and continues to be inflated continuously.

In addition, as shown in FIG. 59 and FIG. 60, the outer side of the boundary slit formed by the outermost slits 101HH and 101II may be provided with one or more recesses 107HH or positioning holes 107II, thereby facilitating the passage of the positioning post. The notch 107HH or the positioning hole 107II acts on the stopper of the inflatable cushion body.

It can be understood that, as shown in FIG. 59, the inflation channel end seal 1030HH may also be integrally formed with the most spaced apart slit 101HH instead of a separate additional plastic seal. Moreover, when the inflation cushion body is a three-dimensional packaging bag, the inflation channel end seal 1030HH and the outermost side slit 101HH may be formed in a three-dimensional plastic sealing step, that is, a plurality of connections of the planar cushioning material after folding Formed in a plastic sealing step when a plurality of side walls.

In addition, the inflation channel end seal 1030HH and the outermost side of the partition 101HH form a margin region 17HH, that is, the damage does not affect the gas storage performance of the entire air cushion body 10HH, so that it can be used for convenient positioning. Position the knife.

As shown in FIG. 61 to FIG. 63, it also specifically discloses an inflation method using an inflation device for inflating a sputum inflation cushion body, the inflation method comprising the following steps:

The inflation cushion body 10d of the same specification that is placed on a platform 50d of the inflatable device is restrained by one or more limiting devices 55d of the inflatable device and is in a superposed state;

The bottom of a head 40d of the inflatable device slidably disposed with a bracket 30d is affixed to the top of the inflatable cushion body 10d by its own gravity, and a positioning tool 44d of the head 40d is vertically inserted into the rafter. The remaining region of the inflated cushion body 10d is in a state of equilibrium until free and stationary;

An air source enters the air intake port 150d of the air cushion body 10d via an air inlet 430d of an air nozzle 43d of the handpiece 40d, and then passes through the air inlet 150d. Entering an inflation passage 153d, and finally entering each of the air reservoirs 14d of the air cushion body 10d, wherein the air inlet 430d of the nose 40d corresponds to the position of the air inlet 150d and the air nozzle 43d contacts The air inlet 150d of the inflating unit 15d The surrounding area forms a relatively closed environment;

The first inflation cushion body 10d of the top layer of the inflatable cushioning body is taken out after being inflated, and at the same time, the positioning cutter 44d cuts the uninflated margin area of the first inflation cushioning body 10d in accordance with the pulling trajectory. The air inlet 430d of the handpiece 40d is separated from the air inlet 150d of the first air cushion body 10d;

The handpiece 40d automatically moves down due to its own gravity, and continues to inflate the second inflation buffer body 10d that is in contact with the bottom of the handpiece 40d;

The inflating device repeatedly performs the steps (c) to (f) until the air supply is closed after the inflation of the inflation cushion is completed.

64-68 is a portable inflatable device for carrying and quickly inflating to a desired device 100e to be inflated, such as an air-packing device, the air-filled package, in accordance with an embodiment of the present invention. Bags, balloons, tires, etc. In particular, when the gas is filled into the air-filled packaging device or the air-filled packaging bag in the inflated mode, a cushioning effect is generated. Therefore, when the air-filled packaging device or the air-filled packaging bag is used to accommodate or wrap the articles, the articles placed inside the air-packing device or the air-filled packaging bag can be protected from collision with each other to cause damage.

In this embodiment, the portable inflator includes a pump body 10e, a control unit 20e, a motor unit 30e, a power supply unit 40e, and a gas nozzle 50e. The pump body 10e is coupled to the motor unit 30e such that when in the inflated mode, the motor 30e operates to draw air outside the portable inflator into the interior of the pump body 10e. The control unit 20e is connected to the motor unit 30e and the power supply unit 40e, such that the control unit 20e can obtain an electric energy via the power supply unit 40e to control the motor unit 30e. Specifically, the electric energy supplied from the power supply unit 40e also serves as a power source when the motor unit 30e is operated. The air nozzle 50e is connected to the pump body 10e and is opposed to the motor unit 30e, so that the air sucked into the pump body 10e when the motor 30e is operated can be discharged through the air nozzle. Therefore, when the air nozzle 50e is connected to the air-packing device or the air-filled packaging bag, the air will be sucked through the motor unit 30e, flow through the pump body 10e, and finally by the air nozzle. 50e fills the air into the air-filled packaging device or the interior of the air-filled packaging bag such that the air-filled packaging device or the air-filled packaging bag will have the cushioning effect.

In this embodiment, the pump body 10e includes a first port 111e connected to a gas cylinder 11e of a first end portion 31e of the motor unit 30e, wherein the gas nozzle 50e is coupled to the gas cylinder 11e. a second port 112e, such that when the motor unit 30e is operated by the control unit 20e, the motor unit 30e draws in the air and from the first end 31e of the motor unit 30e The air is propelled into the inside of the air cylinder 11e of the pump body 10e, and then the air is ejected from the air nozzle 50e of the second air port 112e connected to the air cylinder 11e. It will be appreciated that in the inflated mode, the air nozzle 50e is coupled to the device to be inflated 100e such that the portable inflator will be able to quickly and easily charge the gas into the device 100e to be inflated. As shown in Fig. 68, the air nozzle 50e is connected to an inflation inlet 110e of the apparatus 100e to be inflated, such that the air passes the air outside the portable inflation apparatus via the principle of suction and discharge of the motor unit 30e. Suction into the inside of the air cylinder 11e of the pump body 10e, and then propelling the air to the air nozzle 50e via the air nozzle 50e connecting the second air port 112e of the air cylinder 11e The inflator can stop the operation of the motor unit 30e via the control unit 20e after the inflation is completed.

In this embodiment, the control unit 20e includes a control circuit 21e, a power control switch 22e, a pressure control switch 23e, a flow rate control switch 24e, and a display unit 25e. The power supply unit 40e is electrically connected to the The control circuit 21e is described. The power control switch 22e, the pressure control switch 23e and the flow rate control switch 24e are respectively connected to the control circuit 21e. The display unit 25e is connected to the control circuit 21e. It will be appreciated that the power control switch 22e is located on an outer surface of a housing 90e of the portable inflator for rapid switching of operation of the motor unit 30e. In other words, the motor unit 30e can be controlled to be turned on or off via the power control switch 22e. The pressure control switch 23e is coupled to the air cylinder 11e of the pump body 10e for sensing the internal pressure of the air cylinder 11e. Specifically, in the inflating mode, when the air nozzle 50e is connected to the device to be inflated 100e and starts to push air into the device to be inflated 100e via the air cylinder 11e, the air cylinder 11e, the air nozzle 50e and the device to be inflated 100e assume a connected state. Therefore, the air pressure state inside the to-be-inflated device 100e can be sensed via the pressure control switch 23e, and when the air pressure of the device to be inflated 100e reaches a preset pressure value, the pressure control switch 23e can pass the The control circuit 21e and the power control switch 22e stop inflating the device to be inflated 100e. It is worth mentioning that the preset pressure value can be set and adjusted according to different needs. Further, the flow rate control switch 24e is located on the outer surface of the outer casing 90e of the portable inflatable device, so that the magnitude of the intake air amount can be easily switched by the flow rate control switch 24e. The display member 25e is located on the outer surface of the outer casing 90e of the portable inflatable device, so that various relevant values can be obtained via the display member 25e, such as the preset pressure value, the actual filling process. Pressure value, flow rate related value, on and off display, etc. It will be appreciated that in some embodiments, the pump body 10e may also be integrated with the housing 90e into a housing component, i.e., a portion of the housing 90e forms the pump body 10e.

In this embodiment, the motor unit 30e includes one or more vent openings 33e at a second end 32e such that when the motor unit 30e is in operation, the air enters the vent through the vent opening 33e The inside of the air cylinder 11e of the pump body 10e. It is worth mentioning that the motor unit 30e includes a driving element 34e and a passive element 35e connected to the driving element 34e. It will be understood by those skilled in the art that the drive element 34e can be a motor, an electric motor or an electric motor, which is an electrical device that converts electrical energy into mechanical energy and can use mechanical energy to generate kinetic energy for driving other devices. Most electric motors generate energy in the motor through the magnetic field and winding current. The passive element 35e may be a blade structure, such as a fan blade or an exhaust fan blade, wherein the drive element 34e can drive the passive element 35e to operate, that is, the motor drives the blade to rotate through the blade Rotation will cause convection of the air.

In this embodiment, the power supply unit 40e includes a minimum of one battery 41e coupled to the control circuit 21e of the control unit 20e for providing the electrical energy required for operation of the motor unit 30e. It is worth mentioning that the battery 41e may be a rechargeable battery or a disposable battery. The power supply unit 40e includes a charging connection port 42e connected to the control circuit 21e, such that when the battery 41e is a rechargeable battery, the charging connection port 42e can be connected to an external power source to fill the electrical energy to The battery 41e is internal. It is worth mentioning that the portion of the outer casing of the inflatable device that houses the power supply unit 40e may form a hand-held portion to facilitate the operator to hold the portable inflatable device and perform an inflation operation.

In this embodiment, the gas nozzle 50e can be coupled to various conventional aeration nozzles to facilitate the operation of inflation or venting. In particular, the air nozzle 50e can also be directly replaced with various conventional inflation nozzles to directly and conveniently connect the various inflating devices 100e, such as the inflatable packaging device, the inflatable packaging bag, the balloon, and the tire. , storage boxes, storage bags, etc. Specifically, a hose 51e can be connected between the air nozzle 50e and the second air port 112e of the air cylinder 11e, which can increase the convenience of use, as shown in FIG. It is worth mentioning that the outer casing 90e is further A receiving box 91 is included for housing the conventional aeration nozzle.

In this embodiment, as shown in FIG. 68, it is worth mentioning that the portable inflator further includes a heat sealing unit 60e electrically connected to the control circuit 21e of the control unit 20e to control the Heat sealing unit 60e. The electric energy provided by the power supply unit 40e is converted into thermal energy by the heat sealing unit 60e by using the electrothermal conversion principle. At this time, when the filling device 100e is completed, the heat sealing unit 60e can be passed through the heat sealing unit 60e. The inflation inlet 110e is quickly sealed.

In addition, as shown in FIG. 69, those skilled in the art should understand that the portable inflatable device can be designed into various shapes to achieve various functions such as being simple and easy to carry.

In accordance with still another aspect of the present invention, the present invention provides an inflation method utilizing a portable inflatable device for rapidly inflating an inflating device 100e, the inflation method being as follows:

Connecting a gas nozzle 50e of the portable inflatable device to an inflation inlet 110e of the device 100e to be inflated;

Running a motor unit 30e to allow air to enter a pump 11e of a pump body 10e;

Filling the air from the air nozzle 50e connected to the air cylinder 11e to the to-be-inflated device 100e;

After the filling is completed, the inflation inlet 110e of the device to be inflated 100e is closed as needed. Of course, in some configurations of the device to be inflated having a one-way valve, the above-described step of closing the inflation inlet 110e is not required.

According to the step (2) of the inflation method using the portable inflatable device, the operation of the motor unit 30e can be controlled via a control unit 20e, and the required electric energy is controlled by a power supply unit 40e connected to the control unit 20e. provide. It is worth mentioning that the motor unit 30e includes a driving element 34e and a passive element 35e connected to the driving element 34e. Those skilled in the art will appreciate that the drive element 34e can be a motor, an electric motor or an electric motor. The passive element 35e may be a blade structure, such as a fan blade or an exhaust fan blade, wherein the drive element 34e can drive the passive element 35e to operate, that is, the motor drives the blade to rotate through the blade Rotation will cause convection of the air.

In particular, the air nozzle 50e can be connected to various conventional inflation nozzles to facilitate the operation of inflation, and the air nozzle 50e can also be directly replaced with various conventional inflation nozzles for direct connection to various places. The inflator 100e is described. Further, a hose 51e may be connected between the air nozzle 50e and the second air port 112e of the air cylinder 11e to increase the convenience of use.

According to the step (4), the inflation inlet 110e of the device to be inflated 100e may be closed, the inflation inlet 110e may be plugged by a gas-tight plug, or the inflatable inlet 110e may be clamped by a belt. . It is worth mentioning that the portable inflatable device further includes a heat sealing unit 60e electrically connected to the control circuit 21e of the control unit 20e to control the heat sealing unit 60e. In this way, the electric energy provided by the power supply unit 40e is converted into thermal energy by the heat sealing unit 60e via the electrothermal conversion principle, and when the filling of the device to be inflated 100e is completed, the heat sealing unit 60e can be quickly The inflation inlet 110e is heat sealed.

The operation of the motor unit 30e can be controlled via a control unit 20e, the required electrical energy being provided by a power supply unit 40e connected to the control unit 20e. It is worth mentioning that the motor unit 30e includes a driving element 34e and a passive element 35e connected to the driving element 34e. Those skilled in the art will appreciate that the drive element 34e can be a motor, an electric motor or an electric motor. The passive element 35e may be a blade, such as a fan blade or an exhaust fan blade, wherein the drive element 34e can drive the passive element 35e to operate, that is, the motor drives the blade to rotate, and the blade rotates This air will be convected.

70 to 74 are a portable inflatable device for conveniently carrying and rapidly inflating to a desired device to be inflated 100e, such as an air-packing device, said inflating, in accordance with an embodiment of the present invention. Packaging bags, balloons, tires, etc. In particular, in the inflated mode, a cushioning effect is created when the gas is filled into the inflatable packaging device or the inflatable packaging bag. Therefore, when the air-filled packaging device or the air-filled packaging bag is used to accommodate or wrap the articles, the articles placed inside the air-packing device or the air-filled packaging bag can be protected from collision with each other to cause damage.

In this embodiment, the portable inflator includes a pump body 10e, a control unit 20e, a power supply unit 40e, a gas nozzle 50e, a solenoid valve unit 70e, and a piston 80e. The piston 80e is located inside the pump body 10e and is connected to the solenoid valve unit 70e so that when the solenoid valve unit 70e is actuated, convection of air can be caused. The control unit 20e is connected to the solenoid valve unit 70e and the power supply unit 40e, such that the control unit 20e can obtain an electric energy via the power supply unit 40 to control the solenoid valve unit 70e. In particular, the electric energy supplied from the power supply unit 40e also serves as a power source when the solenoid valve unit 70e is actuated. The air nozzle 50e is coupled to the pump body 10e and is opposite to the solenoid valve unit 70e. Specifically, in the inflation mode, the solenoid valve unit 70e drives the air sucked into the pump body 10e by the piston 80e, and can be discharged through the air nozzle. Therefore, when the air nozzle 50e is coupled to the air-packing device or the air-filled packaging bag, the air will flow through the pump body 10e after being actuated via the piston 80e, and finally by the air nozzle 50e fills the air into the air-filled packaging device or the interior of the air-filled packaging bag such that the air-filled packaging device or the air-filled packaging bag will have the cushioning effect.

In this embodiment, the pump body 10e includes a gas cylinder 11e, a first two-way check valve 12e and a second two-way check valve 13e. The piston 80e is located inside the air cylinder 11e. The first two-way check valve 12e is located at a first port 111e of the air cylinder 11e. The second two-way check valve 13e is located at a second port 112e of the air cylinder 11e. The air nozzle 50e is coupled to the second air port 112e of the air cylinder 11. It is worth mentioning that, as shown in FIGS. 71 to 72, the portable inflator is switched to the inflating mode via the control unit 20e, so that the solenoid valve unit 70e drives the piston 80e to perform inside the pump body. mobile. When the piston 80e moves toward the solenoid valve, the first two-way check valve 12e opens to connect the first port 111e to the inside of the air cylinder 11e and the outside of the portable inflator, when the air The air cylinder 11e will enter via the first port 111e, in particular, the second port 112e is now closed by the second two-way check valve 13e. Next, when the piston 80e moves toward the air nozzle 50e, the first two-way check valve 12e closes the first port 111e, and the second two-way check valve 13e opens to The air inside the air cylinder 11e is ejected through the air nozzle 50e, and at this time, if the air inflating device 100e is connected to the air nozzle 50e, gas filling can be quickly performed. It is worth mentioning that the upper arrow in the figure refers to the direction in which the piston moves.

In this embodiment, the control unit 20e includes a control circuit 21e, a power control switch 22e, a pressure control switch 23e, a flow rate control switch 24e, and a display unit 25e. The power supply unit 40e is electrically connected to the control circuit 21e. The power control switch 22e, the pressure control switch 23e and the flow rate control switch 24e are respectively connected to the control circuit 21e. The display unit 25e is connected to the control circuit 21e. It can be understood that the power control switch 22e is located on an outer surface of the outer casing 90e of the portable inflatable device for quick cutting. The action of the solenoid valve unit 70e is changed. In other words, the solenoid valve unit 70e can be controlled to be turned on or off via the power source control switch 22e. The pressure control switch 23e is coupled to the air cylinder 11e of the pump body 10e for sensing the internal pressure of the air cylinder 11e. Specifically, in the inflating mode, when the air nozzle 50e is connected to the to-be inflated device 100e and starts to push air into the to-be-inflated device 100e via the air cylinder 11e, the air cylinder 11e, the air nozzle 50e and the device to be inflated 100e assume a connected state. Therefore, the air pressure state inside the to-be-inflated device 100e can be sensed via the pressure control switch 23e, and when the air pressure of the device to be inflated 100e reaches a preset pressure value, the pressure control switch 23e can pass the The control circuit 21e and the power control switch 22e stop inflating the device to be inflated 100e. It is worthwhile to note that the preset pressure value can be set and adjusted according to different needs. Further, the flow rate control switch 24e is located on the outer surface of the outer casing 90e of the portable inflatable device, so that the magnitude of the intake air amount can be easily switched by the flow rate control switch 24e. The display member 25e is located on the outer surface of the outer casing 90e of the portable inflatable device, so that various relevant values can be obtained via the display member 25e, such as the preset pressure value, the actual filling process. Pressure value, flow rate related value, on and off display, etc.

In this embodiment, the power supply unit 40e includes at least one battery 41e connected to the control circuit 21e of the control unit 20e for providing the electrical energy required for the solenoid valve unit 70e to operate. . It is worth mentioning that the battery 41e may be a rechargeable battery or a disposable battery. The power supply unit 40e includes a charging connection port 42e connected to the control circuit 21e, such that when the battery 41e is a rechargeable battery, the charging connection port 42e can be connected to an external power source to fill the electrical energy to The battery 41e is internal.

In this embodiment, the gas nozzle 50e can be coupled to various conventional aeration nozzles to facilitate the operation of inflation or venting. In particular, the air nozzle 50e can also be directly replaced with various conventional inflation nozzles to directly and conveniently connect the various inflating devices 100e, such as the inflatable packaging device, the inflatable packaging bag, the balloon, and the tire. , storage boxes, storage bags, etc. Specifically, a hose 51e can be connected between the air nozzle 50e and the second air port 112e of the air cylinder 11e, which can increase the convenience of use, as shown in FIG.

In this embodiment, as shown in FIG. 75, it is worth mentioning that the portable inflator further includes a heat sealing unit 60e electrically connected to the control circuit 21e of the control unit 20e to control the Heat sealing unit 60e. The electric energy provided by the power supply unit 40e is converted into thermal energy by the heat sealing unit 60e by using the electrothermal conversion principle. At this time, when the filling device 100e is completed, the heat sealing unit 60e can be passed through the heat sealing unit 60e. The inflation inlet 110e is quickly sealed.

76 to 77 are air-filled packaging apparatuses 100e according to the present invention which can utilize the above-described embodiments, which have an inflatable structure to be used for various packaged articles such as electronic products, foods, medical products, and chemicals after inflation. The raw material, the biological material, the plastic ceramics, the fast-moving consumer goods and the like provide a gas buffering effect, and when not in use, can be conveniently stored and transported without being inflated, and can be inflated by using the above-mentioned inflatable device of the present invention on site, thereby being very convenient to use. .

In this embodiment of the invention, the inflatable packaging device can be embodied as an air cushioning material, i.e., the charged gas is exemplified by air, although it will be understood by those skilled in the art that other gases may be used as needed in the application. In this embodiment, after inflation, it can form a three-dimensional package, or an inflated, flat-fill cushioning material to provide an air cushioning effect for a packaged item. In the example shown in Figure 76, it is a package having a receiving cavity.

In this embodiment, the air-packing device 100e includes at least one air-filling cushion body, that is, a three-dimensional packaging bag is formed by one of the air-filled cushion bodies, or a plurality of the air-filled cushioning bodies are formed by a plastic sealing connection such as bonding or heat sealing. The three-dimensional Packaging bag. In the example shown in Figs. 76 to 77 of the present invention, it is formed by one of the inflation cushion bodies. More specifically, referring to FIG. 77, the air cushion body includes at least two layers of

air chamber films

101e and 102e formed into a three-dimensional package including one or more connected gas storage units via a series of planar plastic sealing seams and three-dimensional plastic sealing seams. The bag, each of the gas storage units forms a gas storage chamber capable of storing gas.

It will be understood by those skilled in the art that the planar molding seam is used for plastically sealing a multilayer film to form a planar cushioning material for further molding the above-mentioned planar cushioning material to form the air-filled packaging device. The three-dimensional packaging device having a spatial stereo configuration and capable of accommodating the packaged article. The flat plastic sealing seam and the three-dimensional plastic sealing seam may be joined together by bonding or heat sealing connection. Preferably, in this embodiment, the flat plastic sealing seam and the three-dimensional plastic sealing seam may be Both are implemented as a heat seal process.

More specifically, the planar molding slit includes a plurality of rows of slits that divide the two layers of the

gas chamber films

101e and 102e into a plurality of the gas storage units. That is, preferably, each of the slits is formed by a heat sealing process which heat seals the two layers of the

plenum films

101e and 102e such that a row of the slits is formed between two adjacent gas storage units. The dividing slit may be a continuous heat sealing line such that a plurality of the gas storage units are independent of each other. The dividing slit may also be an intermittent heat sealing line such that a plurality of the gas storage units are in communication with each other. The gas storage unit may be in various shapes, such as strips, circles, polygons or other irregular shapes. As shown in FIG. 76, the gas cushion body of the present invention may include a plurality of inflatable columns arranged side by side, but Fang Ming is not restricted in this regard.

In this embodiment, referring to Fig. 77, the inflation cushioning body further includes an inflation valve formed of at least two layers of

valve membranes

103e and 104e, which form a one-way valve, and the valve membrane 103e of the inflation valve And 444e are disposed superposed on each other with the

plenum films

101e and 102e, and an intake passage for inflating the plenum is formed between the

valve films

103e and 104e. It is to be understood that the lengths of the

valve films

103e and 104e are shorter than the

plenum films

101e and 102e. When the air in the air reservoir is inflated through the intake passage and the air pressure in the air reservoir reaches a predetermined requirement, air pressure in the air reservoir acts on the

valve films

103e and 104e, so that The

valve membranes

103e and 104e are attached to one of the plenum membranes to close the intake passage so that the inflation valve functions as a one-way valve. When at least one of the intake passages is formed in each of the gas storage units, and each of the gas storage units is independent of each other, when one of the gas storage units is damaged and leaks, the other gas storage unit It will not be affected and will also have an air cushioning effect.

It can be understood that the

plenum films

101e and 102e of the inflation buffer body and the

valve films

103e and 104e of the inflation valve can be made of various suitable film materials, such as polyethylene film, poly. The present invention is not limited in this respect as long as it is a suitable flexible film, such as a propylene film, a polyvinyl chloride film, a polyester film, a polystyrene film or a composite film. It is worth mentioning that, in order to increase the one-way sealing effect, the

valve films

103e and 104e of the inflation valve may also be self-adhesive films modified by adding chemical components to the above-mentioned film.

The inflatable cushioning body further includes a main passage unit coupled to each of the gas storage units, preferably integrally extending from each of the gas storage units. More specifically, in this embodiment, the main channel unit is perpendicular to the direction in which the gas storage unit extends. The main passage unit forms a main passage, and the main passage has an inflation port, and when the position of the inflation port is provided with the inflation nozzle of the above-described inflation device of the present invention and performing an inflation operation, gas from the inflation port Entering the main passage, and re-entering each of the gas storage units, and after a predetermined gas pressure is reached in each of the gas storage chambers, the

valve films

103e and 104e of the inflation valve are attached to one of the

gas chambers Membrane

101e or 102e, thereby achieving self-sealing to prevent re-infiltration of the charged gas into the main passage.

The portable inflatable device of the present invention may be a hand-held inflatable device in the above air-filled packaging device When the 100e is transported to the place of use or at the origin of the logistics, the air-filled packaging device 100e needs to be inflated on site and the air-filled packaging device 100e is applied to the packaged articles to be packaged, and only the portable inflatable device of the present invention needs to be hand-held. The inflatable packaging device 100e is inflated, and the inflatable packaging device can be automatically closed after the inflation is completed. When the portable inflator is equipped with a self-charging battery, it can perform a charging operation on its self-charging battery when not in use, and in use, provide power supply to the battery, and drive corresponding components that generate air convection effects. Under the action, the inflation operation can be provided, thereby greatly facilitating the on-site inflation operation of the above-described air-packing device 100e.

Those skilled in the art will appreciate that each of the inflating devices of the various embodiments of Figures 36-77 can be used to inflate each of the inflatable cushions of Figures 1 through 35, in accordance with the present invention. Not limited to this.

Those skilled in the art should understand that the embodiments of the present invention described in the above description and the accompanying drawings are only by way of illustration and not limitation. The object of the invention has been achieved completely and efficiently. The present invention has been shown and described with respect to the embodiments of the present invention, and the embodiments of the present invention may be modified or modified without departing from the principles.

Claims

A packaging container having an air cushioning property, comprising: at least one packageable body and at least one inflatable packaging cushion body, wherein the package body is capable of forming at least one accommodating space, the inflatable package cushioning After the body is inflated, at least one receiving space can be formed, the inflatable packaging cushion body is connected to the inner side or the outer side of the packaging body, and when the inflatable packaging cushion body is in an uninflated state, the package body is in a folded state. When the inflatable package cushion is inflated, the package can be deployed.
The packaging container having air cushioning properties according to claim 1, wherein said inflatable packaging cushion is detachably fixedly coupled to an inner side or an outer side of said package by a snap or velcro.
The packaging container with air cushioning properties according to claim 1, wherein the inflatable packaging cushion is fixedly attached to the inside or the outside of the package by bonding or gluing.
A packaging container having air cushioning properties according to any one of claims 1 to 3, wherein the package is made of paper, plastic or composite material.
The packaging container with air cushioning performance according to claim 4, wherein the package body comprises at least six sides, including at least one first side edge, at least one second side edge, at least one third side edge, at least one a fourth side edge, at least one upper bottom surface, and at least a lower bottom surface, the first side edge, the second side edge, the third side edge, and the fourth side edge forming a side edge of the accommodating space, the upper bottom surface and The lower bottom surface is an upper bottom surface and a lower bottom surface of the accommodating space.
The packaging container with air cushioning performance according to claim 5, wherein the first side, the second side, the third side, and the fourth side are formed by folding and stitching, thereby sewing The place forms at least one seam.
A packaging container having air cushioning properties according to claim 6, wherein said package further comprises at least one overlapping edge, said overlapping edge being located at said stitching, and said overlapping edge and said side of said receiving space The edges coincide.
The packaging container with air cushioning performance according to claim 5, wherein said inflatable packaging cushion body is formed by at least one air cushioning body formed by three-dimensional plastic sealing, said inflatable packaging cushioning body further comprising at least one margin, The margin is located at the outer edge of the accommodation space shown.
A packaging container having air cushioning properties according to claim 8, wherein said inflatable package cushion body is fixed to said package body by fixing said margin to said overlapping side and said side of said package body Realized between the sides.
A packaging container having air cushioning properties according to any one of claims 1 to 3, wherein said inflatable packaging cushion body comprises a plurality of gas storage units, and at least one partition is disposed between each of said two gas storage units Sewing the gas storage unit separate.
A packaging container having air cushioning properties according to claim 10, wherein said inflatable is achieved by fixing said gas storage unit or said partitioning slit in said inflatable packaging cushion body to said packaging body. The packaging buffer is fixed to the package.
A packaging container having air cushioning properties according to claim 11, wherein said package body is opened by a side edge, an upper bottom surface or a lower bottom surface of said accommodation space for picking up an article.
A packaging container having air cushioning properties according to any one of claims 1 to 3, wherein said inflatable cushioning body comprises at least two layers of plenum film forming one or more gas storage units and at least two layers of valve film forming sheets To the inflation valve, and the inflatable cushion body forms at least one inflatable package after inflation.
A packaging container having air cushioning properties according to claim 13, wherein said inflatable cushioning body comprises a non-inflatable margin, said package body comprising a plurality of interconnected sides, said margin being bonded to said An edge between the sides or adjacent sides.
A packaging container having air cushioning properties according to claim 14, wherein said inflatable cushioning body is annular, and said margin that is not inflatable is bonded to an intermediate portion of said side edges.
A packaging container having air cushioning properties according to claim 14, wherein said non-inflatable margin is located at the bottom of said inflatable packaging cushion and bonded to the bottom of at least one of said sides of said package end.
A packaging container having air cushioning properties according to claim 16, wherein said non-inflatable margin is located at a portion of the film outside the bottom side boundary of said gas storage unit of said inflatable packaging cushion, or at least one The gas storage unit on the bottom side is molded to be inflated to form the margin.
A packaging container having an air cushioning property according to claim 13, wherein a part of said gas storage unit of said inflatable cushioning body or a partition between said adjacent gas storage units is bonded to said package.
A packaging container having an air cushioning property, comprising at least a first package body, at least one second package body and at least one inflatable package cushion body, wherein the first package body can form a first container a second package body capable of forming at least one second accommodating space, wherein the first package body is disposed in the second accommodating space of the second package body, the inflatable package cushion body Provided between the first package and the second package.
A packaging container having air cushioning properties according to claim 19, wherein said inflatable packaging cushion is detachably fixedly coupled to said first package by a snap or Velcro.
A packaging container having air cushioning properties according to claim 19, wherein said inflatable packaging cushion is fixedly attached to said first package by bonding or gluing.
A packaging container having air cushioning properties according to claim 19, wherein said inflatable packaging cushion is detachably fixedly coupled to said second package by a snap or Velcro.
A packaging container having air cushioning properties according to claim 19, wherein said inflatable packaging cushion is fixedly attached to said second package by bonding or gluing.
A packaging container having air cushioning properties according to claim 19, wherein said inflatable packaging cushion is bonded to said first package and said second package.
A packaging container having air cushioning properties according to any one of claims 21 to 24, wherein the first package and/or the second package are made of paper, plastic or composite material.
A packaging container having air cushioning properties according to claim 25, wherein said inflatable packaging cushion body comprises at least two layers of plenum membranes forming one or more gas storage units and at least two layers of valve membrane forming one-way inflation valves, And forming at least one inflatable package after inflation.
A packaging container having air cushioning properties according to claim 26, wherein said inflatable cushioning body comprises a non-inflatable margin, said first and second packages comprising a plurality of interconnected sides, said Edge bonded to the edge between the side edges or adjacent side edges.
A packaging container having an air cushioning property according to claim 26, wherein a part of said gas storage unit of said inflatable cushion body or a partition between adjacent said gas storage units is bonded to said package.
An inflation device for inflating at least one inflation buffer body, wherein the inflation buffer body comprises at least one gas storage unit and an inflation unit connected, the inflation passage has an inflation passage, and each of the reservoirs The gas unit has at least one gas storage chamber that is inflated through the inflation passage, the gasification unit surface is provided with at least one air inlet, and the inflatable device includes at least one handpiece including at least one inflation having at least one inflation port a mouth, wherein the inflation nozzle is adapted to be press-fitted to the inflation unit, and when there is a supply of gas, a gas is adapted to enter the air inlet through the inflation port of the inflation nozzle, via the inflation passage Each of the gas storage chambers is entered to complete an aeration operation of the inflation buffer.
The inflatable device according to claim 29, wherein said plurality of said inflatable cushioning bodies form at least one of said inflatable cushioning bodies, said inflatable device being adapted to continuously inflate said plurality of inflatable cushioning bodies.
The gas-filling apparatus according to claim 30, wherein each of said gas-filled cushion bodies is formed of said multi-layer film as said gas storage unit and said gas-filling unit, said gas inlet port being provided in one of said film forming said gas-filling unit .
The inflatable device according to claim 31, wherein each of said inflation cushioning bodies further comprises at least one inflation valve having a one-way backstop function, wherein gas entering said inflation passage enters said respective gas storage via said inflation valve After the chamber, the inflation valve is capable of preventing gas reverse osmosis.
The inflatable device according to claim 32, wherein said inflation cushion body comprises a two-layer plenum membrane, said inflation valve comprising at least two layers of valve membranes superposed and connected to two layers of said plenum membranes, two of At least one intake passage that inflates each of the gas storage chambers is formed between the valve membranes.
The inflatable device according to claim 33, wherein both ends of said inflation passage of each of said inflatable cushioning bodies are each closed by at least one inflation passage end seal such that said inflation passage passes only through said intake port and the outside The same.
An inflatable device according to any one of claims 30 to 34, wherein said handpiece further comprises at least one positioning cutter piercing at least two of said inflatable cushioning bodies in the top of said inflatable cushioning body .
An inflatable device according to claim 35, each of said inflatable cushioning bodies having at least one marginal region at the edge that does not affect sealing performance of said inflation passage and said reservoir, wherein said positioning cutter pierces said The marginal area.
The inflatable device according to claim 36, wherein said positioning cutter comprises at least one blade, or at least two blades disposed at a distance from each other.
The inflatable device according to claim 35, further comprising at least one bracket including a vertical strut, wherein said head is slidably disposed on said vertical strut, wherein said one of said inflatable cushions After being taken out, the handpiece slides downward by its own gravity and contacts the next one of the inflation cushions to inflate the next one of the inflation cushions.
The inflatable device according to claim 38, wherein said vertical strut of said bracket and said handpiece are slidably coupled by at least one slider and at least one slide rail that cooperate with each other.
38. The inflatable device of claim 38, further comprising at least one platform as at least one loading platform, wherein a plurality of said inflatable cushioning bodies are placed on said platform for said inflating operation.
The inflatable device according to claim 40, said bracket further comprising at least one lateral pedestal extending vertically from said lateral pedestal, wherein said platform is mounted or integrally formed in said lateral direction Base frame.
The inflatable device according to claim 40, further comprising one or more limiting means disposed on said platform for limiting said plurality of inflatable cushioning bodies to prevent a plurality of sputum The inflation buffer is misaligned, and the inflation port of the inflation nozzle is always corresponding to the position of the air inlet of each of the inflation buffers.
The inflatable device according to claim 42, wherein each of said inflatable cushioning bodies forms a plurality of said gas storage units by a plurality of dividing slits, wherein said outermost slits form a boundary slit, wherein said boundary slits are not The region is provided with one or more recesses, each of the limiting devices being respectively positioned at the recess to limit the inflatable cushioning body of the strand.
The airing device according to claim 43, wherein the limiting device comprises at least one limiting connection portion and at least one limiting cap extending from the limiting connecting portion, the limiting connecting portion being connected to the platform The limiting cap extends from the limiting connecting portion and protrudes outward, and the limiting cap has a size larger than a size of the recess.
The inflatable device according to claim 38, further comprising at least one locking device, said locking device being disposed on said bracket, said locking device having at least one locked state and at least one unlocked state, in said locked state The locking device prevents the handpiece from sliding down freely, and in the unlocked state, the handpiece can freely slide due to its own gravity.
The inflatable device according to claim 45, wherein said locking means comprises at least one fixing portion and at least one locking portion, said fixing portion being fixedly disposed to said vertical strut of said bracket, said fixing portion and said The locking portion is connected by at least one bolt, and the locking portion is capable of pivoting movement with the bolt as a central axis, and the bottom of the head when the locking portion is pivoted below the head It can be blocked by the top of the locking portion, preventing the head from being displaced downward to provide a feeding space for the inflatable cushioning body.
An inflation method for inflating at least one inflation buffer body, wherein the inflation buffer body includes at least one gas storage unit and an inflation unit connected, the inflation passage having at least one inflation passage Each of the gas storage units has at least one gas storage chamber that is inflated through the inflation passage, and the gasification unit surface is provided with an air inlet, and the inflation method includes the following steps:

(A) at least one inflation port of at least one inflator of at least one handpiece is aligned with the position of the air inlet of the inflation cushioning body;

(B) At the supply of the gas source, the gas enters the intake port via the inflation port, and then enters each of the gas storage chambers via the inflation passage to complete the inflation operation of the inflation cushion body.
The inflation method according to claim 47, further comprising the step of performing a continuous inflation operation on said plurality of inflatable cushioning bodies.
The inflation method according to claim 48, wherein in said step (A) of said inflation method, said inflation nozzle is press-fitted to said inflation unit of said inflation cushion.
The method of inflating according to claim 48, wherein in said step (A), the method further comprises the step of: feeding said inflatable cushioning body to and confining to at least one platform.
The method of inflating according to claim 50, wherein in said step (A), further comprising the step of: positioning means by one or more recesses disposed in said platform to be positioned in said recess of said inflatable cushioning body A plurality of the inflatable cushioning bodies are restrained.
The inflation method according to claim 49, wherein after the aforesaid said inflation cushioning body is inflated and taken away, said handpiece is displaced downward by its own weight and said inflation port of said inflation nozzle is lowered The air inlets of one of the air cushions are aligned in alignment to perform the charging operation on the next one of the air cushions.
The inflation method according to claim 52, wherein said handpiece is slidably disposed on at least one of the brackets.
The method of inflating according to claim 52, wherein at least one of the positioning cutters of the handpiece pierces at least two of the inflatable cushioning bodies of the top of the inflatable cushioning body of the weir.
The inflation method according to claim 52, wherein after the current one of said inflation cushions is inflated and taken away, said positioning cutter is displaced downwardly with said head to further pierce said shackles downward The inflatable cushion body.
The method of inflating according to claim 52, wherein said positioning tool comprises at least one blade or at least two blades spaced apart from each other.
The inflation method according to any one of claims 47 to 56, wherein each of said gas-filled cushion bodies is formed of said multi-layer film as said gas storage unit and said gas-filling unit, said gas inlet port being disposed to form said gas-filling unit One of the films.
The inflation method according to claim 57, wherein each of said inflation cushioning bodies further comprises at least one inflation valve having a one-way backstop function, wherein gas entering said inflation passage enters said respective gas storage via said inflation valve After the chamber, the inflation valve is capable of preventing gas reverse osmosis.
The inflation method according to claim 58, wherein said inflation cushioning body comprises a two-layer plenum membrane, said inflation valve comprising at least two layers of valve membranes superposed and connected to two layers of said plenum membranes, two of At least one intake passage that inflates each of the gas storage chambers is formed between the valve membranes.
The inflation method according to claim 58, wherein both ends of said inflation passage of each of said inflation cushion bodies are each closed by at least one inflation passage end seal such that said inflation passage passes only through said intake port and the outside The same.
The method of inflating according to claim 57, wherein each of said inflatable cushioning bodies, after inflation, forms at least one cushion or at least one three-dimensional package having an accommodation space therein.
An aerated cushioning body, characterized in that the aerated cushioning body comprises one or more gas storage units formed by at least two gas chamber membranes and two gas-filled end portions connected to each other and connected to the gas storage unit At least one inflatable unit, wherein a surface of one of the inflated ends of the inflator unit has at least one air inlet, and a gas is adapted to enter the inflation passage through the inflation port, and enter the corresponding gas storage unit through the intake passage .
The inflation cushioning body according to claim 62, further comprising at least one inflation valve which is a one-way check valve, said inflation valve opening to open said inflation valve to enter a corresponding said gas storage unit, and The inflation valve prevents backflow of gas back to the inflation passage.
The gas-filled cushioning body according to claim 63, wherein said inflation valve comprises a two-layer valve film laminatedly connected to said two-layer said gas chamber film, and two layers of said valve film are formed to inflate said gas storage unit One or more intake passages.
The inflation cushioning body according to claim 64, wherein said inflation passage is closed at both ends and communicates with the outside only through said intake port.
The inflation cushioning body according to any one of claims 62 to 65, wherein said inflation unit is formed by laminating two layers of said plenum film at portions corresponding to said inflation passages.
The gas-filled cushioning body according to claim 66, wherein the two layers of the gas chamber film are formed by folding a single film or two separate gas cell films and plastically connecting.
The inflation cushioning body according to any one of claims 64 to 65, wherein said inflation unit is formed by two layers of said valve film being superposed on portions corresponding to said inflation passages.
The gas-filled cushioning body according to claim 68, wherein the two layers of the valve film are formed by folding a single film or two separate valve films and plastically connected.
The inflation cushioning body according to any one of claims 62 to 65, wherein said inflation cushioning body is formed into a plurality of said gas storage units by a plurality of slits, wherein said outermost slit is said said inflation cushion The boundary seam of the body, and the outside of the boundary slit is formed with one or more recesses for limiting.
The inflation cushioning body according to any one of claims 62 to 65, wherein said inflation cushioning body is formed into a plurality of said gas storage units by a plurality of slits, wherein said outermost slit is said said inflation cushion A boundary seam of the body, and one or more positioning holes for the limit are formed outside the boundary slit.
The inflation cushioning body according to any one of claims 62 to 65, wherein a single of said inflation cushioning bodies are independently inflated, or a plurality of said inflation cushioning bodies are provided with said common inflation unit while being inflated.
The inflatable cushioning body according to claim 66, wherein said inflation cushioning body forms at least one inflatable cushion after inflation.
The inflatable cushioning body according to claim 66, wherein said inflatable cushioning body, after inflation, forms at least one three-dimensional packaging bag having an internal receiving space.
The inflatable cushioning body according to claim 68, wherein said inflation cushioning body forms at least one inflatable cushion after inflation.
The inflatable cushioning body according to claim 68, wherein said inflation cushioning body, after inflation, forms at least one three-dimensional packaging bag having an internal receiving space.
A method of manufacturing an aerated buffer body, the method of manufacturing comprising the steps of:

At least one first plenum membrane is perforated for forming at least one air inlet of the plenum; and

Arranging the first plenum membrane and a second plenum membrane and an inflation valve in a superposed manner, and forming the inflatable buffer body having at least one gas storage unit and at least one gasification unit through a series of heat seals, wherein The air inlet is formed in the airing unit, wherein when inflating, gas enters an inflation passage of the airing unit from the air inlet, and enters each of the gas storage units from the inflation passage via the inflation valve And the gas reverse osmosis is prevented by the one-way backstop function of the inflation valve.
A method of manufacturing a gas-filled cushion body according to claim 77, wherein said inflation valve comprises a two-layer valve film which is laminated and connected to said two-layer said gas chamber film, and two layers of said valve film are formed between said valve films One or more intake passages in which the gas unit is inflated.
A method of manufacturing a gas-filled cushion according to claim 78, wherein said inflation passage is thermally sealed by said first plenum membrane and said second plenum membrane through at least one inflatable passage edge slit, at least one edge And two inflatable channel end seals are formed by sealing each other.
A method of manufacturing an aerated buffer body, the method of manufacturing comprising the steps of:

At least one first valve membrane is perforated for forming at least one air inlet of the inflation cushioning body;

Arranging the first valve film and a second valve film, and the first and second plenum films in a superposed manner, and forming the at least one gas storage unit and the at least one gas-filling unit via a series of heat seals An inflation cushioning body, wherein the valve film and the first and second plenum membranes have a convex portion to form the inflation unit, wherein the air inlet is formed in the inflation unit, wherein inflating At the time, gas enters the inflation passage of the inflation unit from the intake port, and further enters each of the gas storage units from the inflation passage via the inflation valve.
A method of manufacturing an inflation cushion according to claim 80, wherein said inflation passage is formed by said first and said second plenum membranes passing through at least one inflation passage edge slit, at least one edge heat seal seam, and two inflation passages The end seals are formed by sealing each other.
An inflation method of an inflation buffer body, characterized in that the inflation buffer body comprises at least one gas storage unit and at least one gas inflation unit, the inflation passage has at least one inflation passage, and each of the gas storage units has a passage Said At least one gas storage chamber inflated by the inflation passage, the gasification unit surface is provided with at least one air inlet, wherein the inflation method comprises: after the gas supply, the gas enters the air inlet through the inflation port, and then The inflating operation of the inflation cushion body is completed by entering the respective gas storage chambers via the inflation passage.
A method of inflating an inflation cushion according to claim 82, wherein said inflation cushioning body further comprises at least one one-way inflation valve formed of at least two layers of valve membranes, such that after inflation is completed, said one-way inflation valve Automatic sealing prevents the gas of each of the gas storage chambers from being reverse osmosis to the gas passage.
A method of inflating an inflation cushion according to claim 83, wherein said inflation passages are closed at both ends, and communicate only with the outside through said intake port of the surface of the inflator unit, and the gas enters in a direction perpendicular to the surface of said inflator unit. The inflatable passage.
The inflation method of the inflation cushion body according to any one of claims 81 to 84, wherein the inflation unit is formed by superposing a two-layer air chamber film at a portion corresponding to the inflation passage.
The inflation method of the inflation cushion body according to any one of claims 63 to 84, wherein the inflation unit is formed by laminating two layers of valve films at portions corresponding to the inflation passages.
A method of inflating an inflation cushion according to any one of claims 81 to 84, wherein when a plurality of said inflation cushions are arranged one on another to form said air cushion body, further comprising the steps of: After the inflation treatment of the topmost side of the inflation cushioning body and removal, the next inflation cushioning body becomes the topmost side inflation cushioning body and continues to be continuously inflated.
A method of inflating an inflation cushion according to any one of claims 81 to 84, wherein said inflation cushion body forms at least one inflation cushion after inflation.
The inflation method of the inflation cushion body according to any one of claims 81 to 84, wherein the inflation cushion body forms at least one three-dimensional packaging bag having an internal accommodation space after inflation.
A portable inflatable device for inflating at least one device to be inflated, comprising:

At least one pump body;

At least one motor unit, the motor unit being disposed on the pump body for drawing the gas into the pump body when the motor unit is in operation;

At least one control unit coupled to the motor unit, the control unit controlling adjustment of the motor unit and being capable of switching the motor unit to at least one charge mode;

At least one gas nozzle connected to the pump body, and when the control unit manipulates the motor unit in the inflation mode, the gas reaches the gas nozzle via the pump body for performing inflation operating.
A portable inflatable device according to claim 90, further comprising at least one outer casing accommodating said pump body, said motor unit, said control unit and said air nozzle for forming a reduced structure.
A portable inflatable device according to claim 90, wherein said pump body comprises at least one air cylinder, said air cylinder being coupled to said motor unit and said air nozzle, said air cylinder having at least one first air port and at least a second a gas port, wherein the first gas port is connected to at least one first end of the motor unit, and the gas nozzle is connected to the second gas port of the gas cylinder, so that in the inflation mode, gas is passed through At least a second end of the motor unit enters the pump body from the outside of the portable inflator and is then filled into the interior of the device to be inflated via the air nozzle.
A portable inflatable device according to claim 90, wherein said control unit comprises at least one power control switch and at least one control circuit, said power control switch being connected to said control circuit, said control circuit being electrically connected to said Motor unit.
A portable inflatable device according to claim 93, further comprising at least one outer casing accommodating said pump body, said motor unit, said control unit and said air nozzle, said power control switch being disposed at said At least one outer surface of the outer casing for quickly switching the operation of the motor unit.
A portable inflatable device according to claim 93, wherein said control unit includes at least one pressure control switch, said pressure control switch being coupled to said control circuit for sensing said internal pressure of said gas cylinder.
A portable inflatable device according to claim 93, wherein said control unit includes at least one flow rate control switch, said flow rate control switch being coupled to said control circuit for controlling the amount of intake air of said portable inflatable device .
A portable inflatable device according to claim 96, further comprising at least one outer casing accommodating said pump body, said motor unit, said control unit and said air nozzle, said flow rate control switch being disposed at said At least one outer surface of the outer casing for easily switching the amount of intake air by the flow rate control switch.
A portable inflatable device according to claim 93, further comprising at least one outer casing accommodating said pump body, said motor unit, said control unit and said air nozzle, wherein said control unit comprises at least one display A component, the display component being coupled to the control circuit, the outer surface of the outer casing for displaying various associated values of the portable inflatable device via the display component.
A portable inflatable device according to claim 90, wherein said motor unit includes at least one driving member and at least one passive member, said passive member being coupled to said driving member, said control unit controlling said driving member to operate The passive component is driven by the driving component to generate an air intake effect.
A portable inflatable device according to claim 99, wherein said drive element is an electric motor and said passive element is a blade structure.
A portable inflatable device according to claim 90, wherein said motor unit of said portable inflator further has one or more vent openings through which gas enters said pump when said motor unit is in operation Inside the body.
A portable inflatable device according to any one of claims 90 to 101, further comprising at least one power supply unit connected to said control unit for supplying an electric energy to said control unit and said electric motor unit.
A portable inflatable device according to claim 102, wherein said power supply unit comprises at least one battery, said battery being a rechargeable battery or a disposable battery.
A portable inflatable device according to claim 102, wherein said portable inflatable device further comprises at least one heat sealing unit electrically connected to said control unit and for sealing at least one of the devices to be inflated via electrothermal conversion Inflated imports.
A portable inflatable device according to any one of claims 90 to 101, further comprising at least one hose connected between said air nozzle and said pump body.
A portable inflatable device for inflating at least one device to be inflated, comprising: at least one gas nozzle, at least one pump body, at least one solenoid valve unit, at least one piston, and at least one control unit, wherein the piston Provided inside the pump body and connected to the solenoid valve unit, the control unit controls the solenoid valve unit to drive the piston to move inside the pump body to generate at least one pressure difference, wherein the gas nozzle Connected to the pump body, when in the inflated mode, the gas is filled through the gas nozzle to the device to be inflated via the pressure difference.
A portable inflatable device according to claim 106, further comprising at least one power supply unit coupled to said control unit for providing control of said solenoid valve unit and said solenoid valve unit for driving said piston At least one electrical energy.
A portable inflatable device according to claim 106, further comprising at least one outer casing accommodating said pump body, said solenoid valve unit, said piston, said control unit and said air nozzle for The portable inflatable device forms a reduced structure.
A portable inflatable device according to claim 108, further comprising at least one power supply unit connected to said control unit and housed in said housing, wherein a part of said housing of said power supply unit is housed Forming at least one hand portion.
A portable inflatable device according to claim 108, wherein said outer casing has one or more flow vents for gas to circulate inside and outside of said portable inflatable device.
A portable inflatable device according to claim 106, wherein said pump body comprises at least one gas cylinder, at least one first two-way check valve and a second two-way check valve, said gas cylinder being connected to said gas nozzle, said A two-way check valve and a second two-way check valve are respectively disposed at both ends of the gas cylinder.
A portable inflatable device according to claim 111, wherein said gas cylinder has at least a first gas port and at least a second gas port, wherein said gas nozzle is connected to said second gas port of said gas cylinder, said first gas port At least one opening of the gas cylinder that enters and exits the pump body as gas, the first two-way check valve is disposed at the first gas port, and the second two-way check valve is disposed at the second gas port.
A method of inflating a portable inflatable device for rapidly inflating at least one device to be inflated, the device to be inflated being formed by at least two layers of air chamber membranes, comprising at least one check valve and having at least one inflation inlet, characterized in that The method of inflating the portable inflatable device includes the following steps:

Activating at least one motor unit to allow gas outside the portable inflatable device to enter the portable inflatable device;

Directing gas to at least one gas nozzle via at least one gas cylinder of at least one pump body;

The gas is introduced into the device to be inflated via the gas inlet of the device to be inflated through the gas nozzle, wherein the one-way valve is automatically closed at the end of the inflation.
A method of inflating a portable inflatable device according to claim 113, wherein at least one control unit operates the motor unit to operate, and at least one power supply unit supplies power to the control unit.
A method of inflating a portable inflatable device according to claim 113, wherein the motor unit comprises at least one driving element and at least one passive element connected to the driving element, wherein the driving element drives the passive element to operate to generate a flow of air pressure, wherein the driving The component is an electric motor and the passive component is a blade structure.