JP2001233389A - Aerosol container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To increase the volume ratio of a content occupying the interior of an aerosol container, retain the given jet state as long as possible until the content is used up and repeatedly use the aerosol container by a user. SOLUTION: A hydrogen stored alloy 30 stored in a bag 32 is bonded for use on an upper section, for example, on a mount cap 26 of the interior of a container main body 10 of the aerosol container.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an aerosol container which uses a hydrogen storage alloy and injects contents in a container body with hydrogen pressure during use.

[0002]

2. Description of the Related Art Conventionally, an aerosol container uses a liquefied gas such as liquefied butane gas or liquefied dimethyl ether, or a compressed gas obtained by pressurizing carbon dioxide gas, nitrogen gas or the like as a propellant.

[0003]

However, in the former aerosol container using a liquefied gas as a propellant, the spray state during the spraying does not change so much, but a large amount of the propellant is required, so that the inside of the container body is required. The ratio of the volume of the propellant to the fuel becomes large, and there is a problem in safety because the change in internal pressure due to temperature change is large.

On the other hand, in the latter aerosol container using a compressed gas as a propellant, the change in internal pressure due to temperature change is small, but the internal pressure in the aerosol container decreases as the contents decrease, and the gas pressure for injection decreases. There is a problem that it is difficult to maintain a constant jet state until the contents are used up. In order to avoid this, it is necessary to increase the space for filling the gas, and there is a problem that the volume ratio of the propellant occupying in the container body increases.

Further, in these conventional aerosol containers, there is a problem that the propellant is gradually lost, and the refilling of the contents is not easy, so that it is difficult for the user to reuse the aerosol container. Was.

Therefore, an object of the present invention is to increase the volume ratio of the contents in the container body in the aerosol container, and to maintain the spraying state as constant as possible until the contents are used up. An object of the present invention is to make it possible for a user to repeatedly use an aerosol container when the contents are used up, with little loss of the propellant, facilitating refilling of the contents.

[0007]

Therefore, according to the present invention, in the aerosol container, a hydrogen storage alloy is provided in a container main body for storing contents, and hydrogen released from the hydrogen storage alloy is used as the hydrogen storage alloy. The pressure inside the container body is increased.

According to a second aspect of the present invention, in the aerosol container according to the first aspect, the hydrogen storage alloy is provided at an upper portion in the container body.

According to a third aspect of the present invention, in the aerosol container according to the first aspect, a flexible bag is provided in the container main body, the contents are stored in the bag, and the flexible bag is placed outside the bag. It is characterized by comprising the hydrogen storage alloy.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an aerosol container according to the invention with the cap removed and the injection button removed.

Reference numeral 10 in the figure is a circular can-shaped container body. The container body 10 is formed by slightly squeezing the upper opening and rounding the peripheral edge outward to form a tightening portion 10a.
The contents 12 to be ejected by the aerosol container are mainly stored in a liquid state. This content 1
The liquefied gas 2, such as liquefied dimethyl ether, is dissolved in the bubble 2, for example, when spraying in a bubble state.

A bubble unit 20 is attached to the opening of the container body 10 as described above. The bubble unit 20 includes a cylindrical housing 21 as shown in FIG. The housing 21 has a step portion a in the middle in the axial direction, and a large diameter portion 21a formed in an upper stage and a small diameter portion 21b formed in a lower stage. A plurality of vertical grooves b are provided on the inner circumference of the large-diameter portion 21a.
Is formed.

Then, the small diameter portion 21b is inserted into the upper end of the pipe 22, the pipe 22 is attached to the housing 21, and is extended downward.

On the other hand, in the large diameter portion 21a, the coil spring 23 is inserted on the step portion a, and the lower portion of the stem 24 is inserted on the coil spring 23.

The stem 24 has a spout hole 24a at the axis thereof and a neck portion 24b at an intermediate portion in the axial direction. The neck portion 24b has a lateral hole 24 communicating the spout hole 24a with the outside.
Open c. An annular plate-like stem rubber 25 is fitted around the neck 24b in a flange shape.

The stem 24 has a mountain cap 2 on the upper part.
6, and a dish-shaped mountain cap 26 is put on the housing 21 with the stem rubber 25 interposed therebetween.
The mountain cap 26 has a winding part 26a on the outer periphery.

In the present invention, for example, as shown in FIG. 1, a hydrogen storage alloy 30 is provided on the lower surface of the mountain cap 26 of the bubble unit 20 constructed as described above.
Is stored in the bag 32 and attached by bonding.

Then, the pipe 22 is put into the container body 10, the housing 21 is dropped into the container body 10, and the winding portion 26a of the mountain cap 26 is
7 is tightly and airtightly wound around the winding portion 10a of the container body 10.

Although not shown, an ejection button is attached to the upper end of the stem 24. The ejection button is provided with a nozzle that communicates with the ejection hole 24 a of the stem 24 and ejects the contents 12 in the container body 10. When not in use, the container body 10 is covered with a cap (not shown) by covering the ejection button.

In the illustrated example described above, the hydrogen storage alloy 30 is housed in the bag 32 and attached to the lower surface of the mountain cap 26 by bonding. In this hydrogen storage alloy, hydrogen forms hydrides in metals and alloys.It stores a large amount of hydrogen, releases it by heating or depressurizing, stores it by cooling or pressurizing, and its release and storage are reversible. Conventionally, many hydrogen storage alloys are known.

The hydrogen storage alloy according to the present invention includes:
Iron-titanium-based alloy (FeTi), which is easy to store and release at around normal temperature and pressure, general formula RMn (where R is a rare earth element, M
Is another metal, preferably an iron group element, and n represents 3 to 5). Among these alloys, LaNi ₅ alloy or a partially substituted LaNi ₅ alloy is particularly preferred.

For example, 1 g of LaNi ₅ alloy
At 0 ° C. and 1 atm, 155 ml of hydrogen can be stored. At room temperature, it has an equilibrium pressure of 0.15 MPa. For example, if about 2 g of LaNi ₅ alloy fully storing hydrogen is put in a 200-ml container body, when the temperature is used at a constant temperature, the contents are reduced. Until it is used up
An internal pressure of 0.15 MPa can be maintained, and a constant injection state can be maintained. At this time, the pressure can be increased by increasing the temperature, and the pressure can be decreased by decreasing the temperature.

[0023] In addition, changing the part of Ni of the LaNi ₅ alloy with other metals, by changing the part of the La on the other rare earth elements, it is also possible to change the equilibrium pressure. For example, when a LaNi ₄ M (M is Cu, Fe, etc.) alloy is used, the equilibrium pressure is lowered, and the La _{0. 8} R _0.2 Ni ₅ (R is N
The use of a rare earth element alloy such as d) increases the equilibrium pressure. Thereby, an alloy corresponding to the working temperature and the optimum injection pressure can be selected as desired.

These rare-earth hydrogen storage alloys may be deteriorated by water or other liquids, and may be suspended in the contents due to powdering if hydrogen is repeatedly stored and released by use. There is.

For this reason, the hydrogen storage alloy 30 is made of a bag 32 having fine pores through which gas can pass but liquid cannot pass.
And the space inside the container body 10 where the gas is filled with the contents 12. The bag 32 is made of, for example, resin or rubber.

The hydrogen storage alloy 30 is, for example,
2 and attached to the mountain cap 26 of the valve unit 20 and then placed in a hydrogen stream of about 1 MPa to store hydrogen, and then placed in a low-temperature storage container and maintained at a balanced hydrogen pressure. Use what was done.

In the illustrated aerosol container, hydrogen is released from the hydrogen storage alloy 30 and the space above the contents 12 is filled with hydrogen, and the pressure in the container body 10 is increased. The contents 12 therein rise in the pipe 22.

When using this aerosol container, the cap (not shown) is removed and the container body 10 is removed.
Hold the hand and point the nozzle of the injection button toward the injection target site. Then, the injection button is pressed down, and that state is maintained.

Then, the stem 24 is pushed into the housing 21 against the coil spring 23 and deforms the stem rubber 25 to form a gap between the stem 24 and the stem 24.
Is communicated with the inside of the container body 10.

Then, due to the pressure in the container body 10, the contents 12 rise up the pipe 22 and enter the ejection hole 24a from the horizontal hole 24c of the stem 24 through the vertical groove b formed in the housing 21. From the spray button and spray from the nozzle of the spray button.

When the hand is released from the injection button of the aerosol container, the stem 24 returns by the spring force of the coil spring 23, and the deformation of the stem rubber 25 is released. The lateral hole 24c and the container body 10 are not communicated with each other, and the injection is terminated.

The amount of the hydrogen storage alloy used is, for example, used in a container having an inner volume of 200 ml.
To maintain the internal pressure at 0.4 MPa, the pressure may be about 5.2 g. Here, the specific gravity of this alloy is about 7 without hydrogen storage, and when hydrogen is stored, it is reduced by about 10%. However, in any case, it is only about 1 ml. The volume is extremely small compared to the case of compressed gas or compressed gas. Therefore, according to the aerosol container of the present invention, the volume ratio of the propellant in the container body can be significantly reduced.

Then, the content 12 gradually decreases and finally almost disappears, but until that point, the hydrogen storage alloy 30 continues to release hydrogen, and at a constant temperature, the pressure inside the container body 10 is reduced. Is kept constant. Therefore, in the aerosol container of the present invention, a constant jet state can be maintained until the contents 12 are used up.

Moreover, when the aerosol container is cooled when the contents 12 are used up, the hydrogen storage alloy 30 stores hydrogen, and the pressure drops to a pressure corresponding to the performance. Depending on the type of hydrogen storage alloy 30 used, it can be at or below atmospheric pressure and in this state it is easy to introduce the contents from the refill via the stem 24. . Moreover, as described above, since hydrogen can be stored again in the original hydrogen storage alloy by cooling, there is almost no loss of hydrogen. Therefore, the aerosol container of the present invention can be used repeatedly by the user.

By the way, in the illustrated example described above, the hydrogen storage alloy 30 is put in the bag 32 and provided on the upper part in the container main body 10. For example, as shown in FIG.
A flexible bag 33 is provided therein, and the contents 12 are contained in the flexible bag 33.
And the hydrogen storage alloy 3
4 may be provided.

In FIG. 3, the reference numerals used for the corresponding parts of the aerosol container shown in FIGS. 1 and 2 are used as they are, and redundant description is omitted. Note that FIG.
In the illustrated example, since a pipe is not required, it is not included in the valve unit 20. However, a pipe may be required in the pipe unit 20 in some cases.

In FIG. 3, the newly added reference numeral 33 is
It is a flexible bag provided in the container body 10. As the flexible bag 33, the inner container of a double-structured container that has recently been increasingly used as an aerosol container may be used as it is.

The contents 12 are stored in the flexible bag 33, and a hydrogen storage alloy 34 is further filled with a fine mesh bag or a resin or rubber bag 36 having many pores. And prepare it. At this time, for example, it is lightly bonded to the inner bottom surface of the container body 10 with an adhesive. Adhesion is not always necessary, but it is better to adhere to prevent abnormal noise or deterioration of the alloy due to contact with the container body 10.

The hydrogen storage alloy 34 is, for example,
6 and placed in a 1 MPa normal-temperature hydrogen stream to store hydrogen, and then placed in a low-temperature storage vessel and maintained at an equilibrium hydrogen pressure.

Then, the hydrogen storage alloy 34 is adhered to the inner bottom surface of the container body 10 as described above, and then the flexible bag 3
3 is installed.

In the illustrated aerosol container, hydrogen is released from the hydrogen storage alloy 34, and the pressure is applied to the flexible bag 3.
When the container 3 is contracted to increase the pressure in the container body 10 and the ejection button is pressed down, the contents 12 stored in the flexible bag 33 are ejected from the nozzle of the ejection button through the valve unit 20.

Since the hydrogen storage alloy and the contents are merely separated by a flexible bag, and the other points are the same as those in the above-described embodiment, a constant jetting state is maintained until the contents 12 are used up. Also, when the contents 12 are used up, the aerosol container is cooled and hydrogen is stored again in the hydrogen storage alloy 34, so that there is almost no loss of hydrogen, and the contents 12 can be easily refilled. Therefore, the user can use the aerosol container repeatedly as in the above-described illustrated example.

[0043]

Therefore, according to the present invention, the pressure inside the container body is increased by the hydrogen released from the hydrogen storage alloy without using the liquefied gas or the compressed gas as in the prior art. The volume ratio occupying the main body can be increased, and a constant jetting state can be maintained until the contents are used up. In addition, when the contents are used up, the loss of hydrogen is almost eliminated, and the contents can be easily refilled. Therefore, the user can repeatedly use the aerosol container.

According to the second aspect of the present invention, it is not necessary to particularly provide an inner bag (flexible bag) in the container body, so that the effect of the first aspect can be easily achieved and the number of members can be reduced. Can be reduced.

According to the third aspect of the present invention, a bag containing the hydrogen storage alloy is provided in another space separated from the contents of the container body by the flexible bag. And the loss of hydrogen as the injection gas can be more completely prevented, and the effect of claim 1 can be further achieved.

[Brief description of the drawings]

FIG. 1 is an overall schematic configuration diagram of an aerosol container of the present invention.

FIG. 2 is a longitudinal sectional view of a bubble unit used in the aerosol container.

FIG. 3 is an overall schematic configuration diagram of an aerosol container according to another example of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Container main body 12 Contents 20 Bubble unit 21 Housing 22 Pipe 23 Coil spring 24 Stem 24a Spray hole 24c Side hole 25 Stem rubber 26 Mountain cap 30 ・ 34 Hydrogen storage alloy 32 ・ 36 bag 33 Flexible bag

────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] February 23, 2000 (200.2.2
3)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of the Invention] Aerosol container

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an aerosol container which uses a hydrogen storage alloy and injects contents in a container body with hydrogen pressure during use.

[0002]

2. Description of the Related Art Conventionally, an aerosol container uses a liquefied gas such as liquefied butane gas or liquefied dimethyl ether, or a compressed gas obtained by pressurizing carbon dioxide gas, nitrogen gas or the like as a propellant.

[0003]

However, in the former aerosol container using a liquefied gas as a propellant, the spray state during the spraying does not change so much, but a large amount of the propellant is required, so that the inside of the container body is required. The ratio of the volume of the propellant to the fuel becomes large, and there is a problem in safety because the change in internal pressure due to temperature change is large.

On the other hand, in the latter aerosol container using a compressed gas as a propellant, the change in internal pressure due to temperature change is small, but the internal pressure in the aerosol container decreases as the contents decrease, and the gas pressure for injection decreases. There is a problem that it is difficult to maintain a constant jet state until the contents are used up. In order to avoid this, it is necessary to increase the space for filling the gas, and there is a problem that the volume ratio of the propellant occupying in the container body increases.

Further, in these conventional aerosol containers, there is a problem that the propellant is gradually lost, and the refilling of the contents is not easy, so that it is difficult for the user to reuse the aerosol container. Was.

Therefore, an object of the present invention is to increase the volume ratio of the contents in the container body in the aerosol container, and to maintain the spraying state as constant as possible until the contents are used up. An object of the present invention is to make it possible for a user to repeatedly use an aerosol container when the contents are used up, with little loss of the propellant, facilitating refilling of the contents.

[0007]

Therefore, according to the present invention, in the aerosol container, a hydrogen storage alloy is provided in a container main body for storing contents, and hydrogen released from the hydrogen storage alloy is used as the hydrogen storage alloy. The pressure inside the container body is increased.

According to a second aspect of the present invention, in the aerosol container according to the first aspect, the hydrogen storage alloy is provided at an upper portion in the container body.

According to a third aspect of the present invention, in the aerosol container according to the first aspect, a flexible bag is provided in the container main body, the contents are stored in the bag, and the flexible bag is placed outside the bag. It is characterized by comprising the hydrogen storage alloy.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an aerosol container according to the invention with the cap removed and the injection button removed.

Reference numeral 10 in the figure is a circular can-shaped container body. The container body 10 is formed by slightly squeezing the upper opening and rounding the peripheral edge outward to form a tightening portion 10a.
The contents 12 to be ejected by the aerosol container are mainly stored in a liquid state. This content 1
The liquefied gas 2, such as liquefied dimethyl ether, is dissolved in the bubble 2, for example, when spraying in a bubble state.

[0012] The opening of such a container body 10, Bal
Mounting the blanking unit 20. The valve unit 20 includes a cylindrical housing 21 as shown in FIG. The housing 21 has a step portion a in the middle in the axial direction, and a large diameter portion 21a formed in an upper stage and a small diameter portion 21b formed in a lower stage. A plurality of vertical grooves b are provided on the inner circumference of the large-diameter portion 21a.
Is formed.

Then, the small diameter portion 21b is inserted into the upper end of the pipe 22, the pipe 22 is attached to the housing 21, and is extended downward.

On the other hand, in the large diameter portion 21a, the coil spring 23 is inserted on the step portion a, and the lower portion of the stem 24 is inserted on the coil spring 23.

The stem 24 has a spout hole 24a at the axis thereof and a neck portion 24b at an intermediate portion in the axial direction. The neck portion 24b has a lateral hole 24 communicating the spout hole 24a with the outside.
Open c. An annular plate-like stem rubber 25 is fitted around the neck 24b in a flange shape.

The stem 24 has a mountain cap 2 on the upper part.
6, and a dish-shaped mountain cap 26 is put on the housing 21 with the stem rubber 25 interposed therebetween.
The mountain cap 26 has a winding part 26a on the outer periphery.

In the present invention, for example, as shown in FIG. 1, a hydrogen storage alloy 30 is provided on the lower surface of the mountain cap 26 of the valve unit 20 constructed as described above.
Is stored in the bag 32 and attached by bonding.

Then, the pipe 22 is put into the container body 10, the housing 21 is dropped into the container body 10, and the winding portion 26a of the mountain cap 26 is
7 is tightly and airtightly wound around the winding portion 10a of the container body 10.

Although not shown, an ejection button is attached to the upper end of the stem 24. The ejection button is provided with a nozzle that communicates with the ejection hole 24 a of the stem 24 and ejects the contents 12 in the container body 10. When not in use, the container body 10 is covered with a cap (not shown) by covering the ejection button.

In the illustrated example described above, the hydrogen storage alloy 30 is housed in the bag 32 and attached to the lower surface of the mountain cap 26 by bonding. In this hydrogen storage alloy, hydrogen forms hydrides in metals and alloys.It stores a large amount of hydrogen, releases it by heating or depressurizing, stores it by cooling or pressurizing, and its release and storage are reversible. Conventionally, many hydrogen storage alloys are known.

The hydrogen storage alloy according to the present invention includes:
Iron-titanium-based alloy (FeTi), which is easy to store and release at around normal temperature and pressure, general formula RMn (where R is a rare earth element, M
Is another metal, preferably an iron group element, and n represents 3 to 5). Among these alloys, LaNi ₅ alloy or a partially substituted LaNi ₅ alloy is particularly preferred.

For example, 1 g of LaNi ₅ alloy
At 0 ° C. and 1 atm, 155 ml of hydrogen can be stored. At room temperature, it has an equilibrium pressure of 0.15 MPa. For example, if about 2 g of LaNi ₅ alloy fully storing hydrogen is put in a 200-ml container body, when the temperature is used at a constant temperature, the contents are reduced. Until it is used up
An internal pressure of 0.15 MPa can be maintained, and a constant injection state can be maintained. At this time, the pressure can be increased by increasing the temperature, and the pressure can be decreased by decreasing the temperature.

[0023] In addition, changing the part of Ni of the LaNi ₅ alloy with other metals, by changing the part of the La on the other rare earth elements, it is also possible to change the equilibrium pressure. For example, when a LaNi ₄ M (M is Cu, Fe, etc.) alloy is used, the equilibrium pressure is lowered, and the La _{0. 8} R _0.2 Ni ₅ (R is N
The use of a rare earth element alloy such as d) increases the equilibrium pressure. Thereby, an alloy corresponding to the working temperature and the optimum injection pressure can be selected as desired.

These rare-earth hydrogen storage alloys may be deteriorated by water or other liquids, and may be suspended in the contents due to powdering if hydrogen is repeatedly stored and released by use. There is.

For this reason, the hydrogen storage alloy 30 is made of a bag 32 having fine pores through which gas can pass but liquid cannot pass.
And the space inside the container body 10 where the gas is filled with the contents 12. The bag 32 is made of, for example, resin or rubber.

The hydrogen storage alloy 30 is, for example,
2 and attached to the mountain cap 26 of the valve unit 20 and then placed in a hydrogen stream of about 1 MPa to store hydrogen, and then placed in a low-temperature storage container and maintained at a balanced hydrogen pressure. Use what was done.

In the illustrated aerosol container, hydrogen is released from the hydrogen storage alloy 30 and the space above the contents 12 is filled with hydrogen, and the pressure in the container body 10 is increased. The contents 12 therein rise in the pipe 22.

When using this aerosol container, the cap (not shown) is removed and the container body 10 is removed.
Hold the hand and point the nozzle of the injection button toward the injection target site. Then, the injection button is pressed down, and that state is maintained.

Then, the stem 24 is pushed into the housing 21 against the coil spring 23 and deforms the stem rubber 25 to form a gap between the stem 24 and the stem 24.
Is communicated with the inside of the container body 10.

Then, due to the pressure in the container body 10, the contents 12 rise up the pipe 22 and enter the ejection hole 24a from the horizontal hole 24c of the stem 24 through the vertical groove b formed in the housing 21. From the spray button and spray from the nozzle of the spray button.

When the hand is released from the injection button of the aerosol container, the stem 24 returns by the spring force of the coil spring 23, and the deformation of the stem rubber 25 is released. The lateral hole 24c and the container body 10 are not communicated with each other, and the injection is terminated.

The amount of the hydrogen storage alloy used is, for example, used in a container having an inner volume of 200 ml.
To maintain the internal pressure at 0.4 MPa, the pressure may be about 5.2 g. Here, the specific gravity of this alloy is about 7 without hydrogen storage, and when hydrogen is stored, it is reduced by about 10%. However, in any case, it is only about 1 ml. The volume is extremely small compared to the case of compressed gas or compressed gas. Therefore, according to the aerosol container of the present invention, the volume ratio of the propellant in the container body can be significantly reduced.

Then, the content 12 gradually decreases and finally almost disappears, but until that point, the hydrogen storage alloy 30 continues to release hydrogen, and at a constant temperature, the pressure inside the container body 10 is reduced. Is kept constant. Therefore, in the aerosol container of the present invention, a constant jet state can be maintained until the contents 12 are used up.

Moreover, when the aerosol container is cooled when the contents 12 are used up, the hydrogen storage alloy 30 stores hydrogen, and the pressure drops to a pressure corresponding to the performance. Depending on the type of hydrogen storage alloy 30 used, it can be at or below atmospheric pressure and in this state it is easy to introduce the contents from the refill via the stem 24. . Moreover, as described above, since hydrogen can be stored again in the original hydrogen storage alloy by cooling, there is almost no loss of hydrogen. Therefore, the aerosol container of the present invention can be used repeatedly by the user.

By the way, in the illustrated example described above, the hydrogen storage alloy 30 is put in the bag 32 and provided on the upper part in the container main body 10. For example, as shown in FIG.
A flexible bag 33 is provided therein, and the contents 12 are contained in the flexible bag 33.
And the hydrogen storage alloy 3
4 may be provided.

In FIG. 3, the reference numerals used for the corresponding parts of the aerosol container shown in FIGS. 1 and 2 are used as they are, and redundant description is omitted. Note that FIG.
In the illustrated example, since a pipe is not required, it is not included in the valve unit 20. However, a pipe may be required for the valve unit 20 in some cases.

In FIG. 3, the newly added reference numeral 33 is
It is a flexible bag provided in the container body 10. As the flexible bag 33, the inner container of a double-structured container that has recently been increasingly used as an aerosol container may be used as it is.

The contents 12 are stored in the flexible bag 33, and a hydrogen storage alloy 34 is further filled with a fine mesh bag or a resin or rubber bag 36 having many pores. And prepare it. At this time, for example, it is lightly bonded to the inner bottom surface of the container body 10 with an adhesive. Adhesion is not always necessary, but it is better to adhere to prevent abnormal noise or deterioration of the alloy due to contact with the container body 10.

The hydrogen storage alloy 34 is, for example,
6 and placed in a 1 MPa normal-temperature hydrogen stream to store hydrogen, and then placed in a low-temperature storage vessel and maintained at an equilibrium hydrogen pressure.

Then, the hydrogen storage alloy 34 is adhered to the inner bottom surface of the container body 10 as described above, and then the flexible bag 3
3 is installed.

In the illustrated aerosol container, hydrogen is released from the hydrogen storage alloy 34, and the pressure is applied to the flexible bag 3.
When the container 3 is contracted to increase the pressure in the container body 10 and the ejection button is pressed down, the contents 12 stored in the flexible bag 33 are ejected from the nozzle of the ejection button through the valve unit 20.

Since the hydrogen storage alloy and the contents are merely separated by a flexible bag, and the other points are the same as those in the above-described embodiment, a constant jetting state is maintained until the contents 12 are used up. Also, when the contents 12 are used up, the aerosol container is cooled and hydrogen is stored again in the hydrogen storage alloy 34, so that there is almost no loss of hydrogen, and the contents 12 can be easily refilled. Therefore, the user can use the aerosol container repeatedly as in the above-described example.

[0043]

Therefore, according to the present invention, the pressure inside the container body is increased by the hydrogen released from the hydrogen storage alloy without using the liquefied gas or the compressed gas as in the prior art. The volume ratio occupying the main body can be increased, and a constant jetting state can be maintained until the contents are used up. In addition, when the contents are used up, the loss of hydrogen is almost eliminated, and the contents can be easily refilled. Therefore, the user can repeatedly use the aerosol container.

According to the second aspect of the present invention, it is not necessary to particularly provide an inner bag (flexible bag) in the container body, so that the effect of the first aspect can be easily achieved and the number of members can be reduced. Can be reduced.

According to the third aspect of the present invention, a bag containing the hydrogen storage alloy is provided in another space separated from the contents of the container body by the flexible bag. And the loss of hydrogen as the injection gas can be more completely prevented, and the effect of claim 1 can be further achieved.

[Brief description of the drawings]

FIG. 1 is an overall schematic configuration diagram of an aerosol container of the present invention.

FIG. 2 is a longitudinal sectional view of a valve unit used in the aerosol container.

FIG. 3 is an overall schematic configuration diagram of an aerosol container according to another example of the present invention.

DESCRIPTION OF SYMBOLS 10 Container main body 12 Contents 20 Valve unit 21 Housing 22 Pipe 23 Coil spring 24 Stem 24a Spray hole 24c Side hole 25 Stem rubber 26 Mountain cap 30 ・ 34 Hydrogen storage alloy 32 ・ 36 bag 33 Flexible bag

Claims (3)

[Claims] An aerosol container comprising a hydrogen storage alloy in a container main body for storing contents, and increasing the pressure in the container main body with hydrogen released from the hydrogen storage alloy. 2. The aerosol container according to claim 1, wherein the hydrogen storage alloy is provided at an upper part in the container main body. 3. The container according to claim 1, wherein a flexible bag is provided in the container body, the contents are stored in the bag, and the hydrogen storage alloy is provided outside the bag. Aerosol container.