CN103662407A - Mouth blowing type aeroseal body - Google Patents

Abstract

The invention relates to a mouth-blown air sealing body, comprising: a first outer film and a second outer film stacked up and down; a first inner film and a second inner film, a plurality of heat-resistant materials, a first transverse heat-sealing line and The second transverse heat-sealing line, a plurality of vertical heat-sealing lines, a plurality of gas columns, a plurality of neck heat-sealing lines, an inflatable channel, a plurality of air inlets, and a plurality of heat-sealed blocks; among them, the gas expansion inflatable channel entering the inflatable port, The first outer film and the second outer film are stretched outward in a longitudinal direction and tightened in a transverse direction, and the first inner film and the second inner film are pressed through the heat-sealing block, so that the first inner film and the second inner film are The second inner film is coated with heat-resistant material and pulled outward in the longitudinal direction, and the first inner film and the second inner film are pulled outward in a longitudinal direction through a part of the neck heat-sealing line located at the heat-resistant material. The air inlet is opened to open, and after the gas enters the air column, it presses the second side of the first inner membrane or the second side of the second inner membrane to close the air column.

Description

A mouth-blown air seal

technical field

The invention relates to an air sealing body, in particular to a mouth-blown air sealing body.

Background technique

The air-sealed body is made of resin film, which is heat-sealed to form an air column in a sealed state, and is equipped with an inflation port for inflation. When the gas is filled into the air column through the inflation port, the air-sealed body can be used for inner packaging as a buffer material.

The structure of the conventional air sealing body, such as the Japanese Utility Model Application No. 5-95851 "Fluid Sealing Bag" patent case, is to set independent check valves on each air column, and the inflow port at the top of each check valve Aligned with the heat-sealing line and connected together, when the gas is filled into the inflatable channel, the inflatable channel expands to open the check valve, so that the gas can be filled into the gas column. However, due to the fact that each check valve is independent of each other in this structure, each air column is inflated separately, and multiple air columns cannot be inflated at the same time. Moreover, it is quite cumbersome to manufacture, and each check valve must be placed one by one. Heat sealing is carried out at the predetermined position in the air column. Once the position of the check valve or the position of the heat sealing mold is shifted, it will not be possible to fix the check valve in the air column, or the inlet at the top will exceed the heat sealing mold. The subsequent heat sealing line will cause the gas to be filled into the inflatable channel. Although the inflatable channel expands, the check valve cannot be opened with the expansion of the inflatable channel, resulting in that the gas cannot be charged into the air column.

Another air seal structure such as Taiwan Invention Patent No. 00587049 "The installation structure of the switch valve of the seal and the manufacturing device of the seal with the switch valve", wherein the switch for air entering the seal adopts two inner membranes and one The side outer membranes are connected to each other to form the passage of the switch valve. When inflated, the sealing body expands to block the passage. This switch valve only describes how to block the air in the sealing body from leaking out, but when the air is introduced into the channel, it will expand when it is filled with gas. , even if the two outer membranes are pushed apart by the gas, the on-off valve will not be pulled apart with the action of the two outer membranes, so the two inner membranes of the on-off valve are still attached together and cannot Open the air passage inlet, if it is designed according to its design, the air cannot automatically enter the sealing body.

Therefore, how to design a sealing body that allows users to easily inflate by mouth blowing, and can automatically open the air inlet to continuously inflate to save inflation time, and can automatically close the air when inflating, and automatically lock after the air is closed. Air, to keep the long-term air not leaking, is the technical problem that the inventor of this case and the technical field person engaged in this related industry need to face.

Contents of the invention

In view of this, the present invention provides a mouth-blown air seal, comprising:

Superimposed first and second adventitia;

a first inner membrane and a second inner membrane between the first outer membrane and the second outer membrane, the first inner membrane and the second inner membrane each comprising a first opposing side with a second side;

A plurality of heat-resistant materials coated between the first side of the first inner film and the first side of the second inner film;

The first transverse heat-sealing line and the second transverse heat-sealing line connect the sides corresponding to the sides of the first outer film and the second outer film together;

a plurality of straight heat seal lines following said first outer film, second outer film, first inner film and second inner film;

A plurality of air columns, each of the air columns is located between two adjacent straight heat-sealing lines, and is located between the first outer film and the second outer film;

A plurality of neck heat-sealing lines, located between the first transverse heat-sealing line and the second transverse heat-sealing line, each of the neck heat-sealing lines corresponds to one of the air columns, and part of the neck heat-sealing lines a line located at said plurality of heat-resistant materials;

An air-filled channel, the air-filled channel is formed by the space between the first transverse heat-seal line and the neck heat-seal line and within the first outer film and the second outer film, the air-inflatable The channel includes an air filling port into which gas can be filled;

A plurality of air inlets are formed at the plurality of heat-resistant materials to communicate with the plurality of air channels and the plurality of air columns;

A plurality of heat-sealed blocks, followed by the first outer film, the second outer film, the first inner film and the second inner film, are formed on the sides of each of the air inlets;

Wherein, the gas entering the inflation port expands the inflation channel, makes the first outer membrane and the second outer membrane stretch outward in a longitudinal direction and shrink in a transverse direction, and through the heat sealing The block squeezes the first inner film and the second inner film, so that the first inner film and the second inner film are coated with the heat-resistant material and pulled outward in the longitudinal direction, and pass through the Part of the neck heat sealing line drives the first inner film and the second inner film to open the air inlet as the first outer film and the second outer film are pulled apart in a longitudinal direction, and the gas enters the air column Compressing the second side of the first inner membrane or the second side of the second inner membrane closes the air column.

Further, each neck heat-sealing line includes:

The two first sections are respectively connected to the two adjacent straight heat-sealing lines;

Two second sections, respectively connected to the first section and extending away from the air column, at least a part of each second section is located on the first inner membrane and the second inner membrane Where said heat-resistant materials are applied; and

A third section, the two ends of which are respectively connected to the two second sections, located at the place where the first inner film and the second inner film are coated with the heat-resistant materials, and then the adjacent first outer film With the first inner membrane or adjacent second adventitia and second inner membrane.

Further, the first inner film and the second inner film are heat-sealed between the neck heat-sealing line and the second side to form a gas channel, and the gas channel includes:

A converging area, adjacent to the neck heat-sealing line and formed between the adjacent straight heat-sealing lines, one end of the converging area protrudes toward the inflation channel;

a lead area connected to said sink area; and

A diversion area connects the guide area and the second side, the diversion area includes a plurality of outlets, and the outlets are smaller than the connection between the diversion area and the guide area.

Further, the heat-sealed block includes at least one gas guiding part, located in the gas-charging channel, for guiding the gas in the gas-charging channel into the gas inlet.

Further, the heat-sealing block includes a positioning part connected to the air guiding part, and the air inlets are located on the side of the positioning part.

Further, the positioning part or the air guiding part is connected to the first sides of the first inner membrane and the second inner membrane and the first outer membrane and the second outer membrane.

Further, the upper and lower stacked first outer membrane and second outer membrane are sequentially divided into a first buffer air column part and a second buffer air column part along the axial direction of the air column, and the first buffer air column part and the second buffer air column part The buffer air column parts are connected to form an accommodating space for accommodating items.

Further, a belt is also included, connected with the first buffer gas column part and/or connected with the second buffer gas column part, and used to cover the opening of the accommodating space.

Further, the first buffer air column part includes a first fixed side and a first opening side, the first opening side is located at the opening of the accommodating space, and the first fixed side is located at the first buffer An end of the air column portion away from the first opening side.

Further, the second buffer air column part includes a second fixed side and a second opening side, the second opening side is located at the opening of the accommodating space, and the second fixed side is located at the second buffer At one end of the air column portion away from the second opening side, the second fixed side is fixedly connected to the first fixed side.

Further, the belt includes:

a fixed end connected to the first fixed side;

The positioning end can be fixed on the second buffer air column part, so as to cover the opening of the accommodating space.

Further, the positioning end is provided with an adhesive piece for fixing the positioning end on the second buffer air column part.

Further, the belt includes:

a fixed end connected to the second fixed side;

The positioning end can be fixed to the first buffer air column part, so as to cover the opening of the accommodating space.

Further, the positioning end is provided with an adhesive piece for fixing the positioning end on the first buffer gas column part.

Further, the length of the band is not shorter than the length of the first adventitia or the second adventitia in the transverse direction.

Further, the width of the band is shorter than or equal to the width of the first adventitia or the second adventitia.

Further, there are multiple belts, and the left and right sides of the two belts are heat-sealed together, and the bottoms of the two belts are connected to the first buffer gas column part and the second buffer gas column. The bottom of the column part is heat-sealed to form a bag enclosing the first buffer gas column part and the second buffer gas column part. The third belt includes a fixed end and a positioning end, and the fixed end is connected to the The first fixed side is connected or the second fixed side is connected, and the positioning end corresponding to the fixed end can be fixed to the second buffer gas column part or the first buffer gas column part, so that the The opening cover of the accommodating space, or one of the straps at the opening of the bag is provided with the positioning end.

The mouth-blown air sealing body of the present invention comprises: two outer films, stacked up and down; two inner films, interposed between the two outer films, each inner film includes a first side and a second side opposite to each other; thermal material, coated between the first sides of the two inner films; multiple transverse heat-sealing lines, followed by two sides of the two outer films; multiple vertical heat-seal lines, followed by the second outer film and the second inner film; multiple air columns , each air column is located between the two outer films of two adjacent straight heat-sealing lines; multiple neck heat-sealing lines are located between the transverse heat-sealing lines, and each neck heat-sealing line corresponds to an air column, which can be mainly determined by Two first sections, two second sections and a third section, wherein the two first sections are respectively connected to two adjacent straight heat-sealing lines, and the two second sections are respectively connected to the first section section, and extends away from the air column, at least a part of the second section is located at the two inner film coating heat-resistant materials, the third section connects the two second sections, and is located at the second inner film coating heat-resistant material material, and the neck heat-sealing line located at the place where the two inner films are coated with heat-resistant materials is connected to an adjacent piece of outer film and a piece of inner film; the inflation channel is located between one of the transverse heat-sealing lines and the neck heat-sealing line The space in the two outer membranes between the two outer membranes, and includes an inflation port that can be filled with gas; multiple air inlets, formed at the place where the two inner membranes are coated with heat-resistant materials, are used to connect the inflation channel and the gas column; and multiple heat seals The block is formed on the side of the air inlet by connecting the two outer films and the second inner film by means of heat sealing; wherein, the gas entering the inflation port expands the inflation channel, so that the two outer films are pulled outwards in the longitudinal direction and horizontally Tighten in the direction, squeeze the second inner film through the heat sealing block, make the second inner film coated with heat-resistant material pull outward in the longitudinal direction, and drive the second inner film along with the second outer film in the longitudinal direction through the third section Pull it outward in the direction to open the air inlet, and after the gas enters the air column, it presses the second side of the second inner membrane to close the air column.

The inflatable channel of the present invention is pre-heat-sealed at a predetermined position to form a heat-sealed block. When it is filled with gas and expands, the two outer membranes are pushed and pulled apart by the gas. Therefore, it is inflated to make the two outer films stretch outward in the longitudinal direction and tighten in the transverse direction, and when the two outer films are tightened in the transverse direction, the two inner films are squeezed with multiple heat-sealed blocks, so that the two inner films The coated heat-resistant material is squeezed in the horizontal direction to form a contraction, thereby opening the air inlet, and, in order to prevent the two inner membranes from being squeezed and shrinking in the same direction, causing the air inlet not to open, the present invention drives the two inner membranes through the third section. The inner membrane pulls outward along with the second outer membrane in the longitudinal direction, so that the second inner membrane is squeezed in the horizontal direction, and pulls outward along with the second outer membrane in the longitudinal direction, so as to ensure that the air inlet is automatically opened and inflated The gas in the channel can be filled into each air column through the plurality of air inlets, and after entering the air column, the gas presses the second side of the two inner membranes to seal the air column.

The preferred embodiments of the present invention and their effects are described as follows in conjunction with the drawings.

Description of drawings

1 is a three-dimensional schematic view of the first embodiment of the present invention after inflation;

Figure 2A is a plan view (1) of the first embodiment of the present invention before inflation;

Fig. 2B is a plan view (2) of the first embodiment of the present invention before inflation;

3A is a schematic cross-sectional view of FIG. 2B in direction D before inflation;

FIG. 3B is a schematic cross-sectional view of FIG. 2B in direction D after inflation;

4A is a schematic cross-sectional view of the first embodiment of the present invention after inflation;

Fig. 4B is a schematic cross-sectional view of Fig. 2B at A-A';

FIG. 5A is a schematic diagram (1) of a heat-sealing block according to the second embodiment of the present invention;

Fig. 5B is a schematic diagram (2) of the heat-sealing block of the second embodiment of the present invention;

6 is a schematic diagram of a heat-sealing block according to a third embodiment of the present invention;

Fig. 7 is a schematic front view (1) of the fourth embodiment of the present invention;

Fig. 8 is a schematic front view (2) of the fourth embodiment of the present invention;

Fig. 9 is a schematic front view (3) of the fourth embodiment of the present invention;

Fig. 10 is a schematic diagram of the appearance of a storage item according to a fourth embodiment of the present invention;

Fig. 11 is a schematic side view of a storage item according to a fourth embodiment of the present invention;

Fig. 12 is a schematic side view of the seal of the fourth embodiment of the present invention;

Fig. 13 is a schematic diagram of the appearance of the labeling of the fourth embodiment of the present invention;

Fig. 14 is a schematic diagram of the appearance of a storage item according to a fifth embodiment of the present invention;

Fig. 15 is a schematic side view of the closure of the fifth embodiment of the present invention.

[Description of main component symbols]

1......Air seal body

1a...........First Intima

1b..........Second intima

1c...Heat-resistant material

11......First side

12......Second side

14..........Gas channel

141......Convergence area

142........... Boot area

143....Diversion area

2a..........First adventitia

2b..........Second adventitia

2e..........Air inlet

3a..........The first transverse heat sealing line

3b...........Second transverse heat sealing line

3d...... Straight heat sealing line

4...........Entraining airway

5..Heat-sealed block

51......Air guide

52......Positioning Department

6..Air column

60......Opening

61..........The first buffer air column part

61a......First fixed side

61b......First opening side

62......Second buffer air column part

62a......Second fixed side

62b...................Second opening side

7...........Neck Heat Sealing Line

71......First segment

72......Second section

73..........The third section

8..... Drawstring

81...Fixed end

82......Positioning end

85......Adhesive parts

86......Label

9.......Inflatable channel

9a......Inflatable port

Detailed ways

Please refer to FIG. 1 , FIG. 2A , FIG. 2B , FIG. 3A , FIG. 3B , FIG. 4A and FIG. 4B , which are the first embodiment of the mouth-blown air sealing body of the present invention.

The mouth-blown air sealing body 1 of the present invention comprises: a first outer film 2a and a second outer film 2b, a first inner film 1a and a second inner film 1b, a heat-resistant material 1c, a first transverse heat-sealing line 3a and a second inner film Two transverse heat-sealing lines 3b, multiple vertical heat-sealing lines 3d, multiple neck heat-sealing lines 7, inflatable passages 9, multiple gas columns 6, and multiple heat-sealing blocks 5.

The first outer membrane 2a and the second outer membrane 2b overlap up and down.

The first inner membrane 1a and the second inner membrane 1b are interposed between the first outer membrane 2a and the second outer membrane 2b, and placed slightly lower on the top of the first outer membrane 2a and the second outer membrane 2b, the first inner membrane The width of the membrane 1a and the second inner membrane 1b is the same as that of the first outer membrane 2a and the second outer membrane 2b, and the length is shorter than that of the first outer membrane 2a and the second outer membrane 2b, the first inner membrane 1a and the second inner membrane 1 b each has a first side 11 and a second side 12 opposite to each other. In addition, a plurality of heat-resistant materials 1c (as shown in FIG. 2A ) are coated at intervals between the first side of the first inner film 1a and the first side 11 of the second inner film 1b, so that the heat-resistant materials 1c can be used as air circulation path.

Carry out heat-sealing by means of heat-sealing along the first transverse heat-sealing line 3a and the second transverse heat-sealing line 3b, so as to connect the two sides of the first outer film 2a and the second outer film 2b, and heat seal along the neck The line 7 is heat-sealed by heat-sealing means, so as to connect the first outer film 2a and the second outer film 2b and the first inner film 1a and the second inner film 1b. Therefore, heat sealing between the first transverse heat-sealing line 3a and the neck In the first outer membrane 2 a and the second outer membrane 2 b between the sealing lines 7 , an inflatable channel 9 through which gas can flow is formed, and an inflatable port 9 a is formed at one end of the inflatable channel 9 . Heat-sealing is carried out by means of heat-sealing along the plurality of vertical heat-sealing lines 3d, so as to connect the first outer film 2a and the second outer film 2b to form a plurality of air columns between the first outer film 2a and the second outer film 2b 6. After the heat-resistant material 1c is coated between the first inner film 1a and the second inner film 1b, a plurality of air inlets 2e are formed at the junction of the neck heat seal line 7 through heat sealing means, and each air inlet 2e corresponds to For each air column 6, the first inner membrane 1a and the second inner membrane 1b form a continuous air valve capable of inflating multiple air columns 6 at the same time.

Here, the neck heat-sealing line 7 is a roughly arc-shaped curve, protruding from the air column 6 toward the direction of the inflatable channel 9 (as shown in Figure 2A), and each neck heat-sealing line 7 corresponds to an air column 6, And it can be mainly composed of two first sections 71 , two second sections 72 and a third section 73 (as shown in FIG. 2B ). Wherein, the two first sections 71 are respectively connected to the two adjacent straight heat-sealing lines 3d; Part of the first inner film 1a and the second inner film 1b are coated with the heat-resistant material 1c, in other words, at least a part of the second section 72 is coated with the first inner film 1a and the second inner film 1b with the heat-resistant material 1c is superimposed; the third section 73 connects the two second sections 72, and is located at the place where the first inner film 1a and the second inner film 1b are coated with heat-resistant material 1c. On the whole, the third section 73 is located in an arc shape at the apex of the curve.

Special attention should be paid to: the neck heat seal line 7 at the place where the first inner film 1a and the second inner film 1b are coated with the heat-resistant material 1c will be adjacent to the first outer film 2a and the first inner film 1a, the second The two outer films 2b and the second inner film 1b, the first inner film 1a and the second inner film 1b are not bonded at the heat-resistant material 1c. The neck heat-sealing line 7 will be connected to the first outer film 2a and the second outer film 2b and the first inner film 1a and the second inner film 1b at the place where the heat-resistant material 1c is not coated, in other words, the neck heat-sealing line 7 Four pieces of film will be followed at the same time where the heat-resistant material 1c is not coated.

Continue to heat seal the first outer film 2a and the second outer film 2b and the first inner film 1a and the second inner film 1b to form a plurality of heat-sealed blocks 5 at predetermined positions on the sides of the plurality of air inlets 2e, Here, the heat-sealing block 5 is generally in the shape of a strip, a part of which is located in the inflatable passage 9, and a part is located in the air column 6 (as shown in Figure 2B). In addition, two adjacent heat-sealing blocks 5 are formed between There is an air-inducing channel 4, and the air-inducing channel 4 is located between the first intima 1a and the second intima 1b and is connected to the air inlet 2e (as shown in Figure 4A and Figure 4B). The heat-sealing block 5 is generally in the shape of a mountain, and the air-entraining channel 4 is generally in the shape of a valley.

When in use, the user only needs to blow air at the inflation port 9a. When the gas entering the inflation port 9a expands the inflation channel 9, the first outer membrane 2a and the second outer membrane 2b are pulled apart in the longitudinal direction. The first outer membrane 2a and the second outer membrane 2b expand from a flat state to a three-dimensional shape with a radian (as shown in Figure 3A), because the place where the heat-sealing block 5 is not set will expand due to inflation, and the heat-sealing block 5 is set It will not be inflated and expanded, so the inflatable channel 9 is compressed in the lateral direction due to the natural drop when inflated (as shown in Figure 3B), so that the first outer membrane 2a and the second outer membrane 2b forming the inflatable channel 9 are tightened. Displacement is generated in the lateral direction to use the heat-sealing block 5 to squeeze the first inner film 1a and the second inner film 1b, and drive the first inner film 1a and the second inner film 1b along with the first inner film 1b through the third section 73 The outer membrane 2a and the second outer membrane 2b are pulled apart in the longitudinal direction, so as to automatically open the air inlet 2e (as shown in Figure 4A and Figure 4B), that is, the heat-sealing block 5, which is roughly in the shape of a mountain peak, is in the shape of a valley. The air-inducing duct 4 is squeezed, and the first inner membrane 1a and the second inner membrane 1b are pulled apart in the longitudinal direction along with the first outer membrane 2a and the second outer membrane 2b through the third section 73, so that The first inner film 1a and the second inner film 1b of the air-introduction channel 4 are pulled apart, so that the first inner film 1a and the second inner film 1b are pre-coated with a heat-resistant material 1c and then heat-sealed to form a gap that is naturally squeezed open.

Since the air inlet 2e is automatically opened, one inflation channel 9 can inflate a plurality of air columns 6 at the same time, and there is no need to inflate each air inlet 2e after positioning, which can save inflation time, and because each air column 6 is independent of each other, some air columns 6 Damage will not affect the overall cushioning effect of the air-tight body 1 . In addition, the user only needs to blow air at the inflation port 9a to inflate each air column 6 without using a high-pressure inflator, which makes the inflation operation simpler and more convenient.

After the filling gas enters the gas column 6 through the air-inducing channel 4 and the gas inlet 2e, the internal pressure of the gas in the gas column 6 presses the second side 12 of the first inner membrane 1a and the second inner membrane 1b, making the first inner membrane 1a and the second inner membrane 1b are attached together to seal the gas column 6 so that the gas does not leak out and achieves the effect of holding breath. Here, the first inner membrane 1a and the second inner membrane 1b are suspended in the air column 6 by the pressure of the gas, or the first inner membrane 1a and the second inner membrane 1b can be connected with the first outer membrane 2a or the second outer membrane. The membrane 2b is next to each other. After gas enters the air column 6, the first inner membrane 1a and the second inner membrane 1b are attached to the first outer membrane 2a or the second outer membrane 2b to close the air column 6 .

Please refer to FIG. 2B , in some embodiments, the gas channel 14 can be formed on the first inner film 1 a and the second inner film 1 b by means of heat sealing. Here, the first inner film 1a and the second inner film 1b are heat-sealed between the neck heat-sealing line 7 and the second side 12 to form a gas channel 14, and the gas channel 14 can be mainly composed of the converging area 141, The guide area 142 and the diversion area 143 are formed. Wherein, the converging area 141 is adjacent to the neck heat sealing line 7, and is formed between two straight heat sealing lines 3d, and one end of the converging area 141 protrudes to the inflatable channel 9; the guiding area 142 is connected to the converging area 141, and More than one path can be provided for gas flow; the diversion area 143 connects the guide area 142 and the second side 12, and the diversion area 143 has a plurality of paths, the number of which is greater than the number of paths provided by the guide area 142, and , each path of the diversion area 143 has an outlet 143a, and the outlet 143a is smaller than the junction of the diversion area 143 and the guide area 142 . Therefore, when the gas enters the gas channel 14 from the gas inlet 2e, it first gathers in the converging area 141 , then flows to the diverging area 143 through the path provided by the guiding area 142 , and then enters the gas column 6 along the diverging area 143 . Since the outlet 143a is smaller than the junction of the diverting area 143 and the guiding area 142, the gas in the gas column 6 will not flow back through the outlet 143a to cause gas leakage.

Please refer to FIG. 5A and FIG. 5B , which are the second embodiment of the mouth-blown air sealing body of the present invention.

In this embodiment, the heat-sealing block 5 can be provided with an air guiding part 51, wherein the air guiding part 51 has 3b) is a gradually expanding plane or arc, and it is arranged in the inflatable channel 9. When the gas entering the inflatable port 9a expands the inflatable channel 9, the gas in the inflatable channel 9 can be guided by the gas guide part 51 Enter the bleed air channel 4 and the air inlet 2e to effectively increase the inflation rate.

Please refer to FIG. 6 , which is a third embodiment of the mouth-blown air sealing body of the present invention.

In this embodiment, the heat-sealing block 5 can be connected to the elongated positioning portion 52 at the bottom of the air guiding portion 51 . Here, the positioning portion 52 is connected to the first side 11 of the first inner film 1a and the second inner film 1b and the first outer film 2a and the second outer film 2b, and the second transverse heat-sealing line 3b is located in the positioning portion 52 And the air inlet 2e is located at the side of the positioning portion 52 . Therefore, even if the position of the first inner film 1a and the second inner film 1b or the heat-sealing mold deviates and does not fall out of the positioning portion 52 during the manufacturing process, the first inner film 1a can still be heat-sealed along the second transverse heat-sealing line 3b. The inner membrane 1a, the second inner membrane 1b, the first outer membrane 2a, and the second outer membrane 2b do not affect the structure of the air inlet 2e and its inflation function, and solve the problem that the conventional sealing body cannot be inflated after heat sealing due to the position deviation of the air valve. And other issues.

In addition, in the present invention, the air guide part 51 can be connected to the first side 11 of the first inner film 1a and the second inner film 1b and the first outer film 2a and the second outer film 2b, and the heat sealing line 3b is located at the air guide part 51 and at the top end of the non-air guide part 51, the air inlet 2e is located on the side of the air guide part 51.

The above-mentioned air column 6 can be connected with an air inlet 2e or a plurality of air inlets 2e, and each air inlet 2e can be further connected with a gas channel 14 or connected with a plurality of gas channels 14, and between each air column 6 can be They are connected, and can further share one gas channel 14 or share a plurality of gas channels 14 .

Please refer to FIG. 7 and FIG. 8 , which are the fourth embodiment of the mouth-blown air sealing body of the present invention.

The plurality of gas columns 6 are arranged adjacently in sequence in the arrangement direction X, and are divided into a first buffer gas column part 61 and a second buffer gas column part 62 in the longitudinal direction Y of the plurality of gas columns 6 . Here, the first buffer air column part 61 has a first fixed side 61a and a first opening side 61b, and the first fixed side 61a and the first opening side 61b are located at two sides of the first buffer air column part 61 in the arrangement direction X. end; the second buffer air column part 62 has a second fixed side 62a and a second open side 62b, and the second fixed side 62a and the second open side 62b are located at the two ends of the second buffer air column part 62 in the arrangement direction X .

The belt 8 has a fixed end 81 and a positioning end 82, wherein the fixed end 81 is fixed to the first fixed side 61a of the first buffer gas column part 61, and the length of the belt 8 is not shorter than the first buffer gas column part 61 The length in the alignment direction, in this embodiment, the length of the belt 8 is the same as the length of the first air cushioning column portion 61 in the alignment direction. For the purpose of waterproofing, the strap 8 can also be made of other waterproof materials. In addition, the strap 8 may be provided with an adhesive member 85 at the positioning end 82 , such as glue, Velcro, etc., but the present invention is not limited thereto.

Please continue to refer to Figure 7 and Figure 8, after the air column sheet is bent, the first buffer air column part 61 and the second buffer air column part 62 are superimposed, and the first buffer air column part 61 and the second buffer air column part 61 are heat-sealed. The non-communicating side of the air column portion 62 is heat-sealed to the first fixed side 61a and the second fixed side 62a so that they are fixed together, so that the first opening side 61b and the second opening side 62b enclose the opening 60 .

Please refer to Fig. 9, after the air column sheet is inflated by the inflation method as mentioned above, the air columns 6 of the first buffer air column part 61 and the second buffer air column part 62 are inflated and expanded, and the laminated sheet in the uninflated state shape (as shown in Figure 2A) becomes a three-dimensional columnar shape in an inflated state (as shown in Figure 4A), in other words, the first outer membrane 2a and the second outer membrane 2b are stretched outward due to inflation and become a three-dimensional shape, The lengths in the arrangement direction of the first buffer air column portion 61 and the second buffer air column portion 62 are shortened. Because the belt 8 is a sheet structure, its length remains unchanged after the air column sheet 2 is inflated, but because the length of the first buffer air column part 61 and the second buffer air column part 62 in the direction of arrangement is shortened, the air column sheet 2 is inflated and expanded. state, the length of the belt 8 in the arrangement direction will be longer than the length of the first buffer air column portion 61 or the second buffer air column portion 62 .

Please refer to FIG. 10 , the air column sheet forms a bag body, and there is an accommodating space between the first buffer air column part 61 and the second buffer air column part 62 for accommodating the article 100 . Please refer to Fig. 10, Fig. 11, Fig. 12 and Fig. 13, when the user puts the article 100 between the first buffer gas column part 61 and the second buffer gas column part 62, the belt 8 is pulled from the first buffer gas column part 62. The buffer air column part 61 is wound around the second buffer air column part 62, so that the adhesive part 85 of the strap 8 attaches its positioning end 82 to the second buffer air column part 62, thereby covering the opening 60 and preventing the article 100 from being released from the second buffer air column part 62. A buffer air column part 61 and the second buffer air column part 62 are disengaged.

It should be noted that, as shown in FIG. 12 , when the user utilizes the strap 8 for packing, the strap 8 is tightened so that the top ends of the first buffer gas column portion 61 and the second buffer gas column portion 62 ( The end close to the opening 60) is closely fitted together, therefore, the air column 6 will tightly cover the article 100, which can effectively prevent the article 100 from being trapped between the first buffer air column part 61 and the second buffer air column part 62 during transportation. In other words, with the size of the article 100, the strap 8 can be adjusted to stick to different positions to tighten the first buffer air column part 61 and the second buffer air column part 62, so that the air column 6 Items 100 of different sizes can be tightly wrapped to improve the convenience of sending without changing the size of the mailing envelope because of the different sizes of the items.

In some implementations, a label 86 can be provided on the strap 8, and the user can write, print or print the recipient information and sender information on the label, or record shipping precautions for delivery.

Please refer to FIG. 14 and FIG. 15 , in some embodiments, a plurality of belts 8 can be provided on the side of the air column 6, and a bag is formed by the plurality of belts 8, so as to put the object 100 into the first Between the buffer air column part 61 and the second buffer air column part 62 . In other words, the position of the belt 8 can be adjusted according to different structures.

The above is a preferred embodiment of the present invention, it should be pointed out that for those skilled in the art, without departing from the principle of the present invention, some improvements and modifications can also be made, and these improvements and modifications should also be regarded as The protection scope of the present invention.

Claims (17)

1. A mouth-blown air seal, characterized in that it comprises: Superimposed first and second adventitia; a first inner membrane and a second inner membrane between the first outer membrane and the second outer membrane, the first inner membrane and the second inner membrane each comprising a first opposing side with a second side; A plurality of heat-resistant materials coated between the first side of the first inner film and the first side of the second inner film; The first transverse heat-sealing line and the second transverse heat-sealing line connect the sides corresponding to the sides of the first outer film and the second outer film together; a plurality of straight heat seal lines following said first outer film, second outer film, first inner film and second inner film; A plurality of air columns, each of the air columns is located between two adjacent straight heat-sealing lines, and is located between the first outer film and the second outer film; A plurality of neck heat-sealing lines are located between the first transverse heat-sealing line and the second transverse heat-sealing line, each of the neck heat-sealing lines corresponds to one of the air columns, and some of the neck heat-sealing lines are located the plurality of heat-resistant materials; An air-inflating channel, the space between the first transverse heat-sealing line and the neck heat-sealing line and in the first outer film and the second outer film forms the air-inflating channel, the air-inflating channel Contains an inflation port into which gas can be charged; A plurality of air inlets are formed at the plurality of heat-resistant materials to communicate with the plurality of air channels and the plurality of air columns; A plurality of heat-sealed blocks, followed by the first outer film, the second outer film, the first inner film and the second inner film, are formed on the sides of each of the air inlets; Wherein, the gas entering the inflation port expands the inflation channel, makes the first outer membrane and the second outer membrane stretch outward in a longitudinal direction and shrink in a transverse direction, and through the heat sealing The block squeezes the first inner film and the second inner film, so that the first inner film and the second inner film are coated with the heat-resistant material and pulled outward in the longitudinal direction, and pass through the Part of the neck heat sealing line drives the first inner film and the second inner film to open the air inlet as the first outer film and the second outer film are pulled apart in a longitudinal direction, and the gas enters the air column Compressing the second side of the first inner membrane or the second side of the second inner membrane closes the air column. 2. A mouth-blown air seal according to claim 1, wherein each neck heat-sealing line comprises: The two first sections are respectively connected to the two adjacent straight heat-sealing lines; Two second sections, respectively connected to the first section and extending away from the air column, at least a part of each second section is located on the first inner membrane and the second inner membrane Where said heat-resistant materials are applied; and A third section, the two ends of which are respectively connected to the two second sections, located at the place where the first inner film and the second inner film are coated with the heat-resistant materials, and then the adjacent first outer film With the first inner membrane or adjacent second adventitia and second inner membrane. 3. A mouth-blown air seal according to claim 1, wherein the first inner film and the second inner film are heated between the neck heat-sealing line and the second side. Sealed to form a gas channel, the gas channel comprising: A converging area, adjacent to the neck heat-sealing line and formed between the adjacent straight heat-sealing lines, one end of the converging area protrudes toward the inflation channel; a lead area connected to said sink area; and A diversion area connects the guide area and the second side, the diversion area includes a plurality of outlets, and the outlets are smaller than the connection between the diversion area and the guide area. 4. A mouth-blown air-sealed body according to claim 1, wherein the heat-sealing block comprises at least one air guiding part, which is located in the air-inflating channel and is used to guide the air-inflating channel The gas enters the gas inlet. 5. A mouth-blown air sealing body according to claim 4, wherein the heat-sealing block comprises a positioning part connected to the air guiding part, and the air inlets are located at the positioning part. side of the department. 6. A mouth-blown air seal according to claim 5, characterized in that, the positioning part or the air guiding part is connected to the first sides of the first inner film and the second inner film with the first and second adventitia. 7. A mouth-blown air sealing body according to claim 1, characterized in that the upper and lower superimposed first outer membrane and second outer membrane are sequentially divided into first buffer gas along the axial direction of the air column. The column part and the second buffer gas column part, the first buffer gas column part and the second buffer gas column part are connected to form an accommodating space for accommodating articles. 8. A mouth-blown air-tight body according to claim 7, characterized in that it further comprises a band connected to the first buffer gas column part and/or connected to the second buffer gas column part The connection is used to cover the opening of the accommodating space. 9. A mouth-blown air sealing body according to claim 8, characterized in that, the first buffer gas column part comprises a first fixed side and a first opening side, and the first opening side is located on the At the opening of the accommodating space, the first fixed side is located at an end of the first buffer air column part away from the first opening side. 10. A mouth-blown air sealing body according to claim 9, characterized in that, the second buffer air column part includes a second fixed side and a second opening side, and the second opening side is located at the At the opening of the accommodating space, the second fixed side is located at an end of the second buffer air column part away from the second opening side, and the second fixed side is fixed to the first fixed side connect. 11. A mouth-blown air seal according to claim 10, wherein the strap comprises: a fixed end connected to the first fixed side; The positioning end can be fixed on the second buffer air column part, so as to cover the opening of the accommodating space. 12. A mouth-blown air sealing body according to claim 11, characterized in that, the positioning end is provided with an adhesive piece for fixing the positioning end on the second buffer air column part . 13. A mouth-blown air seal according to claim 10, wherein the strap comprises: a fixed end connected to the second fixed side; The positioning end can be fixed to the first buffer air column part, so as to cover the opening of the accommodating space. 14. A mouth-blown air sealing body according to claim 13, characterized in that, the positioning end is provided with an adhesive piece for fixing the positioning end on the first buffer air column part . 15. A mouth-blown air sealing body according to any one of claims 10-14, characterized in that, the length of the strap is not shorter than that of the first outer film or the second outer film on the The length in the horizontal direction. 16 . The mouth-blown air sealing body according to claim 10 , wherein the width of the band is shorter than or equal to the width of the first outer film or the second outer film. 17 . 17. A mouth-blown air sealing body according to claim 10, characterized in that, there are multiple straps, wherein the left and right sides of the two straps are heat-sealed together by themselves, and the two straps The bottoms of the first buffer gas column and the bottom of the second buffer gas column are heat-sealed to form a bag enclosing the first buffer gas column and the second buffer gas column. Each of the straps includes a fixed end and a positioning end, the fixed end is connected to the first fixed side or the second fixed side, and the positioning end corresponding to the fixed end can be fixed to the The second buffer air column part or the first buffer air column part is used to cover the opening of the accommodating space, or one of the straps at the opening of the bag body is provided with the positioning end.

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