TW201121848A - Continuous inflation type airtight body and manufacturing method thereof. - Google Patents

Abstract

This invention relates to a continuous inflation type airtight body, which a plurality of channel bonding parts are used to bond two inner films to form a plurality of air channels; a plurality of heat sealing wire are used to bond a first outer film, a second outer film, and two inner films along a first direction; and two second heat sealing wires are used to bond along a second direction intersected with the first direction, wherein one of the second heat sealing wire bonds the first outer film and the second outer film, and the other second heat sealing wire is located at a heat insulation member and bonds the first outer film and the adjacent inner film, and the second outer film and the adjacent inner film, making two inner films not bonded at the location of the second heat sealing wire to form a plurality of air inlets, and making the spaces between the first outer film, the second outer film, and two inner films bonded by the plurality of first heat sealing wires and the plurality of second heat sealing wires to form into a plurality of air columns. The air flows into the plurality of air channels through the plurality of air inlets to be filled into the plurality of air columns to inflate. After the air enters the air column, one end of the two inner films are pressed to be adhered to each other to seal the air column, and the other end of the two inner films are separated to form a gap.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air seal body and a method of manufacturing the same, and more particularly to a continuously inflated air seal body and a method of manufacturing the same. [0002] [Previous Art] The air sealing body is made of a resin film and is formed into a gas column by heat sealing to form a gas column, and is provided with an inflation port which can be inflated, and when the gas is charged into the air column through the inflation port, the air The sealing body can be used as a cushioning material in the inner package. The conventional air-sealed body structure, such as the utility model, is disclosed in the patent application No. 5-95851, "The Sealing Bag for Fluids" patent, which is provided with independent check valves for each gas column, and the flow at the top of each check valve. The inlet is aligned with the heat seal line and then joined together. When the gas is filled into the inflation passage, the inflation passage expands to open the check valve, allowing gas to be charged into the gas column. However, since the respective check valves are independent of each other, the gas cylinders are each inflated, and it is impossible to simultaneously inflate a plurality of gas columns at the same time. Further, it is quite cumbersome in manufacturing, and it is necessary to place each check valve The heat sealing is performed at a predetermined position in the gas column. Then, once the check valve placement position or the heat sealing mold is followed by the positional deviation, the check valve cannot be fixed in the gas column, or the top inlet is beyond the heat sealing mold. Then, the heat sealing line will cause the gas to be filled into the inflation passage, and although the inflation passage expands, the check valve cannot be opened with the expansion of the inflation passage, and the gas cannot be charged into the air column. Another type of air-sealed body structure is, for example, the Republic of China Patent No. 00587049 "Installation structure of an opening and closing valve for a sealing body and a manufacturing device for a sealing body having an opening and closing valve", wherein a switch for the air entering the sealing body 099131420 uses two inner membranes and One side of the outer membrane then forms a path for the switching valve, Form No. A0101 Page 3 of 45 0992055060-0 201121848 When inflated, the sealing body expands to block the passage. This switching valve only describes how to block the air resistance of the sealing body. It does not leak, but when the air introduction passage is filled with gas and expands, even if the two outer membranes are pushed outward by the gas, the on-off valve does not pull outwards as the two outer membranes move, so The two inner membranes of the on-off valve are still attached together and cannot open the air passage inlet. According to the design, air cannot automatically enter the sealing body. In addition, in the conventional air sealing body, the inlet port of the check valve tip is narrow and its width is smaller than the width of the air column. Therefore, when inflating, the inflator must be aligned with the air inlet port, which is inconvenient for inflation work. Too small an air inlet structure will result in poor inflation efficiency. Therefore, how to design a sealing body, which can automatically open the air inlet and continuously inflate to save the inflation time, avoid the problem of incomplete inflation, and effectively improve the inflation efficiency, which is the inventor of the case and engaged in the related industries. Technical issues that the technical field needs to face. SUMMARY OF THE INVENTION [0003] In view of this, the present invention provides a continuous inflatable air sealing body, comprising: a first outer film; a second outer film and a first outer film; two inner film, between the first Between the outer membrane and the second outer membrane; a plurality of channel followers located on one side of the inner membrane followed by a second inner membrane; a plurality of gas passages located between the second inner membrane of the plurality of channels; Located between the two inner membranes; a plurality of first heat seal lines, followed by a first outer film, a second outer film, and two inner films along a first direction; and a second heat seal line along a second direction intersecting the first direction Next, one of the second heat seal lines is followed by the first outer film and the second outer film, and the other second heat seal line is located at the heat insulating member, and then the first outer film and the adjacent inner film and the second outer film are Adjacent inner membrane; a plurality of air inlets formed by the two inner membranes not adjacent to each other at the second heat seal line, connected to form number A0101, page 4 / total 45 pages 0992055060-0 201121848 plural gas passages, each into The width of the gas port is the same as the width of the adjacent two first heat seal lines; and a plurality of air columns are located between the first outer heat seal line and the first outer heat seal line, the first outer film, the second outer film and the second inner film, and the inner film is opened outward to open the plurality of air inlets. The gas flows into the plurality of gas passages through the plurality of gas inlet ports, and is filled into the plurality of gas columns to inflate and expand. After the gas enters the gas column, one end of the inner membrane is pressed to close the gas column, and the other end of the inner membrane is separated to form a gap. The invention also provides a method for manufacturing a continuous inflatable air sealing body, comprising the steps of: providing a first outer film and a second inner film; the inner film of the inner film has a heat insulating member; the heat sealing is followed by the inner film and the first outer film. Forming a plurality of channel followers, and forming a plurality of gas channels between the second inner membranes of the plurality of channels; providing a second outer film, overlapping the first outer film to make the second inner film first Between the film and the second outer film; a plurality of first heat seal lines along the first direction followed by the first outer film, the second outer film and the second inner film; and a second heat in a second direction intersecting the first direction The sealing line is followed by wherein V.. | a second heat sealing line is followed by the first outer film and the second outer film, and the second heat sealing line of Qinyi is located at the heat insulating member, and then the first outer film and the adjacent inner film a second outer () film and an adjacent inner film, the two inner films are not adjacent to each other at the second heat seal line to form a plurality of air inlets, each of the air inlets having the same width as the adjacent two first heat seals The width of the line spacing, and the first of the plurality of first heat seal lines and the plurality of second heat seal lines a plurality of gas columns are formed between the second outer membrane and the inner membrane; and the inner membrane is opened outward to open the plurality of gas inlets, and the gas flows into the plurality of gas passages through the plurality of gas inlet ports, and is filled with the plurality of gas cylinders to inflate After the gas enters the gas column, one end of the inner membrane is pressed to close the gas column, and the other end of the inner membrane is separated to form a gap. The preferred embodiment of the present invention and its effects are described in conjunction with the drawings. 099131420 Form No. A0101 Page 5 of 45 0992055060-0 201121848 As explained later. [Embodiment] [0004] 099131420 Please refer to FIG. 1, FIG. 2A, FIG. 2B, FIG. 2C®, FIG. 3, FIG. 4 and FIG. 5 for the continuous inflatable air sealing body of the present invention. First embodiment. The continuous inflatable air sealing body 1 of the present invention comprises: a first outer film 2& and a first outer film 2b, two inner 臈ia and ib, a plurality of channel end portions 5, a gas passage 2f, and a plurality of first heat seal lines 3 And the second heat sealing line “and the enthalpy, the plurality of air columns 6. The first outer film 2a and the second outer film 2b are superposed one on top of the other” two viscera a and lb are interposed between the first outer film 2a and the second outer film Between 2b, and placed at the top of the first outer ridge 2a and the second outer film 2b slightly lower, the width of the two inner membranes la and lb is the same as that of the first outer film 2a and the second outer film 2b, and the length is short. The first outer film 2a and the second outer film 2b, so that the two inner films 1& and the two sides of the lb are located in the first outer film 2a and the second outer film 2b, and are not aligned with the first outer film 2a and the second The two sides of the second outer membrane 2b (as shown in Fig. 2C). The structure of the two inner membranes 丨 and lb described above are only examples, and the invention is limited to one of the two films. The side edges may also be aligned with the sides of the tops of the first outer film 2a and the second outer film 2b (as shown in FIG. 5), and may be respectively heat-sealed by the first outer film 2a and the inner film ia, second. Adventitial ridge and top side of intima lb In addition, the two inner membranes are coated with a long strip of heat-resistant material ic (as shown in the figure) which is equal to the length of the two inner membranes la and lb near the top, which means that the heat-resistant material lc The width is substantially the same as the two inner films 1& and lb, so that the heat-resistant material ic is used as the air permeable passage. However, the present invention is divided into the heat-resistant material 1c as the heat insulating member, and may also be numbered in the soil form. A0101 Page 6 of 45; sin 0992055060-0 201121848 Place a barrier sheet at the top instead of the heat-resistant material lc for 'heat-sealing means and then remove the barrier sheet. Further, the heat resistant material lc may be applied between the two inner films la and lb at a predetermined length and a predetermined width, wherein the predetermined width may preferably be the same as the interval between the adjacent two first heat seal lines 3. The width. The plurality of channel followers 5 are formed by heat sealing means, and are located on one side of the two inner films la and lb, followed by two inner films la and lb and the first outer film 2a, so that the two inner films la and 1] ;) can be attached to the first outer film 2a (as shown in Figure 3) 'here' the channel follower 5 can be point, straight or curved, but the invention is not limited thereto, in addition, plural The channel follower 5 is located on one side of the two inner membranes la and lb and only the two inner membranes la and lb are followed, so that the two inner membranes la and lb are not attached to the first outer meal 2a or the second outer film 2b ( As shown in Figure 4). The plurality of gas passages 2f are located between the two inner membranes la and lb of the plurality of passages 5. The plurality of first heat seal lines 3 are heat sealed hands; the segment formers follow the first outer film 2a and the second outer film end films la and lb in the first direction, where the first direction is the first outer The film 2a, the second outer film 2b, and the two inner films 1& and the length direction of the lb" and the second heat seal lines 4a and 4b are formed by heat sealing means, which are followed by the second direction and located in the first outer film 2a and two ends of the second outer film 2b, wherein the 'second heat seal line 4a is located at the finernic material ic and then the first outer film 2a and the inner film la, the second outer film 2b and the inner medium lb, the second heat The sealing line 4b follows the first outer film 2a and the second outer film 2b. Here, the second direction intersects the first direction as the width direction of the first outer film 2a, the second outer film 2b, and the two inner films la and lb. 099131420 Form No. A0101 Page 7 / Total 45 Page 0992055060-0 201121848 The plurality of inlet ports 2e are formed by the two inner membranes la and lb not adjacent to each other at the second heat seal line 4a, and the plurality of inlet ports 2e are connected to the plurality of gases Channel 2f. Here, the width of each air inlet 2e is the same as the width of the interval between the adjacent two first heat seal lines 3. In this embodiment, since the portions of the two inner films la and lb beyond the second heat seal line 4a are too long, the excess portion will sag and cover the air inlet 2e, resulting in a problem of poor inflation. It is preferable that the portions of the films 1a and 1b project out of the second heat seal line 4a so as not to sag, but the degree of sag does not obscure the air inlet 2e. The plurality of gas columns 6 are located between the first outer film 2a, the second outer film 2b, and the two inner films la and lb of the plurality of first heat seal lines 3 and the second heat seal lines 4a and 4b. When inflating, the first outer film 2a and the second outer film 2b are pulled apart, and the two inner films la and 1b are pulled outward to automatically open the air inlet 2e, and the gas flows into the gas passage 2f via the air inlet 2e, and along The gas passage 2f is filled into the air column 6, and the first outer membrane 2a and the second outer membrane 2b are pulled outward to inflate the air column 6, and the gas enters the air column 6, and the two inner membranes la and lb are pressed together. On the other hand, the air column 6 is closed, and the first outer film 2a and the second outer film 2b are expanded from a planar state to a three-dimensional shape having a curvature, so that the other ends of the two inner films la and lb are separated to form a gap. Since the width of each air inlet 2e is the same as the width of the adjacent two first heat seal lines 3, that is, the width of the air column 6, the gas can be filled into the air column 6 in a stepless manner. The charging efficiency is improved, and in the conventional air sealing body, the inflating device must be aligned with the air inlet and the charging efficiency is poor because the air inlet is too small. Referring to Figures 6 and 7, a second embodiment of the continuously inflated air seal of the present invention is shown. The difference between this embodiment and the first embodiment is 099131420 Form No. A0101 Page 8 of 45 0992055060-0 201121848 The structure is inflated. In this embodiment, the method further includes: a third heat seal line 4c, wherein the first outer film 2a and the second outer film 2b are followed by heat sealing means in the second direction, so that the first outer film 2a and the second outer film 2b are Between the second heat seal line 4a and the third heat seal line 4c, an inflation passage 9 is formed to communicate with the plurality of air inlets 2e, and the gas in the inflation passage 9 can simultaneously pass through the plurality of air inlets 2e and the plurality of gas passages 2f. The plurality of gas cylinders 6 are inflated. Ο Referring to Figures 8, 9A, 9B, 10A and 10B, a third embodiment of the continuously inflated air sealing body of the present invention is shown. In the present embodiment, the first heat seal line 3 is further extendable to form a reinforcing back portion 8, which is located at the intersection of the plurality of first heat seal lines 3 and the second heat seal line 4a at the coated heat resistant material lc. Here, the plurality of reinforcing contigs 8 may protrude from the heat-resistant material lc and then the first outer film 2a and the inner film la, the second outer film 2b and the inner film lb. When the crucible is inflated, the first outer membrane 2a and the second outer membrane 2b are pulled outward in the first direction, because the first outer membrane 2a and the second outer membrane 2b are expanded from a planar state to a three-dimensional shape having a curvature, because the The plurality of reinforcing joints 8 will expand due to inflation, and the plurality of reinforcing joints 8 will not be inflated, so that the first outer membrane 2a and the second outer layer 2a are formed by the natural drop during inflation. The film 2b is contracted to be displaced in the second direction to press the two inner membranes la and lb with the plurality of reinforcing joints 8 to pull outwardly in the first direction and automatically open the air inlet 2e (eg, 8B) The figure and the Fig. 9B), that is, the mountain-like complex strengthening joint 8 is pressed toward the valley-shaped gas passage 2f, so that the two inner membranes la and lb of the gas passage 2f are pulled outward, so that the plural The air port 2e is naturally squeezed out, effectively solving the problem that the air inlet can not be opened in the conventional air sealing body and the air can not be inflated. 099131420 Form No. A0101 Page 9 / Total 45 Page 0992055060-0 201121848 Method of manufacturing continuous inflatable air sealing body , including the following steps Step 101: providing a first - 2a having a heat insulating member between the outer membrane and two endometrial ia and lb, and two endometrial la lb. An inner film la and lb are superposed on the first outer film 23, and a heat insulating member is preliminarily provided between the two inner films la and lb, and the width of the heat insulating member is substantially the same as the two inner films la and lb. The width, or the width of the heat insulating member is smaller than the width of the two inner films la and lb and is spaced apart from the two inner films. Here, the heat insulating material may be a heat resistant material, and the two inner films 1 & 11} is coated with a strip of heat-resistant material lc having the same length as the two inner membranes 13 and 15 near the top to make the air-resistant and permeable passage or the two inner membranes la using the heat-resistant material 1 < The heat-resistant material lc is applied in a manner spaced apart from one of the lbs; in addition, a barrier sheet may be placed near the top instead of the #heat-resistant material ^. Further, the two inner membranes are placed on the first outer film. The top of the 2a is slightly lower, the widths of the two inner membranes la and lb are the same as those of the first outer film 2a, and the length is shorter than the first outer film 2a. Therefore, the two sides of the inner film 13 and 11} are not aligned with the first side. An outer membrane 2a has two sides. In this aspect, since the two inner membranes and the lb are excessively long beyond the second heat seal line 4a, the excess portion will sag and cover the air inlet 2e, causing a problem of poor inflation, and therefore, within two months. It is preferable that the portions of the film 1a and 1b protrude from the second heat seal line 4a so as not to sag, but the degree of sag does not obscure the air inlet 2e. The structure of the two inner films la and lb described above is merely an example, and the present invention is not limited thereto. One side of the two inner films la and lb may also be aligned with the side of the top of the first outer film 2a. Step 102: heat sealing followed by two inner membranes 13 and 1}3 and a first outer membrane ^ 099131420 form number A0101 page 10 / total 45 pages 0992055060-0 201121848 to form a plurality of passages 5, and in the plural channel A plurality of gas channels 2f are formed between the next two inner membranes la and lb. The plurality of inner membranes la and lb and the first outer membrane 2a are formed by heat sealing means to form a plurality of channel end portions 5, so that the two inner membranes la and lb can be adhered to the first outer film 2a, wherein the channel end portion 5 can be It is dotted, linear or curved, but the invention is not limited thereto. Step 103: providing a second outer film 2b overlapping the first outer film 2a such that the two inner films la and lb are interposed between the first outer film 2a and the second outer film 2b. Here, the length and width of the second outer film 2b are the same as those of the first outer film 〇 2a. Step 104: The first outer heat seal line 3 is followed by the first outer film 2a, the second outer film 2b, and the two inner films la and lb in the first direction. Here, the first direction is the longitudinal direction of the first outer film 2a, the second outer film 2b, and the two inner films la and lb. Step 105: Following the second heat seal lines 4a and 4b in a second direction intersecting the first direction, wherein the second heat seal line 4b is followed by the first outer film 2a and the second outer film 2b, and the second heat seal line 4a is located at the coating heat-resistant material lc and is connected to the first outer film 2a and the inner film la, the second outer film 2b and the inner film lb, and the two inner films la and lb are not adjacent to each other at the second heat seal line 4a. The plurality of air inlets 2e are formed, and the width of each air inlet 2e is the same as the width of the adjacent two first heat seal lines 3, and is applied to the plurality of first heat seal lines 3 and the second heat seal lines 4a. A plurality of gas columns 6 are formed between the first outer film 2a, the second outer film 2b, and the two inner films la and lb which are followed by 4b. The second heat seal lines 4a and 4b are formed by heat sealing means, which are followed by the second direction and located at both ends of the first outer film 2a and the second outer film 2b. Here, the second direction intersects the first direction, which is the first outer film 2a and the second outer 099131420. Form No. A0101 Page 11 / Total 45 pages 0992055060-0 201121848 The width direction of the film 2b and the two inner films la and lb . Further, the first heat seal line 3 extends at a point where it intersects with the second heat seal line 4a at the heat-resistant material lc to form a reinforcing back portion 8, where the plurality of reinforcing joint portions 8 may protrude from the heat-resistant material lc The first outer membrane 2a and the inner membrane la, the second outer membrane 2b and the inner membrane lb are then placed. Step 106: The gas flows into the plurality of gas passages 2f through the plurality of gas inlets 2e, and is filled with the plurality of gas columns 6 to inflate and expand. After the gas enters the gas column 6, the gas is pressed into the inner membranes la and one end of the lb to close the gas column 6, The two inner membranes la and lb are separated from each other to form a gap. When inflating, the first outer film 2a and the second outer film 2b are pulled apart, and the two inner films la and 1b are pulled outward to automatically open the air inlet 2e, and the gas flows into the gas passage 2f via the air inlet 2e, and along The gas passage is filled into the gas column 6, and the first outer membrane 2a and the second outer membrane 2b are pulled outward to inflate the gas column 6, and the gas enters the gas column 6, and then the two inner membranes la and lb are pressed together. The gas column 6 is closed, and the first outer film 2a and the second outer film 2b are expanded from a planar state to a three-dimensional shape having a curvature, so that the other ends of the two inner films la and lb are separated to form a gap. Since the width of each air inlet 2e is the same as the width of the adjacent two first heat seal lines 3, that is, the width of the air column 6, the gas can be filled into the air column 6 in a stepless manner and greatly increased. The charging efficiency solves the problem that in the conventional air sealing body, since the air inlet is too small, the inflator must be aligned with the air inlet and the charging efficiency is not good. Further, when the first outer film 2a and the second outer film 2b are expanded from a planar state to a three-dimensional shape having a curvature, the plurality of reinforcing portions 8 are not provided to expand due to inflation, and the plurality of reinforcing portions 8 are not provided. The inflation expands, so that the first outer film 2a and the second outer film 2b are contracted due to the natural drop during inflation, so that the first outer film 2a and the second outer film 2b are contracted to generate a displacement in the second direction. 099131420 Form No. A0101 Page 12 of 45 Page 0992055060-0 201121848 'Using the plurality of reinforcing joints 8 to squeeze the inner film 1 s and 1 b, pulling it outward in the first direction and automatically opening the air inlet 2e effectively solves the problem in the conventional air sealing body In the middle, the air inlet cannot be opened and the problem of inflating cannot be caused. Further, after step 105, the first outer film 2a and the second outer film 2b are followed by the third heat seal line 4c in the second direction, so that the first outer film 2a and the second outer film 2b are in the second The heat sealing line 4a and the third heat sealing line 4C form an inflation passage 9 and communicate with the plurality of air inlets 2e. The gas in the inflation passage 9 can simultaneously pass through the plurality of air inlets 2e and the teaching gas passages 2f to the plurality of air cylinders. 6 inflatable. The air inlet of the invention has the same width as the air column. Therefore, gas can be injected into the air column from anywhere between the two inner membranes, thereby improving the convenience of inflation, and at the same time solving the problem that the conventional sealing body is too small due to the air valve. This causes problems such as having to align the inflator with the air inlet and incomplete inflation. Referring to Fig. 11, the air column form of the present invention can be designed according to the shape of the object to be packaged.. 13⁄4 r ' 'This embodiment uses the bottle 7 as an example, and the bottle contains a bottle mouth. 71. A bottle body 73 and a -Hf tile bottom 75, the bottle body 73 close to the bottle mouth 71 is narrow, and the bottle body 73 close to the bottle bottom 75 is wider. The air sealing body 1 of the embodiment is a bag body, and the bottle body 7 for installing the wine bottle 7' close to the bottle mouth is narrow, so that the first air column 6a covering the bottle body 73 close to the bottle mouth 71 is larger. The bottle body 73 near the bottom 75 is wider' so that the second air column 6b of the bottle body 73 covering the bottom 75 is smaller. The air sealing body 1 of the present embodiment mainly uses the larger first air column 6a and the smaller second air column 6b to cover the wine bottle 7 before, so that the bottle 7 can be effectively prevented from being transported during transportation. Collided with other wine bottles 7. Please also refer to Figures 12A and 12B'. In the above example, air seal 099131420 Form No. A0101 Page 13 / Total 45 Page 0992055060-0 201121848 Body 1 is only wrapped around the bottle 7 before there is still a gap around the bottle 7 Therefore, the bottle body 73 which is closer to the bottle opening 71 can be mainly covered by the four first air columns 6a. Further, according to the width of the bottle body 73 close to the bottom 75, the wider the width of the bottle body 73 close to the bottom 75, the more the second gas column 6b of the bottle body 73 is covered; when the bottle is close to the bottom 75 The narrower the width of the body 73, the smaller the number of second air columns 6b covering the bottle body 73. Thus, the circumference of the wine bottle 7 is covered by the first gas column 6a and the second gas column 6b, so that the damage rate caused by the collision of the wine bottle 7 with other wine bottles 7 during transportation is reduced. Please refer to FIG. 13 together with the above-mentioned FIG. 11 and FIGS. 12A and 12B. FIG. 11 shows that before the bottle 7 is covered with the air sealing body 1, the 12A and 12B drawings disclose the use of the air sealing body 1 system. Cover the circumference of the wine bottle 7. The air sealing body 1 disclosed in FIG. 11 and FIGS. 12A and 12B is connected by a plurality of units, each unit comprising a first gas column Ga and a plurality of second gas columns 6b, in the second gas column of the embodiment. The number of 6b is three, and the number of the second gas column 6b is mainly based on the width of the bottle. The air seal body 1 of Fig. 11 is connected by two units, and the air seal body 1 of Figs. 12A and 12B is connected by four units. The thirteenth drawing depicts a unit of the air sealing body 1. Each unit of the air sealing body 1 includes a first outer film 2a and a second outer film 2b, two inner films la, lb, a heat resistant material lc, and a plurality of channels. a second portion 5a, a plurality of second passages 5b, a plurality of gas passages 2f, a plurality of first gas passages 2g, a plurality of first heat seal lines 3a, a plurality of fourth heat seal lines 3b, two second heat seal lines 4a, 4b, A first gas column 6a and a plurality of second gas columns 6b. The first outer film 2a and the second outer film 2b are superposed one on another, the two inner films la, lb are disposed between the first outer film 2a and the second outer film 2b, and the two inner films la, lb are near the top A long strip of heat resistant material 1 c is applied. The plurality of channel followers 5a are formed by heat sealing means, the plurality of channels 099131420 Form No. A0101 Page 14 / Total 45 pages 0992055060-0 201121848 The second part 5a is followed by two inner films la and lb and the first outer film 2a, so that two The inner films la and lb may be attached to the first outer film 2a. The gas passage 2f is located between the plurality of passage portions 5a, and the gas passes between the two inner membranes la and lb which are followed by the plurality of passage portions 5a. The first heat seal line 3a is formed by a heat sealing means, and follows the first outer film 2a, the second outer film 2b, and the two inner films la and lb along the first direction. Here, the first direction is the first outer The length direction of the film 2a, the second outer film 2b, and the two inner films la and lb. The second heat seal line 4a, 4b is formed by a heat sealing means, which is located along the second direction and located at both ends of the first outer film 2a and the second outer film 2b, wherein the second heat seal line 4a is located The heat resistant material lc is followed by the first outer film 2a and the inner film 1a, the second outer film 2b and the inner film 1b, and the second heat seal line 4b is followed by the first outer film 2a and the second outer film 2b. Here, the second direction intersects the first direction, and is the width direction of the first outer film 2a, the second outer film 2b, and the two inner films la and lb. The air inlet 2e is the two inner films la and lb. The two heat seal lines 4a are formed without each other, and the plurality of gas inlets 2e are connected to the plurality of gas passages 2f. Here, the width of each air inlet 2e is the same as the width of the interval between the adjacent two first heat seal lines 3a. Then, each unit is provided with a first air column 6a and three second air columns 6b. The second and fourth heat seal lines 3b are formed by heat sealing means, and the second and fourth heat seal lines 3b are followed by the first direction in the first direction. The outer film 2a and the second outer film 2b are located between the two first heat seal lines 3a, the distance between the first heat seal line 3a to the fourth heat seal line 3b and the fourth heat seal line 3b to the other fourth heat The length of the sealing line 3b is equal, and the length of the second and fourth heat sealing lines 3b is the height of the bottle 73 of the wine bottle 7 from the narrow width to the height of the bottom of the bottle 099131420, and the second and fourth heat sealing lines 3b are not sealed with the second heat sealing. Line 4b is followed by form number A0101. Page 15/45 pages 0992055060-0 201121848 One end is respectively provided with a first passage 5b, and the first heat seal line 3a corresponds to the fourth heat seal line 3b and the second heat seal line. 4b is further provided with a first channel follower 5b, a plurality of first channel followers 5b followed by a first outer film 2a and a second outer film 2b, and a plurality of first gas channels 2g between the plurality of first channel followers 5b . According to the above structure, the original gas column is divided into a first gas column 6a and three second gas columns 6b. When inflating, the first outer film 2a and the second outer film 2b are pulled apart, and the two inner films la and 1b are pulled outward to automatically open the air inlet 2e, and the gas flows into the plurality of gas passages 2f through the air inlet 2e, plural The gas passage 2f is in communication with the first gas column 6a, the gas is charged into the first gas column 6a along the plurality of gas channels 2f, and the plurality of first gas channels 2g are in communication with the plurality of second gas columns 6b, and the gas is first along the plural first The gas passage 2g is filled into the plurality of second gas columns 6b, and the first outer membrane 2a and the second outer membrane 2b are pulled outward to inflate the first gas cylinder 6a and the plurality of second gas cylinders 6b, and the gas enters the first gas column 6a. And after the plurality of second gas columns 6b are pressed, the two inner membranes la and lb are pressed together to close the first gas column 6a and the plurality of second gas columns 6b. Referring to FIG. 14 , in the above embodiment, the air sealing body 1 of the present embodiment is a bag body, and a belt body 10 is disposed on the bag body, so that the user can directly extract the belt body connected to the air sealing body 1 . Body 10. The belt body 10 is also an air sealing body. Please refer to FIG. 15 together. The air sealing body of the belt body 10 also includes a first outer film 2a and a second outer film 2b, two inner films la, lb, and a heat resistant material. Lc, a plurality of channel followers 5, a gas channel 2f, a plurality of first heat seal lines 3, two second heat seal lines 4a, 4b, and an air column 6. The first outer film 2a and the second outer film 2b are superposed one on another, the two inner films la, lb are disposed between the first outer film 2a and the second outer film 2b, and the two inner films la, lb are near the top A long strip of heat resistant material 1 c is applied. 099131420 Form No. A0101 Page 16 / Total 45 Page 0992055060-0 201121848 The plurality of passages 5 are formed by heat sealing means, and the plurality of passages 5 are followed by two inner films la and lb and the first outer film 2a, so that two The inner films la and lb may be attached to the first outer film 2a. The gas passage 2f is located between the plurality of passage portions 5, and the gas passes between the two inner membranes 1a and 1b following the plurality of passage portions 5a. The first heat seal line 3a is formed by a heat sealing means, and follows the first outer film 2a, the second outer film 2b, and the two inner films la and lb along the first direction. Here, the first direction is the first outer The length direction of the film 2a, the second outer film 2b, and the two inner films la and lb. The second heat seal line 4a, 4b is formed by a heat sealing means, which is located along the second direction and located at both ends of the first outer film 2a and the second outer film 2b, wherein the second heat seal line 4a is located The heat resistant material lc is followed by the first outer film 2a and the inner film 1a, the second outer film 2b and the inner film 1b, and the second heat seal line 4b is followed by the first outer film 2a and the second outer film 2b. Here, the second direction intersects the first direction as the width direction of the first outer film 2a, the second outer film 2b, and the two inner films la and lb. The air inlet 2e is formed such that the two inner membranes la and lb are not adjacent to each other at the second heat seal line 4a, and the air inlet 2e is connected to the gas passage 2f. Here, the width of each air inlet 2e is the same as the width of the interval between the adjacent two first heat seal lines 3. Referring to Figure 16, the tape body 10 is then attached to the top end of the bag body, and the tape body is fixed by a third heat sealing wire 4c and the top ends of the first outer film 2a and the second outer film 2b are sealed. The air inlet 2e of the tape body is not Sealed by the third heat seal line 4c, such that the first outer film 2a, the second outer film 2b, the second heat seal line 4a and the third heat seal line 4c form an inflation passage 9 for inflating to the bag body and the belt body. 10. Although the technical content of the present invention has been disclosed in the preferred embodiment as above, 099131420, Form No. A0101, Page 17 of 45, 0992055060-0, 201121848, which is not intended to limit the present invention, and anyone skilled in the art without departing from the invention. The scope of the present invention is intended to be included in the scope of the present invention, and the scope of the present invention is defined by the scope of the appended claims. BRIEF DESCRIPTION OF THE DRAWINGS [0005] Fig. 1 is a schematic view showing the appearance of a first embodiment of the present invention. Fig. 2A is a schematic view (1) of the first embodiment of the present invention at the time of manufacture. Fig. 2B is a schematic view (2) of the first embodiment of the present invention at the time of manufacture. Fig. 2C is a schematic view (3) of the first embodiment of the present invention at the time of manufacture. Figure 3 is a cross-sectional view (1) of the first embodiment of the present invention. Figure 4 is a cross-sectional view (2) of the first embodiment of the present invention. Fig. 5 is a perspective view showing another aspect of the first embodiment of the present invention. Figure 6 is a schematic view showing the appearance of a second embodiment of the present invention. Figure 7 is a schematic cross-sectional view showing a second embodiment of the present invention. Figure 8 is a schematic view showing the appearance of a third embodiment of the present invention. Fig. 9A is a schematic view (1) of the third embodiment of the present invention when inflated. Fig. 9B is a schematic view (2) of the third embodiment of the present invention when inflated. Fig. 10A is a schematic view showing another perspective of the third embodiment of the present invention when inflated (1). Figure 10B is a schematic view of another perspective view of the third embodiment of the present invention when inflated (2). Figure 11 is a schematic cross-sectional view showing a fourth embodiment of the present invention. Figure 12A is a schematic cross-sectional view showing a fifth embodiment of the present invention. Fig. 12B is a schematic cross-sectional view showing the fifth embodiment of the present invention. Figure 13 is a perspective view of a unit according to a fourth embodiment and a fifth embodiment of the present invention. 099131420 Form No. A0101 Page 18 of 45 0992055060-0 201121848 FIG. 14 is a cross-sectional view showing a sixth embodiment of the present invention. Fig. 15 is a view showing the appearance of a belt according to a seventh embodiment of the present invention. Figure 16 is a schematic cross-sectional view showing a seventh embodiment of the present invention. [Main component symbol description] Ο ο 099131420 [0006] 1 air seal body la/lb inner film lc heat resistant material 2a first outer film 2b second outer film 2e air inlet 2f gas passage 2g first gas passage 3/3a first Heat seal line 3b Fourth heat seal line 5/5a Channel follower 5b First passage follower 4a/4b Second heat seal: :.:....:.......... 4c ... ...''Third Heat 6 Air Column 6a First Air Column 6b Second Air Column 7 Wine Bottle 71 Bottle Port 73 Bottle Body 75 Bottle Bottom 8 Reinforced Bottom Form Number A0101 Page 19 / Total 45 Page 0992055060-0 201121848 9 Inflatable channel 10 belt body 099131420 Form number A0101 Page 20 / Total 45 page 0992055060-0

Claims (1)

201121848 VII. Patent application scope: 1. A continuous inflatable air sealing body, comprising: a first outer film; a second outer film overlapping with the first outer film; and two inner films between the first outer film Between the membrane and the second outer membrane; a plurality of channel followers located on one side of the inner membranes followed by the inner membranes; a plurality of gas passages located between the inner membranes followed by the passages; a heat insulating member located between the inner membranes; 0 a plurality of first heat seal lines, followed by the first outer film, the second outer film and the inner film along a first direction; And following a second direction intersecting the first direction, wherein the second heat seal line is followed by the first outer film and the second outer film, and the other second heat seal line is located at the heat insulator And then the first outer film and the adjacent inner film, the second outer film and the adjacent inner film; a plurality of air inlets, wherein the inner films are not connected to each other at the second heat seal line Connected to the gas passages, each of the inlet ports has the same width as the adjacent two of the first heats a width of the gap between the sealing lines; and a plurality of gas columns between the first heat sealing line and the first outer film, the second outer film and the inner film The inner membranes are pulled outward to open the air inlets, and the gas flows into the gas passages through the air inlets, and is inflated and inflated by the air cylinders, and the gas enters the air cylinders and compresses the inner membranes. One end is attached to close the gas column, and the other ends of the inner membranes are separated to form a gap. 2. The continuous inflatable air sealing body of claim 1, wherein the width of the heat insulating member is 099131420. Form number A0101 page 21/45 pages 0992055060-0 201121848 degrees are substantially the same as the width of the inner film. 3. The continuous inflatable air sealing body of claim 1, wherein the heat insulating member has a width smaller than a width of the inner film and is spaced apart from the inner film. 4. The continuous inflatable air seal of claim 1 wherein the channels follow the inner film and the first outer film. 5. The continuous inflatable air sealing body of claim 1, wherein the length of the inner film is shorter than the length of the first outer film and the second outer film, and one of the inner films is aligned with the first side The outer membrane is on the side of one of the second outer membranes. 6. The continuous inflatable air sealing body of claim 1, wherein the two sides of the inner film are located in the first outer film and the second outer film and are not aligned with the first outer film and the second outer The two sides of the membrane. 7. The continuous inflatable air seal of claim 1, further comprising: a plurality of reinforcing ends located at an intersection of the first heat seal line and one of the second heat seal lines at the heat shield. 8. The continuous inflatable air sealing body of claim 7, wherein the reinforcing protrusions protrude from the heat insulating member and then the first outer film and the adjacent inner film, the second outer film and adjacent ones The inner membrane. 9. The continuous inflatable air seal of claim 1, wherein the second heat seal lines are located at both ends of the first outer film and the second outer film. 10. The continuous inflatable air sealing body of claim 1, wherein the heat insulating member is a heat insulating ink. 11. The continuous inflatable air sealing body of claim 1, wherein the heat insulating member is a stopper. 12. The continuous inflatable air seal of claim 1, further comprising: a third heat seal line along which the first outer film and the second outer film are along the first outer film and the first outer film An inflation passage is formed between the second outer membranes, and is connected to the inlets 099131420 Form No. A0101, page 22/45 pages 0992055060-0 201121848. 13. The continuous inflatable air sealing body of claim 1, wherein the plurality of air column systems respectively comprise at least a first air column and at least a second air column, the first air column and the first a second gas column is disposed between the channel follower portion and the second heat seal line following the first outer film and the second outer film by using a plurality of first channel followers, the first channel followers along The second direction is followed by the first outer film and the second outer film dividing the air enthalpy, and the first channel has a plurality of first gas channels between the second portions, and the second gas column passes through the first gas channels The first gas column is in communication, and the first gas column is in communication with the gas channels. The continuous inflatable air sealing body of claim 13, wherein the second air columns are further disposed between the first heat seal lines by using at least one fourth heat seal line, and the first direction is followed by the first An outer film and the second outer film divide the gas column, and the fourth heat seal line connects the first channel follower. A method for manufacturing a continuous inflatable air sealing body, comprising the steps of: providing a first outer film and a second inner film, wherein the inner film has a heat insulating member; and heat sealing the inner film and the first outer portion Forming a plurality of channel followers, and forming a plurality of gas channels between the inner membranes followed by the channels; providing a second outer film, superimposing the first outer film to make the inner films Between the first outer film and the second outer film; a plurality of first heat seal lines along a first direction followed by the first outer film, the second outer film and the inner films; One of the directions intersecting the second direction is followed by two second heat seal lines, wherein the second heat seal line is followed by the first outer film and the second outer film, and the other second heat seal line is located at the heat insulation And then the first outer film and the adjacent 099131420 Form No. 1010101 Page 23 / Total 45 Page 0992055060-0 201121848 16 17 18 19 20 The inner membrane, the second outer membrane and the adjacent inner membrane, The inner membranes are not adjacent to each other at the second heat seal line to form a plurality of air inlets, each of which The width of the air port is the same as the width of the two adjacent first heat seal lines, and the first outer film and the second film are followed by the first heat seal line and the second heat seal lines. Forming a plurality of gas columns between the outer membrane and the inner membranes; and pulling the inner membranes outward to open the gas inlet ports, and the gas flows into the gas passages through the gas inlet ports, and is filled into the gas columns When the gas expands, the gas enters the gas column and presses one end of the inner film to seal the gas column, and the other end of the inner film separates to form a gap. The method of manufacturing the continuous inflatable air sealing body of claim 15, wherein the length of the inner film is shorter than the length of the first outer film and the second outer film, and one side of the inner film is aligned with the first side An outer film and one side of the second outer film. The method of manufacturing the continuous inflatable air sealing body of claim 15, wherein the two sides of the inner film are located in the first outer film and the second outer film and are not aligned with the first outer film and the second The two sides of the outer membrane. The method of manufacturing the continuously inflated air sealing body of claim 15, wherein after the step of following the second heat sealing line in the second direction intersecting the first direction, the method further comprises: following the first outer film And the adjacent inner film, the second outer film and the adjacent inner film form a plurality of reinforcements at intersections of the first heat seal lines and one of the second heat seal lines at the heat insulation member Next. The method of manufacturing the continuously inflated air sealing body of claim 15, wherein after the step of following the second heat sealing line in the second direction intersecting the first direction, the method further comprises: following the second direction A third heat seal line is followed by the first outer film and the second outer film, and an inflation passage is formed between the first outer film and the second outer film to communicate with the air inlets. A method of manufacturing a continuously inflated air sealing body according to claim 15, wherein 099131420 Form No. A0101 Page 24 of 45 0992055060-0 201121848 21 . 22 · 23 . Ο 24 . 25 . 26 . 隔热 The width of the insulation is substantially the same as the width of the inner membrane. A method of manufacturing a continuously inflated air-sealing body according to claim 15, wherein the width of the heat insulating member is smaller than the width of the inner film and spaced apart from the inner film. A method of manufacturing a continuously inflated air seal according to claim 15, wherein the passages are followed by the inner membrane and the first outer membrane. The method of manufacturing a continuous inflatable air sealing body according to claim 15, wherein the reinforcing protrusions protrude from the heat insulating member, and then the first outer film and the adjacent inner film and the second outer film are adjacent to each other The inner membrane. A method of manufacturing a continuously inflated air-sealing body according to claim 15, wherein the second heat seal lines are located at both ends of the first outer film and the second outer film. A method of manufacturing a continuously inflated air sealing body according to claim 15, wherein the heat insulating member is a heat ink. A method of manufacturing a continuously inflated air sealing body according to claim 15, wherein the heat insulating member is a barrier sheet. 099131420 Form number Α0101 Page 25 of 45 0992055060-0