JP2001239915A - Gas generator for air bag and air bag device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inflator for showing stable operational, performance by blocking up an opening part for communicating with outside air of a gas generator for an air bag by a moistureproof seal tape capable of preventing moisture absorption of a gas generating agent in the gas generator for the air bag. SOLUTION: This gas generator is featured by being set not more than 2.0 % in a weight increase rate by the moisture absorption, of the gas generating agent housed in the gas generator when the gas generator is left as it is for 20 days 4n a constant temperature/ constant humidity tank of a temperature of 80 deg.C and humidity of 90% by moisture permable performance of the seal tape by blocking up the opening part for communicating with the outside air of the gas generator by the moistureproof seal tape composed of a base material and an adhesive.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an airbag apparatus for protecting an occupant from an impact, and more particularly to an airbag gas having a stable operation performance, which effectively prevents the gas generating agent from absorbing moisture from outside air. Regarding the generator.

[0002]

2. Description of the Related Art When a vehicle such as an automobile collides at a high speed,
Automobile air that rapidly inflates the bag with gas generated from a gas generating agent to prevent the occupant from hitting hard or dangerous parts inside the vehicle such as the steering wheel or windshield due to inertia and causing injury or death. Bag systems have been developed. The requirements for gas generants suitable for automotive airbag systems are very stringent. First, the bag inflation time is required to be very short, typically within 40-50 milliseconds. Alkali metal salts and alkaline earth metal salts of hydrazoic acid, which are generally used at present, and gas generating agents using sodium azide as a gas generating base are excellent ones satisfying the above conditions. .

[0003] Further, non-azide gas generating agents have been developed to replace the sodium azide system. For example, Japanese Patent Application Laid-Open No. Hei 3-208878 discloses tetrazole, triazole or their metal salts and sodium nitrate. A composition containing an alkali metal nitrate-based oxygen-containing oxidizing agent as a main component is disclosed. On the other hand, JP-B-64-6156 and JP-B-64-6157 disclose gas generating agents containing a hydrogen-free metal salt of a bitetrazole compound as a main component. Further, JP-A-3-2088878 discloses a gas generating agent mainly composed of a transition metal complex of aminotetrazole. However, many components such as the oxidizing agent constituting the gas generating composition as described above exhibit remarkable hygroscopicity or deliquescent, and the water content of the gas generating agent greatly affects the combustion. In the gas generator described above, various methods are employed as means for preventing and protecting the gas generating agent contained therein from absorbing moisture. For example, there is a method of filling a thin aluminum container with a gas generating agent, closing the container with a lid and sealing with a sealing agent, and then filling the inside of the gas generator. However, this method is costly, and it is difficult to reduce the size of the inflator container. Therefore, recently, a gas generator in which a seal tape formed by applying an adhesive such as a thermosetting adhesive or a pressure-sensitive adhesive to a moisture-proof film is adhered to a gas outlet to increase the humidity is increasing. This can significantly reduce costs,
Further, downsizing of the gas generator is also feasible. However, this seal tape is generally not superior in terms of moisture permeability as compared with the above-described moisture-proof method. That is, in the gas generator to which the seal tape is attached, there is a portion (tape side surface) that is strictly blocked by only the adhesive between the outside and the internal space of the gas generator. However, in general, rubber-based, acrylic-based, silicone-based, and polyvinyl ether-based chemicals are used as the main component of the adhesive in order to improve the adhesive strength and holding power, and these chemicals are water-soluble. And the moisture diffusion property is relatively high, so that the external moisture more or less passes through a portion blocked by the adhesive alone. Therefore, the moisture proofing by the conventional sealing tape is not perfect, and there is a possibility that moisture permeation is surely achieved at a certain level.

[0004]

As described above, as described above,
In general, the main component of the adhesive used for the seal tape is rubber-based, acrylic-based,
Those having relatively high water solubility and water diffusibility such as silicone and polyvinyl ether are used. However, for example, when a seal tape is attached to a gas outlet of a gas generator housing partition wall and left in a normal environment,
Moisture in the external world more or less moves through a portion shielded only by the adhesive and enters the inside of the gas generator. Therefore, when moisture proofing is performed using a seal tape, it is necessary to use a seal tape that is as excellent as possible in moisture proofness while securing the adhesion function and the holding function.

Accordingly, an object of the present invention is to provide a gas generator for an airbag using an inflator moisture-proof sealing tape which solves the above-mentioned problems of the prior art.

[0006]

The present inventors have conducted intensive studies to solve the above-mentioned problems, and as a result, surprisingly, the weight increase rate of the gas generating agent due to moisture permeation after being left in a humid environment has been found. When a seal tape, which can be 2.0% or less, is used for the communication port with the outside air of the gas generator, it is possible to achieve the moisture proof of the gas generating agent and to have a remarkably little effect on the performance of the gas generator for an air bag. The present invention has been found.

That is, according to the present invention, an opening communicating with the outside air of the gas generator is closed by a moisture-proof sealing tape composed of a base material and an adhesive. When left in a constant temperature and humidity chamber at 80 ° C and 90% humidity for 20 days, the rate of weight increase due to moisture absorption of the gas generating agent contained in the gas generator is 2.0% or less. It relates to a gas generator.

[0008] The weight increase rate is determined by attaching the seal tape by hand in a gas generator so that the communication port with the outside air such as the through-hole on the inner cylinder portion and the gas discharge port is completely closed. After leaving the thing in a constant temperature and humidity chamber at a temperature of 80 ° C and a humidity of 90% for 20 days, measure the weight, calculate the difference from the weight before leaving the constant temperature and humidity chamber, and calculate the difference as a percentage of the gas generating agent. In particular, the weight increase rate in this case is defined as the moisture absorption rate of the gas generator.

When the combustion of the gas generator of the present invention was evaluated before and after the standing test, no significant difference was observed after the test even when compared with the gas generator performance before the humidification standing test. Was. From this, by performing moisture proofing with the seal tape of the present invention, it is possible to obtain a gas generator whose operating performance is constant without being affected by external moisture.

In particular, the seal tape used in the present invention is:
Those having the following moisture permeability are preferred.

That is, the gas generator moisture-proof seal tape is a moisture-permeable seal tape in which the rate of weight increase by moisture absorption of the gas generating agent per day is 0.050% or less under the following measurement conditions.

The conditions for measuring the moisture permeability of the seal tape are as follows.

The experimental vessel may be any vessel as long as the following conditions are satisfied.

1. The container is made of 100% moisture-proof material and does not show chemical change and remarkable expansion change at a temperature of 100 ° C or less and humidity of 100%. At least from the lid, the filling container and the members for ensuring airtightness Be composed.

2. The container can be hermetically sealed, and the lid has a circular opening having a diameter of 3 mm.

3. The inner volume of the container is 1 cc or more.

Using a container that satisfies the above conditions, the container is filled with 0.80 g or more of a gas generating agent, and 10 g is inserted into the opening of the lid.
A seal tape for inflator moistureproofing processed into a square of mm × 10 mm is applied while uniformly applying a pressure of 5 kg / cm ² or more to the tape surface so that the center thereof coincides with the center of the opening hole. Next, after the weight of the gas generating agent to be used is measured in advance, the gas generating agent is quickly filled in a container, and a lid is installed and fixed so that airtightness is ensured. Then place the sealed container at a temperature of 80
After leaving for 5 days or more and 25 days or less in an environment of 90 ° C and 90% humidity,
The container is disassembled and the weight of the gas generating agent is measured to obtain the rate of weight increase due to moisture absorption per day for the gas generating agent.

Under these measurement conditions, when a seal tape whose weight increase rate due to moisture absorption of the gas generating agent is 0.050% or less per day is used in the gas generator to prevent the gas generating agent from moisture, In addition, the operation performance of the gas generator is less affected by moisture due to moisture permeation from outside air.

The seal tape used in the present invention is usually
It is preferable to have a width of 2 to 3.5 times the diameter of the through hole to which the seal tape is attached and closed, such as a gas outlet of an inflator, between the upper end of the through hole and the upper edge of the seal tape, and the lower end of the through hole. It is desirable that a width of about 0.5 to 1.25 times the through hole is secured between each lower gap and the lower edge of the seal tape. Aluminum foil is desirable as the base material of the sealing tape. If the aluminum foil has a thickness of usually 25 μm or more, the moisture permeability is zero, and in this case, the aluminum foil is excellent in ease of processing, ease of sticking and environmental resistance. For example, the thickness of the sealing tape can be formed by an aluminum foil having a thickness of 50 μm or more and an adhesive having a thickness of 30 μm or more. When the thickness of the aluminum tape is 200 μm or more, the pressure inside the inflator container rapidly rises because the aluminum foil is not easily ruptured even when a gas is generated by burning the gas generating agent, and the container is joined. In addition to the risk of damage from the part, normal operation may not be performed, and furthermore, damaged containers and parts and uncooled gas may be blown out and cause harm to the human body. Therefore, when an aluminum foil is used as the base material of the sealing tape, the tape thickness is desirably in the range of 50 to 150 μm.

Further, a coating film such as a resin film such as a fluorine film may be provided on a base material such as an aluminum foil to improve the corrosion resistance of the seal tape.

The base material of the above-mentioned sealing tape is stuck to a predetermined place using various adhesives such as a pressure-type adhesive and a hot-melt adhesive. Hot melt adhesives are preferred because they can be melted by heating to ensure adhesion. The thickness of the adhesive is desirably in a ratio of 0.2 or more to 5.0 or less with respect to the thickness of the base material of the sealing tape. As the adhesive, an adhesive can be desirably used. Since long-term durability is desired for the pressure-sensitive adhesive, an acrylic or silicon-based pressure-sensitive adhesive is generally used. As for acrylic, the main component is acrylic ester, the ratio of which is 40% or more,
It is desirable that the hydrocarbon group on the side where the alcohol reacts and binds in the ester has 3 or more carbon atoms, as long as the physical properties of the pressure-sensitive adhesive do not change even at a freezing point expected under the global environment. As the silicone-based pressure-sensitive adhesive, one containing silicone rubber and silicone resin as main components is desirable. As a standard having normal adhesive strength and holding power,
When the tape width is set to 20 mm in accordance with JIS 0237, the 180 ° peel adhesive strength is desirably 1 kgf or more. In addition, it is desirable that the shear holding force does not drop after one hour, and the shifted distance is 1 mm or less.

The above-mentioned inflator using the gas generator moisture-proof seal tape is provided with an ignition means which operates in response to impact detection and a gas generating agent which generates gas by combustion in a housing having a gas discharge port. In a gas generator for an airbag accommodating a gas generating means including a gas generating means and a filter for cooling generated gas, a through hole such as a gas outlet is closed by the gas generator moisture-proof sealing tape.

The housing of the gas generator according to the present invention can be formed by welding a diffuser shell having a gas discharge port and a closure shell having an igniter storage port.

In the housing, an igniter including an igniter activated by an impact and a transfer charge ignited by the operation of the igniter, a gas generating agent ignited by the ignited transfer charge to generate a combustion gas, In addition, members necessary for constituting a gas generator for an air bag, such as a coolant filter for removing and cooling a combustion residue from the generated combustion gas, are appropriately accommodated.

As the ignition means, any of an electric ignition type and a mechanical ignition type in which a sensor for firing a firing pin by impact and a detonator are combined can be used.

As the gas generating agent to be used, known gas generating agents such as an azide-based gas generating agent and a non-azide-based gas generating agent can be used. Examples of the azide-based gas generating agent include those based on inorganic azides, particularly sodium azide (sodium azide), which have been widely used in the past, such as an equivalent mixture of sodium azide and copper oxide. Examples thereof include those containing a nitrogen-containing organic compound such as tetrazole, triazole, or a metal salt thereof and an oxygen-containing oxidizing agent such as an alkali metal nitrate as a main component, triaminoguanidine nitrate, carbohydrazide, nitroguanidine, dicyandiamide, and the like. As a fuel and nitrogen source, nitrate of alkali metal or alkaline earth metal as oxidizing agent,
There are compositions using chlorates, perchlorates, and the like. Considering safety and the like, non-azide gas generating agents are advantageous.

The coolant filter serves to remove combustion residues generated by the combustion of the gas generating agent and to cool the combustion gas. For example, stainless steel, SUS304, SUS310S, SUS316
A wire mesh made of (JIS standard symbol) or the like may be used as an annular laminate and compression molded. In addition, as for the filter coolant, a combination of a filter and a coolant widely used conventionally can be used.

[0028]

FIG. 1 shows a gas generator according to the present invention, which comprises a housing 3 comprising a diffuser shell 1 and a closure shell 2, a central cylindrical member 8 disposed in the housing 3 and serving as a partition. Ignition means comprising an igniter 4 and a transfer charge 5 provided in a hollow portion of the central cylindrical member 8, that is, an ignition means accommodating chamber 12, and solid gas generation which is ignited by the ignition means to generate combustion gas Agent 6 and the gas generating agent 6
, And a coolant filter 7 for cooling and purifying the gas, and supporting members, that is, plate members 9 and 10 disposed on both upper and lower ends of the coolant filter 7. . In this inflator, a sealing tape 13 is stuck to the outside to close a through hole 14 formed in a central cylindrical member 8 in the housing 3 and a housing 3 for discharging generated gas.
In order to close the gas discharge port 11 formed in the above, a seal tape is adhered to a place where a seal tape 13 is adhered to the inside thereof to prevent moisture.

In this gas generator, when an impact is detected by a sensor and a signal is sent to the igniter 4, the igniter is activated, whereby the transfer charge 5 in the ignition means container 16 is ignited and a high-temperature flame is generated. Generate This flame is blown out from the through-hole 14 and ignites the gas generating agent 6 near the through-hole 14, and the path is bent by the peripheral wall portion 15 of the plate member 9, and the flame is blown to the gas generating agent 6 below the gas generating agent storage chamber. Ignite. As a result, the gas generating agent 6 burns to generate a high-temperature and high-pressure gas, and this combustion gas passes through the entire area of the coolant filter 7,
In the meantime, it is effectively cooled, and the combustion residue is collected,
The cooled and purified combustion gas passes through the gas passage, breaks the seal tape 13, is ejected from the gas outlet 11, and flows into the airbag.

FIG. 2 is a sectional view of an airbag gas generator according to another embodiment of the present invention. The gas generator shown in this embodiment includes a housing 21 including a diffuser shell 19 and a closure shell 20, a filter means for defining a combustion chamber 22 in the housing 21, that is, a coolant filter 7, and the combustion chamber 22. And an igniter 18 disposed adjacent to the igniter 18
And a solid gas generating agent 6 that is ignited by the operation of the above to generate combustion gas.

The diffuser shell 19 and the closure shell 20 are formed by pressing a stainless steel plate. In the diffuser shell 19, a gas outlet 11 is provided at an outer peripheral portion constituting an outer peripheral wall of the housing at equal intervals in the circumferential direction. Are provided. The seal tape 13 is attached to the gas outlet 11 to prevent moisture from entering the gas generator from the outside. The movement of the gas generating agent 6 filled in the combustion chamber 22 is restricted by the plate member 17. The peripheral edge of the plate member 17 abuts on the inner peripheral surface of one end of the coolant filter 7 to cover the inner peripheral surface, so that the combustion gas can flow through the one end surface of the coolant filter and the inner wall surface of the diffuser shell. To prevent a short pass between

FIG. 3 is a diagram showing the construction of an airbag device. The gas generator of the present invention and an airbag (bag) 100 are shown.
And a module case 101. The gas discharged from the gas discharge port 11 of the gas generator is
As a result, the airbag 100 breaks the module cover 102 and bulges out, forming a cushion between the steering wheel 103 and the occupant for absorbing shock.

As the gas generator, the gas generator described with reference to FIGS.

The module case 101 is made of, for example, polyurethane and includes a module cover 102. The airbag 100 and the gas generator are housed in the module case 101 and configured as a pad module, which is attached to a steering wheel 103 of an automobile.

The airbag 100 is formed of nylon (for example, nylon 66) or polyester, and its bag mouth surrounds the gas discharge port 11 of the gas generator, and is formed around the gas generator in a folded state. It is fixed to the flange.

[0036]

EXAMPLES The present invention will be described in more detail with reference to the following Examples and Comparative Examples, which are not intended to limit the present invention.

Example 1 [Evaluation of Moisture Permeability of Seal Tape] Diameter 10 made of SUS304
mm, 13 mm deep recess, and 3 mm wide, 1.5 mm deep recess on the end face for moisture-proof packing
A SUS304 35mm diameter, 1mm high disk with a 3mm opening hole in the center of a 5mm, 17mm high cylinder with a packing sandwiched between the top and bottom of the disk. Use 10mm on the lid of this container
At the center of the lid, seal tape processed into a square of × 10 mm,
5 kg / cm ² force is applied evenly. The lid to which the sealing tape was attached was placed in such a state that the side to which the tape was attached was on the inside, and the gas generating agent was precisely weighed to 0.8000 g and filled into the container, and a silicone packing having a thickness of 2 mm was sandwiched. Cover and screw tight.

The sealed container was left for 24 days in an environment of a temperature of 80 ° C. or more and a humidity of 90% or more to disassemble the container, precisely weigh the gas generating agent, and determine the rate of weight increase with respect to 0.8000 g of the gas generating agent. Was calculated per day.

[Gas Generator for Airbag] In the gas generator for an airbag having the structure shown in FIG. 1, the internal volume of the housing and the total area of the opening are as follows.

Opening total area of 103cc housing; [0040] internal volume of the housing 146.01Mm ² outer opening ^{area; (1.5mm) 2 × 3.14 ×} 18 pieces = 127.17Mm
² Inner opening area; (1.0mm) ² x 3.14 x 6 = 18.84mm
² [Evaluation of Moisture Absorption Rate of Inflator] In the gas generator for an airbag having the above configuration, a seal tape having a width of 10 mm and a length of 65 mm was used so as to completely close the inner cylinder portion side through-hole 14, and a width of 10 mm The 205mm seal tape is pressed firmly by hand so that the gas outlet 11 is completely closed, and is stuck in a constant temperature / humidity chamber at 80 ° C and 90% humidity for 20 days to reduce the weight. The inflator was measured and the difference from the weight of the inflator before being left in the constant temperature and humidity chamber was calculated, and the percentage of the difference with respect to the gas generating agent was defined as the inflator moisture absorption rate.

[Evaluation of Combustion of Inflator] The characteristics of the moisture-proof sealing tape were evaluated based on the above evaluation method. As a result, the moisture-proof sealing tape in this example is as follows.

Product name: Nitto Foil AT-50 manufactured by Nitto Denko Structure: Aluminum foil thickness about 50 μm, adhesive thickness about 50 μm.

Water vapor transmission rate (weight increase rate per day): 0.03
0% Moisture absorption rate of inflator: 0.37% Combustion evaluation of an inflator using this seal tape was performed. In the combustion evaluation, the temperature of the gas generator after standing was immediately adjusted to 20 ° C, and this was fixed in a 60-liter non-expandable metal tank, the tank was sealed, and a signal was sent to the gas generator to ignite. I do. FIG. 4 shows a change in pressure in the tank at this time detected by a sensor, and the result is shown with time. On the other hand, the result of combustion evaluation without standing (FIG. 4
The standard is shown as a. No significant difference was observed when compared with ()).

Example 2 The characteristics of the moisture-proof seal tape were evaluated based on the same evaluation method as in Example 1. The same evaluation as in Example 1 was performed except that the following was used as the moisture-proof seal tape.

Trade name: Nortac's VITAC AF-2
1 Structure: about 25 μm Teflon (registered trademark) FEP, about 50 μm
m Aluminum foil and adhesive of about 30 μm Water vapor transmission rate (weight increase rate per day): 0.036% Moisture absorption rate of inflator: 1.59% The result of combustion evaluation of the inflator using the above-mentioned sealing tape is shown in FIG. On the other hand, no significant difference was confirmed when compared with those evaluated for combustion without standing.

Comparative Example 1 The characteristics of the moisture-proof sealing tape were evaluated based on the same evaluation method as in Example 1. The same evaluation as in Example 1 was performed except that the following was used as the moisture-proof seal tape.

Product name: # 433L manufactured by Sumitomo 3M Company Structure: about 50 μm aluminum foil and about 30 μm adhesive Water vapor transmission rate (weight increase rate per day): 0.060% Moisture absorption rate of inflator 5.41% Using the above sealing tape FIG. 4 shows the results of the combustion evaluation of the inflator thus performed. On the other hand, a remarkable difference was confirmed when compared with those evaluated for combustion without standing.

Comparative Example 2 The characteristics of the moisture-proof sealing tape were evaluated based on the same evaluation method as in Example 1. The same evaluation as in Example 1 was performed except that the following was used as the moisture-proof seal tape.

Product name: # 439L manufactured by Sumitomo 3M Co., Ltd. Structure: about 50 μm aluminum foil and about 30 μm adhesive Water vapor transmission rate (weight increase rate per day): 0.083% Moisture absorption rate of inflator: 6.81% Using the above sealing tape FIG. 4 shows the results of the combustion evaluation of the inflator thus performed. On the other hand, a remarkable difference was confirmed when compared with those evaluated for combustion without standing.

Example 3 The properties of the moisture-proof seal tape were evaluated based on the same evaluation method as in Example 1. The same evaluation as in Example 1 was performed except that the following was used as the moisture-proof seal tape.

Trade name: Nitto Foil AT-8 manufactured by Nitto Denko Corporation
0 Structure: Approximately 80 μm aluminum foil and approximately 50 μm adhesive Moisture permeability (weight increase per day): 0.037% Moisture absorption rate of inflator: 0.46% The results of the combustion evaluation of the inflator using the above seal tape are shown in FIG. Show. On the other hand, no significant difference was confirmed when compared with those evaluated for combustion without standing.

[0052]

According to the gas generator of the present invention, the seal tape to be applied for closing the gas ejection hole of the partition wall has a moisture permeability lower than a reference value obtained as a result of a predetermined experiment. When there was no significant decrease in combustion performance,
In airbag gas generators that require long-term environmental resistance, the reliability of airbag operation at the time of collision is improved by avoiding a decrease in combustion speed due to the moisture of the gas generating agent. When the airbag device is formed using a gas generator, a safer airbag device is realized.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a gas generator according to an embodiment of the present invention.

FIG. 2 is a longitudinal sectional view of a gas generator according to another embodiment of the present invention.

FIG. 3 is a configuration diagram of an airbag device.

FIG. 4 is a graph showing a result of combustion evaluation of an inflator.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 diffuser shell 2 closure shell 3 housing 4 igniter 5 transfer charge 6 gas generating agent 7 coolant / filter 11 gas outlet 13 seal tape 14 through hole

Claims (10)

[Claims] An opening for communicating with the outside air of a gas generator is closed by a moisture-proof sealing tape composed of a base material and an adhesive. Air characterized in that the rate of weight increase due to moisture absorption of the gas generating agent contained in the gas generator is 2.0% or less when left in a thermo-hygrostat at 90 ° C and a humidity of 90% for 20 days. Gas generator for bags. 2. A moisture-proof seal tape used for the purpose of moisture-proofing a gas generating agent contained in a gas generator for an air bag, wherein the seal tape is composed of a base material and an adhesive, and has a transparent property. A gas generator for an airbag, wherein the moisture performance is such that the rate of weight increase per day due to moisture absorption under the following measurement conditions is 0.05% or less. “Measurement conditions” The container is made of 100% moisture-proof material and has a temperature of 100%.
It does not show a chemical change or a remarkable expansion change at a temperature of 100 ° C. or less and a humidity of 100%, and comprises at least a lid, a main body of a filling container, and a member for ensuring airtightness. 2. The container can be hermetically sealed, and the lid has a circular opening having a diameter of 3 mm. 3. The inner volume of the container is 1 cc or more. Using a container that satisfies these conditions, fill the inside of the container with 0.80 g or more of a gas generating agent, and apply a 10 mm × 10 mm square moisture-proof sealing tape to the opening of the lid, and uniformly apply 5 kg / cm on the tape surface. While applying pressure of ² or more, the center is made to coincide with the center of the opening hole, and then pasted. Next, after the weight of the gas generating agent to be used is measured in advance, the gas generating agent is quickly filled in a container, and a lid is installed and fixed so that airtightness is ensured. After leaving the sealed container in an environment of a temperature of 80 ° C. and a humidity of 90% for 5 to 25 days, the container is disassembled, and the weight of the gas generating agent is measured.
The rate of weight increase due to moisture absorption per day for the gas generating agent is obtained. 3. The sealing tape for inflator dampproofing,
3. The gas generator for an air bag according to claim 1, wherein the base material is made of aluminum. 4. The sealing tape for inflator moisture proofing,
The gas generator for an airbag according to any one of claims 1 to 3, wherein a thickness of the gas generator is 50 µm or more and 150 µm or less. 5. The sealing tape for inflator moisture proofing,
The gas generator for an airbag according to claim 4, wherein the ratio of the adhesive to the base material is 0.2 or more and 5.0 or less. 6. The sealing tape for inflator moisture proofing,
The adhesive is a pressure-sensitive adhesive.
The gas generator for an airbag according to any one of claims 5 to 7. 7. The gas generator for an airbag according to claim 6, wherein the pressure-sensitive adhesive of the inflator moisture-proof seal tape is an acrylic pressure-sensitive adhesive. 8. The seal tape for inflator moisture proofing,
2 to 3.5 of the diameter of the through-hole that closes with the sealing tape attached
The gas generator for an airbag according to any one of claims 1 to 7, wherein the gas generator has a double width. 9. The sealing tape for inflator dampproofing,
0.5 between the upper end of the through hole and the upper edge of the seal tape and between the lower end of the through hole and the lower edge of the seal tape.
The gas generator for an airbag according to any one of claims 1 to 8, wherein a width of about 1.25 times is secured. 10. An airbag gas generator for generating a gas upon sensing an impact, an airbag for introducing and inflating a gas generated by the inflator, and a module case for accommodating the airbag. An airbag apparatus, wherein the airbag gas generator is the airbag gas generator according to any one of claims 1 to 9.