JP4278164B2 - Air seal with continuous pump and its manufacturing method - Google Patents

Description

  The present invention relates to an air seal and a manufacturing method thereof, and more particularly to an air seal using a continuous pump and a manufacturing method thereof.

  The air seal is made of a resin film, is sealed by heat sealing to form an air column, and is provided with an inlet for injecting gas.When gas is injected from the inlet into the air column, the air seal is Used as a cushioning material for internal packaging.

  General air seals are mainly divided into two types. The first type of air seal is mainly composed of a plurality of independent air columns. Each air column has an independent air inlet and injects gas into the air inlet of each air column. Therefore, much time is spent in the injection process as in the invention patent of the Chinese application number 9211574.

  The second type of air seal is mainly composed of multiple air columns that communicate with each other. One or more air inlets are provided, and gas is packed into the air column from the air inlets during injection. Since each air column communicates with each other, a plurality of air columns can be filled with gas at the same time. However, if any one of the air columns is damaged, a large number of air columns, as in US Pat. No. 5,427,830, can be obtained. Each communicating air column causes gas leakage at the same time.

In these two types of air seals, the inner thin film is raised by the atmospheric pressure during injection to close the gas, but the method of closing the gas has not been studied deeply yet, and after the injection, the air in the air column is stored for a long time. The above disadvantages affect the practicality of air seals.

  The Chinese Invention Patent No. 9211574 on May 20, 921 is a seal on-off valve installation structure. When the air enters, the seal on-off valve seals two inner thin films and one outer thin film to open and close each other. The valve seal is formed and the air seal expands after injection to shut off the passage, and this on-off valve only describes how to shut off the sealed air so that it does not leak. Not mentioned and according to the design, air is not automatically injected into the seal.

  How to design a seal, so that each can be injected independently and simultaneously, and can be continuously infused by opening the inlet port indirectly to save injection time, automatically closing the gas at the time of injection, The ability to automatically close the air so as not to leak outside for a long time after the closing is a technical problem faced by the inventors of the present invention and engineers in the related industry.

  The present invention provides an air seal using a continuous pump and a manufacturing method thereof.

The air seal by the continuous pump in the present invention includes two outer thin films covered one above the other and one or more inner thin films positioned between the two outer thin films, and the outer thin film and the inner thin film are formed by heat sealing means. A pump channel, an air inlet, a plurality of air columns and a plurality of curved gas channels are formed therebetween, and are located in the pump channel and interposed between one outer thin film and one inner thin film. It includes at least one heat seal point that seals the outer thin film and the inner thin film, and an external gas is loaded through the inlet of the pump channel during injection, and the pump channel is a gas The two outer thin films are opened outward, and the two inner thin films that are not sealed by the heat seal point are moved outward. When all the air inlets are opened automatically, gas is injected into the air column through the curved gas channel, the gas pressure in the air column gradually increases, and the inner thin film becomes thinner to the outer thin film. The intake port is closed by the inner thin film and performs an automatic gas closing function. At the same time, the gas channel of the inner thin film is pressed by the outer thin film, and the gas channel is thinned to the outer thin film at a curved portion to perform the gas closing function.

The air seal by the continuous pump in this invention and its manufacturing method include the following processes. Provide one or more inner thin films. A heat-resistant material is applied to the surface of the inner thin film. Two outer thin films are covered and an inner thin film is interposed between the outer thin films. The outer thin film and the inner thin film are sealed by heat sealing means along the heat seal line. The outer thin film and the inner thin film form a pump channel and a plurality of air columns. A lot of air inlets are formed in the inner thin film coated with the heat-resistant material, communicated with the pump channel and the air column, and are located in the pump channel between one outer thin film and one inner thin film. by intervening by at least one heat-sealing point was it seal one said outer film and one said thin film of. Fill the gas to expand the pump channel , open the two outer thin films outward, move the two inner thin films that are not sealed by the heat seal point, and open them outward to automatically inhale Open your mouth. Gas is continuously filled into the air column from the intake port. The air column gas squeezes the inner thin film to cover the air intake and close the air column.

  In the present invention, the air seal by the continuous pump and the manufacturing method thereof are filled with gas, the pump channel is expanded, the two outer thin films are opened, and the air inlet formed by the inner thin film is coated with a heat resistant material to form another thin film The air inlet automatically opens and fills the air column with more gas than the air inlet, but there is no need to position each air inlet during filling, so gas injection time can be saved. It is. Each air column is independent of each other, and even if the air column is broken, the buffering effect is not affected. The gas in the air column can compress the inner thin film to block the intake port and close the air column to prevent gas leakage, thereby increasing the gas blocking effect. The air column includes a curved gas channel and communicates with the intake port. One end leading to the intake port is wider than the other end, and the gas channel has a gas pressure at the curved portion larger than the gas pressure on both sides. When the pressure inside the air column increases, the gas channel curve is thinned and the gas closing effect is achieved.

  Preferred embodiments of the present invention and effects thereof will be described later in conjunction with the drawings.

[Example]
FIG. 1 is the first embodiment of air sealing by a continuous pump. 2A and 2B are two wall-mounted air seals, FIG. 2A is a cross-sectional view after injection, and FIG. 2B is a plan view before injection.

  The air seal includes two outer thin films 2a and 2b, two inner thin films 1a and 1b, a pump channel 9, an air column 11, and an intake port 2d. The two outer thin films 2a and 2b are covered up and down. The two inner thin films 1a and 1b are between the two outer thin films 2a and 2b, and the width is narrower than the outer thin films 2a and 2b.

  Heat sealing is performed along the heat sealing lines 3 and 4 to seal the two outer thin films 2a and 2b to form a gas channel 9. The gas channel 9 includes an inlet 12 that leads to an external gas.

  Heat sealing is performed by heat sealing means along the heat sealing lines 4, 5, 6, and 7, and the two outer thin films 2a and 2b are sealed to form an air column 11 for gas storage.

  A heat seal point 2c is generated by the heat sealing means, and the outer thin film 2a and the inner thin film 1a and the outer thin film 2b and the inner thin film 1b are sealed.

  When the heat-resistant material 1c is applied between the two inner thin films 1a and 1b at equal intervals so as to print heat-resistant rubber or ink by a printing method, the two inner thin films 1a and 1b are also sealed by the heat sealing means. The air inlet 2d is formed without this.

  The gas entering the inlet 12 expands the gas channel 9, opens the two outer thin films 2a and 2b outward, and seals the outer thin film 2a, the inner thin film 1a, the outer thin film 2b, and the inner thin film 1b with heat sealing means. The two inner thin films 1a and 1b that are not sealed are opened to the outside and the intake port 2d is automatically opened.

  When the intake port 2d is automatically opened, one gas channel 9 is continuously injected into the plurality of air columns 11, and injection can be performed without positioning with respect to each intake port 2d. Since the air columns 11 are independent of each other, even if a certain air column 11 is broken, the overall cushioning effect of the air seal is not affected.

  After filling the air column 11 from the air inlet 2d, the gas is filled, and the internal pressure of the gas in the air column 11 presses against the inner thin film 1a or 1b to cover the air inlet 2d and closes the air column 11, so that the gas is leaked to the outside. In this way, a gas blocking effect is achieved.

  First, a curved gas channel 13 is installed in the air column 11 and communicates with the intake port 2d. One end of the gas channel 13 communicating with the intake port 2d is wider than the other end. Is larger than the gas pressure on both sides, the gas at the inlet 2d is more likely to enter and difficult to come out, and when the pressure inside the air column 11 increases, the curved portion of the gas channel 13 is pressed to achieve a gas closing effect. is there.

  In this mode, the two inner thin films 1a and 1b are employed and are attached to the side surfaces of the outer thin film 2a or 2b, so that it is referred to as “two-wall bonding type”.

  3A and 3B are two wall-mounted air seals, FIG. 3A is a cross-sectional view after injection, and FIG. 3B is a plan view before injection.

  In this mode, the two inner thin films 1a and 1b are adopted and attached between the two outer thin films 2a or 2b.

  4A and 4B are a single wall-mounted air seal, FIG. 4A is a cross-sectional view after injection, and FIG. 4B is a plan view before injection.

  The air seal includes two outer thin films 2a and 2b, one inner thin film 1b, a pump channel 9, an air column 11, and an intake port 2d.

  The two outer thin films 2a and 2b are covered up and down.

  One inner thin film 1b is located between the two outer thin films 2a and 2b, and the width thereof is narrower than that of the outer thin films 2a and 2b.

  The heat seal lines 3 and 4 are heat-sealed by heat-sealing means, and the two outer thin films 2a and 2b are sealed to form a pump channel 9 including an inlet 12 communicating with an external gas.

  The heat column is heat sealed along the heat seal lines 4, 5, 6, 7, and the two outer thin films 2 a and 2 b are sealed to form the air column 11 used for storing gas.

  The heat sealing point 2c is generated by the heat sealing means, and the outer thin film 2b and the inner thin film 1b are sealed with this.

  When the heat-resistant material 1c is applied between the inner thin film 1b and the outer thin film 2a at equal intervals so as to print with heat-resistant rubber or ink by a printing method, the inner thin film 1b and the outer thin film 2b are still sealed by the heat sealing means. And the air inlet 2d is formed.

  The gas that has entered through the inlet 12 expands the pump channel 9 and opens the two outer thin films 2a and 2b to the outside. The outer thin film 2b and the inner thin film 1b are sealed by heat sealing means, and the inner thin film 1b and the outer thin film that are not sealed are sealed. The thin film 2a opens outward and opens the inlet 2d.

  By automatically opening the intake port 2d, one pump channel 9 can be continuously injected into a plurality of air columns 11, and it is not necessary to inject after positioning with respect to each intake port 11. Since the air columns 11 are independent of each other, even if a certain air column 11 is broken, the overall cushioning effect of the air seal is not affected.

  When the gas is filled, the air enters the air column 11 through the air inlet 2d, the internal pressure of the gas in the air column 11 presses the inner thin film 1b to cover the air inlet 2d, and the air column 11 is closed to leak the gas to the outside. The obstruction effect is achieved in such a way that it does not come off.

  In the air column 11, a curved gas channel 13 is first provided and communicated with the inlet 2d. The width of one end where the gas channel 13 communicates with the inlet 2d is wider than the width of the other end. Since the gas pressure at the inlet is larger than the gas pressure at both sides, the gas at the inlet 2d is easy to enter and difficult to come out, and when the internal pressure of the air column 11 increases, the curved portion of the gas channel 13 is pressed to exert a gas closing effect. Achieve.

  This mode employs a single inner thin film 1b and is attached to the side surface of the outer thin film 2a or 2b.

  In the first embodiment, the effects of automatically opening and closing and closing the gas can be achieved, and the injection time can be saved because there is no need to position each inlet. However, when the injection port 12 injects into the plurality of air columns 11 via the pump channel 9, the air column 11 far from the injection port 12 tends to be delayed in injection, and the injection time becomes longer. In the present invention, examples are disclosed below.

  FIG. 5 shows a second embodiment of the air seal using a continuous pump (injection). The air seal includes two outer thin films 2a and 2b, two inner thin films 1a and 1b, a chamber 14, a pump channel 9, an air column 11, and an intake port 2d.

  Heat sealing is performed along the heat sealing lines 3 and 4 by heat sealing means, and the two outer thin films 2a and 2b are sealed to form one chamber 14 and many pump channels 9, and the chamber 14 is used as an external gas. It includes an inlet 12 that is in contact.

  A heat sealing point 2c is generated by the heat sealing means, and the outer thin film 2a and the inner thin film 1a, and the outer thin film 2b and the inner thin film 1b are sealed.

  When the heat resistant material 1c is applied at equal intervals so that the two inner thin films 1a and 1b are printed with heat resistant rubber or ink by a printing method, the two inner thin films 1a and 1b are still sealed by the heat sealing means. The air inlet 2d is formed without any problems.

  The gas that has entered through the inlet 12 expands the pump channel 9 via the chamber 14, opens the two outer thin films 2a and 2b outward, and opens the outer thin film 2a, the inner thin film 1a, the outer thin film 2b, and the inner thin film 1b. When sealed by heat sealing means, the two inner thin films 1a and 1b that are not sealed are opened to the outside and the intake port 2d is automatically opened. One injection port 12 can simultaneously inject a plurality of air columns 11 via the chamber 14 and the pump channel 9 to save the injection time.

  In this embodiment, two wall-mounted type, two wall-mounted type or one wall-mounted type can be designed, the heat sealing means is a mold press, and the gas channel 9 is one The air column 11 communicates with the air inlet 2d or the plurality of air inlets 2d, and each air column 11 also communicates with one gas channel 13 or a plurality of gas channels 13, and also between each air column, so The gas channel 13 or a plurality of gas channels 13 can be shared. A first embodiment of a method for making a continuously injected air seal includes the following steps.

  Step 1: At least one inner thin film 1b is provided.

  Step 2: The heat resistant material 1c is applied to the surface portion of the inner thin film 1b at equal intervals so as to print with heat resistant rubber or ink by a printing method.

  Step 3: The outer thin films 2a and 2b are covered and the inner thin film 1b is interposed between the outer thin films 2a and 2b. When there are two inner thin films 1a and 1b, the heat resistant material 1c is between the inner thin films 1a and 1b, and when only one inner thin film 1b is present, the heat resistant material 1c is between the inner thin film 1b and the outer thin film 2a. .

  Step 4: The outer thin films 2a and 2b and the inner thin film 1b are sealed by heat sealing means along the heat seal lines 4, 5, 6, and 7.

  Step 5: The outer thin films 2a and 2b form one pump channel 9 and a plurality of air columns 11. The pump channel 9 includes an inlet 12 that communicates with external gas, and the air column 11 is used to store gas. .

  Step 6: Many intake ports 2d communicating with the pump channel 9 and the air column 11 are formed in the portion of the inner thin film 1b where the heat-resistant material is applied. When there are two inner thin films 1a and 1b, the heat seal point 2c seals the outer thin film 2a, the inner thin film 1a and the outer thin film 2b, and the inner thin film 1b, and the two inner thin films 1a and 1b are also sealed by heat sealing means. The inlet 2d is formed without being sealed. Only when there is one inner thin film 1b, the heat seal point 2c seals the outer thin film 2b and the inner thin film 1b, and the inner thin film 1b and the outer thin film 2a are not sealed by the heat sealing means to form the inlet 2d. .

  Step 7: Gas is filled to expand the pump channel 9, and the inlet 2d is automatically opened. The gas that has entered through the inlet 12 expands the pump channel 9 and opens the two outer thin films 2a and 2b to the outside. The outer thin film 2b and the inner thin film 1b are sealed by heat sealing means, and the inner thin film 1b and the outer thin film that are not sealed are sealed. The thin film 2a opens outward and opens the inlet 2d.

  Step 8: Gas is continuously filled into the air column 11 from the intake port 2d. By automatically opening the intake port 2d, one pump channel 9 can be continuously injected into a plurality of air columns 11, and it is not necessary to inject after positioning with respect to each intake port 11. Since the air columns 11 are independent of each other, even if a certain air column 11 is broken, the overall cushioning effect of the air seal is not affected.

  Step 9: The inner thin film 1b is pressed with the gas of the air column 11 to close the air inlet 2d, and the air column 11 is sealed. When the gas is filled, the air enters the air column 11 through the air inlet 2d, the internal pressure of the gas in the air column 11 presses the inner thin film 1b to cover the air inlet 2d, and the air column 11 is closed to leak the gas to the outside. In this way, a gas blocking effect is achieved. In the air column 11, a curved gas channel 13 is first provided and communicated with the inlet 2d. The width of one end where the gas channel 13 communicates with the inlet 2d is wider than the width of the other end. Since the gas pressure at the gas inlet portion is larger than the gas pressure at both sides, the gas at the inlet 2d is easy to enter and difficult to come out, and when the pressure in the air column 11 increases, the curved portion of the gas channel 13 is compressed and the gas closing effect is achieved. To achieve.

  In this embodiment, two wall-mounted, two wall-mounted, or one wall-mounted types can be designed, the heat sealing means is a mold press, and the gas channel 9 is one Since each of the air columns 11 communicates with one gas channel 13 or a plurality of gas channels 13 and communicates with each other between the air columns 2d. The gas channel 13 or a plurality of gas channels 13 can be shared.

  A second embodiment of a continuous pumped air seal fabrication method includes the following steps.

  Step 1: At least one inner thin film 1b is provided.

  Process 2: The heat-resistant material 1c is apply | coated to the surface part of the inner thin film 1b at equal intervals.

  Step 3: The outer thin films 2a and 2b are covered and the inner thin film 1b is interposed between the outer thin films 2a and 2b.

  Step 4: The outer thin films 2a and 2b and the inner thin film 1b are sealed by heat sealing means along the heat seal lines 4, 5, 6, and 7.

  Step 5: The outer thin films 2a and 2b form one chamber 14 and a number of pump channels 9 and a plurality of air columns 11, and the chamber 14 includes an inlet 12 that leads to external gas. Through the air column 11 is used for storing gas.

  Step 6: Many intake ports 2d communicating with the pump channel 9 and the air column 11 are formed in the portion of the inner thin film 1b where the heat-resistant material is applied.

  Step 7: Gas is filled by the chamber 14 to expand the pump channel 9, and the inlet 2d is automatically opened.

  Step 8: Gas is continuously filled into the air column 11 from the intake port 2d.

  Step 9: The inner thin film 1b is pressed with the gas of the air column 11 to close the air inlet 2d, and the air column 11 is sealed.

  In this embodiment, two wall-mounted, two wall-mounted, or one wall-mounted types can be designed, the heat sealing means is a mold press, and the gas channel 9 is one Since each of the air columns 11 communicates with one gas channel 13 or a plurality of gas channels 13 and communicates with each other between the air columns 2d. The gas channel 13 or a plurality of gas channels 13 can be shared.

  As shown in FIG. 6, in the third embodiment of the air seal of the continuous pump, as can be seen from the drawing, one or more air columns 11 are provided, and each air column 11 and pump channel 9 are provided. One or more air inlets 2d are provided between the air inlets 2d, and each air inlet 2d has a gas channel 13 corresponding thereto. When the volume of the air column 11 is large, a plurality of air inlets 2d and gas channels 13 are provided. When the gas is injected from the air column 11, the gas can be quickly filled into the air column 11.

  Although the technical contents of the present invention have already been disclosed above in the preferred embodiments, the present invention is not limited to these, and minor modifications made by engineers skilled in the art within the scope of the present invention and Any correction is included in the present invention.

It is the first Example of the air seal by a continuous pump (injection). It is sectional drawing after injection | pouring of two wall sticking type air seals. It is a top view before injection | pouring of two wall sticking type air seals. It is sectional drawing after injection | pouring of two wall-hanging type air seals. It is a top view before injection | pouring of two wall-hanging type air seals. It is sectional drawing after injection | pouring of one sheet of a wall sticking type air seal. It is a top view before the injection | pouring of one sheet of a wall sticking type air seal. It is the 2nd Example of the air seal by a continuous pump (injection). It is a 3rd Example of the air seal by a continuous pump (injection).

Explanation of symbols

1a, 1b inner thin film
1c Heat-resistant material 2a, 2b Outer thin film 2c Heat seal point 2d Inlet 3, 4, 5, 6, 7 Heat seal line 9 Pump channel 11 Air column 12 Inlet 13 Gas channel 14 Chamber

Claims (18)

Two outer thin films that are covered by upper and lower thin films;
One or more inner thin films positioned between the two outer thin films;
A pump channel having an inlet for injecting air from outside, forming a space by sealing the two outer thin films by heat sealing means;
At least one heat seal point located in the pump channel, interposed between the one outer thin film and the one inner thin film, and sealing one outer thin film and one inner thin film; ,
A plurality of air columns that form a space for storing gas by sealing the two outer thin films by heat sealing means;
Between the pump channel and the air column, including a plurality of air inlets formed by applying a heat-resistant material at regular intervals in order from one surface of the inner thin film, without sealing other thin films by heat sealing means,
The gas at the inlet is made to enter, the gas channel is expanded, the two outer thin films are opened outward, the two inner thin films that are not sealed by the heat seal point are moved and opened outward, after gas allowed to enter the air column opens an inlet, the air column of the gas covers the inlet pressure on said thin film, characterized by sealing the air column,
Air seal with continuous pump. 2. The air seal according to claim 1, wherein the inner thin film is a single sheet, and the heat-resistant material is applied between the inner thin film and the single outer thin film at equal intervals. 2. The air seal by a continuous pump according to claim 1, wherein the inner thin film is two sheets and the heat-resistant material is applied between the two inner thin films at equal intervals. 3. The continuous pump air according to claim 2, wherein the air column includes a curved gas channel connected to the intake port, and the gas pressure in the curved portion is larger than the gas pressure on both sides in the gas channel. sticker. The air seal according to claim 2, wherein the air column includes a curved gas channel connected to the air inlet, and is connected to one end of the air inlet and wider than the other end. Two outer thin films that are covered by upper and lower thin films;
One or more inner thin films interposing the two outer thin films;
At least one heat seal point interposed between one outer thin film and one inner thin film and sealing one outer thin film and one inner thin film;
A chamber having an inlet for injecting air from outside , forming a space by sealing the two outer thin films by heat sealing means;
A space is formed by sealing the two outer thin films by heat sealing means,
A plurality of pump channels connected to the chamber;
A plurality of air columns that form a space for storing gas by sealing the two outer thin films by heat sealing means;
Connected to the pump channel and the air column, including a plurality of air inlets formed by applying a heat-resistant material to the surface portion of the inner thin film without sealing other thin films by heat sealing means,
The inlet gas is introduced, the pump channel is expanded by the chamber, the two outer thin films are opened outward, and the two inner thin films that are not sealed by the heat seal point are moved and opened outward. was, after gas is entering into the air column opens the inlet, the gas of the air column pressure on said thin film, you characterized by sealing the air column covering the air inlet, Air seal with continuous pump. Said thin film is one, said refractory material is air sealed by continuous pump according to claim 6, characterized in that are applied between the outer film in said thin film and one at equal intervals. It said thin film is a two, airtight seal by continuous pump according to claim 6, wherein the refractory material are applied between the said thin film of two at equal intervals. The continuous air according to claim 6, wherein the air column includes a curved gas channel connected to the intake port, and the gas pressure of the curved portion is larger than the gas pressure on both sides of the gas channel. Air seal by pump. The air seal according to claim 6, wherein the air column includes a curved gas channel connected to the air inlet, and is connected to one end of the air inlet and wider than the other end. Providing one or more inner thin films;
Applying a heat-resistant material to one side of the inner thin film at regular intervals;
A step in which the inner thin film is interposed in the outer thin film by combining two outer thin films;
Heat sealing the outer thin film by heat sealing along a pair of heat seal lines;
Forming a pump channel and a plurality of air columns from the outer thin film;
A plurality of air inlets are formed in a portion where the heat-resistant material is applied at equal intervals from the inner thin film, connected to the pump channel and the air column, and located in the pump channel, one outer thin film and one sheet Sealing one outer thin film and one inner thin film by at least one heat seal point interposed between inner thin films ;
Filling the gas and inflating the pump channel , opening the two outer membranes outward, moving the two inner membranes not sealed by the heat seal point to open outwards, and opening the inlet Automatically opening process,
Continuously filling the air column with gas from the inlet;
The method for producing an air seal using a continuous pump according to claim 1, further comprising a step of sealing the air column by pressing the inner thin film with the gas of the air column to cover the intake port. 12. The method for producing an air seal with a continuous pump according to claim 11, wherein the step of applying the heat-resistant material at equal intervals is completed by printing. Said refractory material within the thin film in one sheet manufacturing method of the airtight seal by continuous pump according to claim 11, characterized in that are applied between said thin film and one said outer film at equal intervals . Method of fabricating an air seal by continuous pump according to claim 11, wherein said thin film of two sheets said refractory material are applied between two said films at equal intervals. Providing one or more inner thin films;
Applying a heat-resistant material to one side of the inner thin film at regular intervals;
A step in which the inner thin film is interposed in the outer thin film by combining two outer thin films;
Heat sealing the outer thin film and the inner thin film by heat sealing along a pair of heat seal lines;
Forming a chamber, a plurality of pump channels, a plurality of air columns by the outer thin film, and connecting the chamber to the pump channel;
A plurality of air inlets are formed in a portion where the heat-resistant material is applied from the inner thin film, the pump channel and the air column are connected , and one outer thin film and one inner thin film are located in the pump channel. Sealing one sheet of the outer thin film and one sheet of the inner thin film with at least one heat sealing point interposed between
The chamber is filled with gas and the pump channel is expanded, the two outer thin films are opened outward, and the two inner thin films that are not sealed by the heat seal point are moved to open outward. a step of opening the intake port automatically,
Continuously filling the air column with gas from the inlet;
A method for producing an air seal with a continuous pump, comprising the step of compressing the inner thin film with the gas of the air column to cover the intake port and seal the air column. 16. The method for producing an air seal with a continuous pump according to claim 15, wherein the step of applying the heat-resistant material at equal intervals is completed by printing. Said refractory material within said film is a piece manufacturing method of the air seal by continuous pump according to claim 15, characterized in that are applied between said thin film and one said outer film at equal intervals . Method of fabricating an air seal by continuous pump according to claim 15, wherein said thin film of two sheets said refractory material are applied between two said films at equal intervals.

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