KR20030002000A - Over pressure safety apparatus of aerosol cans - Google Patents

Abstract

PURPOSE: An over-pressure safety device of an aerosol container is provided to prevent such dangers as the deformation and bursting of the aerosol container by discharging gas before the pressure of the aerosol container reaches a deforming pressure or a bursting. CONSTITUTION: A nozzle assembly(200) of an aerosol container(100) comprises a nozzle body(210) supported on the inner center of a support member(116), an upper and a lower valve stems(220,230) for jetting the gas filled in the aerosol container, a sealing body(240) for opening and closing a gas inlet(232) of the lower valve stem, an over-pressure safety spring(250) applying a force in the direction by which the over-pressure safety valve is adhered to the upper portion of the gas inlet of the lower valve stem, an elastic spring(252) elastically supporting the lower valve stem at the lower portion of the lower valve stem, a rubber opening and closing spring(260) for opening and closing a gas inlet(222) of the upper valve stem, and a connecting unit(284) for combining the upper valve stem with the lower valve stem.

Description

Over pressure safety apparatus of aerosol cans

The present invention relates to an overpressure stabilizer of an aerosol container, and more particularly, to a deformation of an aerosol container when the internal pressure of an aerosol container such as a portable gas container, a spray mosquito drug, a hair spray, a portable aerosol fire extinguisher, a gas lighter and the like increases to a predetermined pressure or more. An overpressure safety device for an aerosol container in which a gas is ejected prior to the pressure or burst pressure to prevent the risk of deformation and bursting.

In general, aerosol cans are filled with the contents to be injected (fluid or gas) inside the container and sealed together with the injection gas (propellant or propellant gas) by using the pressure of the injection gas or gas (hereinafter referred to as "aerosol cans"). Refers to a container for injecting gas outwardly. At this time, as the injection gas, gases such as LPG, DME, Freon, carbon dioxide, nitrogen and oxygen are used. Representative examples of such aerosol containers include portable gas containers, spray mosquito repellents, hair sprays, portable aerosol fire extinguishers, and gas lighters. For example.

On the other hand, aerosol containers such as portable gas containers, spray mosquitoes, hair sprays, portable aerosol fire extinguishers, gas lighters, etc., as described above, use a gas filled therein to eject the contents, so that a certain pressure is applied to prevent internal pressure. If it becomes high, there is a risk of deformation and rupture of the container.

1 is a longitudinal cross-sectional view showing an embodiment of a conventional aerosol container, Figure 2 is a longitudinal cross-sectional view showing the action when using the aerosol container according to FIG.

1 and 2 show an aerosol container, the conventional aerosol container 10 as shown in the figure is a cylindrical container body 12 for filling gas, the container body 12 for sealing the container body 12 The container body is installed on the upper and lower sealing caps (14, 14a) and the support member (20) that is crimped to the center of the upper sealing cap 14, which is integrally joined to the upper and lower parts of the It consists of a nozzle assembly 30 for injecting the gas filled in the interior (12).

The nozzle assembly 30 described above has a predetermined space portion 32a formed therein, the upper portion of which is open and the lower portion of the gas inlet 32b, which is coupled to and supported by the inner center of the support member 20. The body 32, the gas inlet 34a through which the gas filled in the container body 12 flows, and a gas injection port 34b for injecting the gas introduced into the gas inlet 34a into the outside is formed to support the member 20. The valve stem 34 and the gas inlet 34a formed at the center of the valve stem 34 are formed on the outer periphery of the valve stem 34 and the valve stem 34 is opened and closed to open and close the gas inlet 34a. 20 and an elastic ring 38 for elastically supporting the valve stem 34 at the lower side of the valve stem 34 inside the container body 12 and the opening / closing ring 36 for sealing the valve stem 34 with the valve stem 34. Is done.

Looking at the assembly structure of the nozzle assembly 30 described above, the valve stem 34, the opening and closing ring 36 and the elastic spring in the space 32a of the nozzle body 32 coupled to the inner center of the support member 20 38 is provided and the valve stem 34 is elastically supported by the elastic spring 38. As shown in FIG.

In the conventional portable gas container 10 configured as described above, when the valve stem 34 is pressed into the container body 12 by an external force, the gas inlet 34a is opened by the elastic deformation of the opening / closing ring 36. As the gas in the portable gas container 10 flows into the gas inlet 34a of the valve stem 34, the gas introduced into the gas inlet 34a is injected into the outside air through the gas injection port 34b.

Meanwhile, the conventional portable gas container 10 configured as described above is partially filled with the gas inlet 34a through the gas injection hole 34b when the initial gas is filled, and the rest of the conventional gas valve 34 and the valve stem ( 34 is filled in the gap of the support member 20 through.

However, when the conventional portable gas container as described above is subjected to an impact or a heat source from the outside, the liquefied petroleum gas filled therein may easily vaporize and burst with expansion. Therefore, there is always a risk that can cause fire and personal injury due to rupture.

Therefore, as a means for delaying or preventing the rupture of the portable gas container, the upper and lower sealing caps are formed in a bent and curved shape to secure a free space in consideration of the expansion of the liquefied petroleum gas filled with the upper and lower sealing caps. However, when the liquefied petroleum gas is expanded, the upper and lower sealing caps are opened or convex, so that the expansion of the filled liquefied petroleum gas continues even when the volume inside the portable gas container is at maximum. The joint portion of the sealing cap is separated and the portable gas container is ruptured.

As mentioned above, although there is always a risk of rupture, the portable gas container is still used in outdoor as well as at home due to its convenience and portability, but efforts to minimize the risk of rupture are still insufficient. One situation.

The present invention has been made to solve the above problems, the gas before the deformation pressure or burst pressure of the aerosol container when the internal pressure of the aerosol container such as a portable gas container, hair spray, simple fire extinguisher, gas lighter is higher than a certain pressure It is an object of the present invention to provide an overpressure safety device for an aerosol container that can prevent the risk of deformation and rupture by ejecting it.

Another object of the present invention is to improve the reliability of the aerosol container product by allowing the gas to be ejected before the deformation pressure or the burst pressure of the aerosol container to prevent the risk of deformation and burst.

It is another object of the present invention to prevent damage to property or damage to life by preventing the risk of deformation and rupture by ejecting the gas prior to the deformation pressure of the aerosol container.

1 is a longitudinal sectional view showing one embodiment of a conventional aerosol container;

Figure 2 is a longitudinal sectional view showing the action of the aerosol container according to Figure 1 in use.

Figure 3 is a longitudinal sectional view showing an aerosol container is configured with an overpressure safety device according to the present invention.

Figure 4 is a longitudinal cross-sectional view showing the action when using the aerosol container configured overpressure safety device according to the present invention.

Figure 5 is a longitudinal sectional view showing the action according to the overpressure of the aerosol container is configured with an overpressure safety device according to the present invention.

** Description of symbols for the main parts of the drawing **

100. Aerosol container 110. Container body

112. Upper Cap 114. Lower Cap

116. Support member 116a. Through Groove

200. Nozzle Assembly 210. Nozzle Body

212. Space section 220. Upper valve stem

222. Gas inlet 224. Gas injection port

226. Space section 230. Lower valve stem

232. Gas inlet 240. Sealing body

250. Overpressure safety springs 252. Elastic springs

260. Opening and closing ring 284. Fastening part

The present invention configured to achieve the above object is as follows. That is, the nozzle assembly as the overpressure safety device of the aerosol container according to the present invention is a predetermined space portion is formed therein, the upper portion is open, the lower portion is a gas inlet is formed in the nozzle body which is supported on the inner center of the support member; A gas inlet for injecting the gas introduced into the space portion of the nozzle body and a gas injection port for injecting the gas introduced into the gas inlet to the outside are formed, and a predetermined space is formed inside the lower side to open the space of the nozzle body. An upper valve stem installed in the unit; A lower valve stem which is formed to be in close contact with a lower end surface of the upper valve stem so that a gas inlet is formed to penetrate up and down to allow gas to flow into the space of the upper valve stem; A sealing body installed above the gas inlet of the lower valve stem to open and close the gas inlet of the lower valve stem; An overpressure safety spring in which elasticity is provided between the upper end surface of the inner space of the upper valve stem and the upper end surface of the sealing member so that the force is always in close contact with the upper portion of the gas inlet of the lower valve stem; An elastic spring for elastically supporting the valve stem at a lower side of the lower valve stem; It is made of an opening / closing ring of rubber material which is supported between the support member and the upper end of the nozzle body in a state of being fitted on the outer circumference of the gas inlet of the upper valve stem to open and close the gas inlet by the up / down action of the upper valve stem.

In the above configuration, the overpressure safety spring is such that when the internal pressure of the aerosol container is increased to a predetermined pressure or more, the sealing body is moved upward so that the gas inlet of the lower valve stem can be opened before the predetermined pressure of the aerosol container, and the internal pressure of the aerosol container is constant pressure. If it is lowered below, the seal is in place so that the gas inlet of the lower valve stem can be closed.

As described above, the aerosol container configured with the overpressure safety device according to the present invention is configured to prevent the possibility of deformation and rupture and consequent fire and personal injury caused by the problems of the conventional aerosol container.

That is, the gas inlet of the lower valve stem is opened before the deformation pressure and the burst pressure of the aerosol container due to the expansion of the gas filled in the aerosol container so that the filled gas in the aerosol container can be ejected in advance. It is to prevent rupture after deformation.

The aerosol container equipped with the overpressure safety device of the present invention to be described below can be applied to both aerosol containers made of synthetic resin, steel or aluminum.

The portable gas container of FIGS. 3 to 5 described in the detailed description of the present invention is merely one example of an aerosol container, and the overpressure safety device of the present invention is not limited to the portable gas container. Therefore, it is obvious that the overpressure safety device according to the present invention can be applied not only to portable gas containers but also to all aerosol containers such as spray mosquitoes, hair sprays, portable aerosol fire extinguishers, gas lighters and the like.

On the other hand, the predetermined pressure described in the features of the configuration according to the present invention, the detailed description of the invention and the claims as described above refers to the deformation pressure or bursting pressure, the deformation pressure for the bonding vessel of the high pressure gas safety management regulations Is 13 kg / cm 2 and the burst pressure is 15 kg / cm 2.

Hereinafter, the overpressure safety device of the aerosol container according to a preferred embodiment of the present invention with reference to the drawings in detail.

Figure 3 is a longitudinal sectional view showing an aerosol container configured with an overpressure safety device according to the present invention, Figure 4 is a longitudinal sectional view showing the action when using an aerosol container configured with an overpressure safety device according to the present invention, Figure 5 is an overpressure safety according to the present invention Longitudinal sectional view showing the effect of overpressure of the aerosol vessel in which the device is constructed.

3 to 5 show a portable gas container as an aerosol container, which will be referred to as an aerosol container in the following description. 3 to 5, the aerosol container 100 configured with the overpressure safety device according to the present invention is also a cylindrical container body 110, bent and formed in a predetermined shape to be connected to the upper portion of the container body 110 The upper sealing cap 112 is coupled to the inner surface of the container body 110, concave curved, formed, the lower sealing cap 114, which is coupled to the lower portion of the container body 110, the center of the upper sealing cap 112 The nozzle assembly 200 is installed at the center of the support member 116 and the support member 116 to be compressed and coupled to support the nozzle assembly 120 to be described later to inject the gas filled in the container body 110 The present invention is the same as the conventional art, but the present invention improves the configuration of the nozzle assembly 200 so that the gas inside the aerosol container 100 can be discharged to the outside when the internal pressure of the aerosol container 100 becomes higher than a predetermined pressure. will be.

The nozzle assembly 200 of the aerosol container 100 according to the present invention has a large space portion 212 is formed in the inner side of the nozzle body 210, the nozzle body 210 is supported at the inner center of the support member 116 A seal 240 installed in the space 212 to open and close the upper and lower valve stems 220 and 230 for injecting the gas filled in the aerosol container 100 and the gas inlet 232 of the lower valve stem 230. ), The overpressure safety spring 250 and the lower valve stem 230 at the lower side of the valve actuated in the direction in which the seal 240 is always in close contact with the upper portion of the gas inlet 232 of the lower valve stem 230 An elastic spring 252 for elastically supporting the stem, an opening / closing ring 260 of rubber material for opening / closing the gas inlet 222 of the upper valve stem 220 by the entry / exit action of the upper valve stem 220, and the upper valve stem 220. ) And a fastening part 284 for coupling between the lower valve stem 230.

The present invention through the configuration as described above, the internal pressure of the aerosol container 100 is raised to a predetermined pressure or more, when the force to overcome the elastic force of the overpressure safety spring 250 is applied to the sealing member 240 is raised by the internal pressure to lower the valve When the gas inlet 232 of the stem 230 is opened, the filled gas is discharged to outside air so that the internal pressure of the aerosol container 100 can be lowered, while the internal pressure of the aerosol container 100 is lowered below a predetermined pressure. The sealing body 240 is in place so that the gas inlet 232 of the lower valve stem 230 can be closed.

Hereinafter, the nozzle assembly 200 of the aerosol container 100 according to the present invention will be described in detail. First, the nozzle body 210 of the upper and lower valve stems 220 and 230, the sealing body 240, the overpressure safety spring 250, the elastic spring 252, the opening and closing ring 260, the fastening portion 284 The nozzle body 200 is for constituting an element constituting the inside, the nozzle body 210 has a predetermined space portion 212 is formed therein, the upper portion is open and the lower gas inlet 214 Is formed is coupled to the inner center of the support member 116 is supported.

The valve stems 220 and 230 are for injecting the introduced gas into the outside air, and the valve stems 220 and 230 in the present invention have a structure of the upper valve stem 220 and the lower valve stem 230.

First, the upper valve stem 220 is installed in the longitudinal direction on the space portion 212 of the nozzle body 210 is pressed and released by the pressing means of the device for using the aerosol container 100 and elasticity to be described later The spring 252 is lifted by the elastic action.

The upper valve stem 220 has a gas inlet 222 through which the gas introduced into the space 212 of the nozzle body 210 flows, and a gas injection port for injecting the gas introduced into the gas inlet 222 to the outside ( 224, a space portion 226 having a lower portion formed in an open shape, and a fastening portion 284 formed on an outer circumferential surface of the upper valve stem 220 at the lower side of the gas inlet 222. At this time, the gas inlet 222 is formed laterally on the upper side of the fastening portion 284, the gas injection port 224 is in communication with the gas inlet 222 and the space portion 226 of the upper valve stem 220 It is formed in the longitudinal direction.

The lower valve stem 230 is one of the overpressure safety devices, and the lower valve stem 230 includes a gas inlet 232 penetrated in the longitudinal direction and a fastening part 284 coupled to the upper valve stem 220. It is installed on the lower side of the upper valve stem 220.

The lower valve stem 230 configured as described above has a predetermined or more overpressure inside the aerosol container 100 so that the sealing body 240 to be described later is pushed upward to open the gas inlet 232 of the lower valve stem 230. In this case, the gas of the overpressure is discharged through the space part 226 of the upper valve stem 220.

The sealing body 240 is for opening and closing the gas inlet 232 of the lower valve stem 230, and the sealing body 240 is installed at the upper end of the lower valve stem 230 so as to be a safe gas pressure. 232 is closed and the gas inlet 232 of the lower valve stem 230 is pushed upward by the overpressure when an overpressure occurs to overcome the elastic force of the overpressure safety spring 250 to be described later in the aerosol container 100. Will open.

On the other hand, the above-mentioned sealing body 240 is the elastic force of the overpressure safety spring 250 to be described later when the pressure inside the aerosol container 100 is restored to a predetermined pressure or less after the overpressure in the aerosol container 100 is discharged to the outside air As a result, the gas inlet 232 of the lower valve stem 230 is closed.

The overpressure safety spring 250 is to close the gas inlet 232 of the lower valve stem 230 through the elastic force by contacting the sealing member 240 to the upper surface of the lower valve stem 230, such overpressure safety The spring 250 is elastically installed between the upper portion of the inner surface of the space portion 226 of the upper valve stem 220 and the upper end of the seal 240 to seal the seal 240 with the upper surface of the lower valve stem 230. The force acts in the direction of always close contact.

The overpressure safety spring 250 installed as described above is compressed by pushing the seal 240 upward by the overpressure when a certain pressure or more that overcomes the elastic force of the overpressure safety spring 250 inside the aerosol container 100 occurs. When the pressure inside the aerosol container 100 is restored to a predetermined pressure or less by the discharge of the overpressure, the gas inlet 232 of the lower valve stem 230 is closed by the sealant 240.

Therefore, it can be seen that the above-mentioned pressure relief spring 250 is elastically deformed when a pressure close to the deformation pressure or the burst pressure of the aerosol container 100 acts on the interior of the aerosol container 100.

That is, the overpressure safety spring 250 installed as described above is in close contact with the sealing member 240 in the direction of the upper surface of the lower valve stem 230 through the elastic force to overcome the elastic force of the overpressure safety spring 250 acts. Unless the sealing member 240 is in close contact with the upper surface of the lower valve stem 230 to prevent the gas inlet 232 of the lower valve stem 230 is opened.

In more detail, when the overpressure safety spring 250 described above has an internal pressure of the aerosol container 100 at a predetermined pressure or more, that is, a force that overcomes the elastic force of the overpressure safety spring 250 is applied. The overpressure safety spring 250 is compressed. In this case, the compression of the overpressure safety spring 250 may indicate that the sealing member 240 is pushed up by the pressure acting inside the aerosol container 100.

Therefore, the overpressure gas filled in the aerosol container 100 flows into the gas inlet 232 of the lower valve stem 230 and is discharged to the outside air through the gas injection port 224 of the upper balance stem 220. The pressure inside the aerosol container 100 is lowered. As such, when the pressure inside the aerosol container 100 is lowered and the pressure inside the aerosol container 100 becomes smaller than the elastic force of the overpressure safety spring 250, the overpressure safety spring 250 is tensilely restored to seal the seal 240. The gas inlet 232 of the lower valve stem 230 is closed by returning to the top surface of the stem 230 to block the discharge of the gas.

The elastic spring 252 is for close contact with the lower valve stem 230 to the upper valve stem 220 through the elastic force, and also to closely contact the upper valve stem 220 in the direction of the lower surface of the support member 116. The elastic spring 252 is elastically installed between the inner lower surface of the space portion 212 of the nozzle body 210 in a state of being fitted to the lower outer periphery of the lower valve stem 230 to move the lower valve stem 230 to the upper valve stem. The force acts on the 220 and in a direction that always keeps the upper valve stem 220 in the direction of the lower surface of the support member 116.

On the other hand, the above-mentioned elastic spring 252 is compressed when the upper valve stem 220 is pressed down by the pressing means of the device for using the aerosol container 100, pressurized for using the aerosol container 100 When the pressure by the means is released, the elastic spring 252 is tension-restored to return the upper valve stem 220 to its original position.

Rubber opening and closing ring 260 is to open and close the gas inlet 222 of the upper valve stem 220 as described above, the opening and closing ring 260 is the outer periphery of the gas inlet 222 of the upper valve stem 220 It is supported on the upper end of the nozzle body 210 in the state fitted. At this time, the opening and closing ring 260 is supported by the upper end of the nozzle body 210 is in a state that can no longer go down.

As described above, the rubber opening / closing ring 260 fitted to the outer circumference of the gas inlet 222 of the upper valve stem 220 is pressurized by the upper valve stem 220 by the pressurizing means of the device for using the aerosol container 100. As it descends, as shown in FIG. 4, the opening and closing ring 260 is elastically deformed in a supported state. Accordingly, the gas inlet 222 of the upper valve stem 220 is opened so that the gas filled in the aerosol container 100 may be introduced through the gas inlet 222 and discharged to the outside through the gas inlet 224. Will be.

As described above, the gas filled in the aerosol container 100 can be introduced through the gas inlet 222 to be discharged to the outside through the gas injection port 224 of the apparatus for using the aerosol container 100 When the pressure by the pressing means is released, the upper valve stem 220 is returned to its original position by the restoring force of the elastic spring 252, and thus the gas inlet 222 is closed by the opening and closing ring 260.

The fastening part 284 seals between the upper valve stem 220 and the lower valve stem 230 to normally fill the gas inside the aerosol container 100 through the upper valve stem 220 and the lower valve stem 230. To prevent leakage.

Looking at the effect of the aerosol container 100 is configured with an overpressure safety device according to the present invention configured as described above are as follows. First, the upper valve stem 220 is pressurized by the pressing means (external force) of the device for using the aerosol container 100 as shown in Figure 4 in the absence of an external force pressing the upper valve stem 220 as shown in FIG. When the gas is lowered, the gas inlet 222 of the upper valve stem 220 is opened by the elastic deformation of the opening / closing ring 260, so that the gas in the aerosol container 100 flows into the gas inlet 222 of the upper valve stem 220. Inflow is injected into the outside air through the gas injection port (224).

On the other hand, when the pressurization by the pressurizing means of the device for using the aerosol container 100, the elastic spring 252 is restored as shown in Figure 3 to restore the upper valve stem 220, and accordingly the upper valve stem ( Gas inlet 222 of 220 is closed by the opening and closing ring 260.

Meanwhile, as shown in FIG. 3, the internal pressure of the aerosol container 100 is increased to a predetermined pressure or more in a state in which there is no external force that pushes the upper valve stem 220 or the pushing force of the overpressure safety valve 240 to increase the pressure of the aerosol container 100. When approaching the deformation pressure or the bursting pressure, as shown in FIG. 5, the overpressure of the aerosol container 100 pushes up the sealing body 240, thereby opening the gas inlet 232 of the lower valve stem 230. The overpressure gas inside the aerosol container 100 is discharged to the outside air through the gas injection port 224 of the upper valve stem 220.

On the other hand, when the pressure inside the aerosol container 100 is lowered through the discharge of the overpressure gas, and the pressure inside the aerosol container 100 becomes smaller than the elastic force of the overpressure safety spring 250, the overpressure safety spring 250 is tension-restored and sealed. The sieve (ball, 240) to the upper surface of the lower valve stem 230 to close the gas inlet 232 of the lower valve stem 230 to block the discharge of gas.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

As described above, according to the present invention, when the internal pressure of an aerosol container such as a portable gas container, a hair spray, a simple fire extinguisher is increased above a predetermined pressure, the gas is ejected before the deformation pressure or the burst pressure of the aerosol container to reduce the risk of deformation and rupture. The preventable effect is exerted.

Another effect of the present invention is to improve the reliability of the aerosol container product by allowing the gas to be ejected prior to the deformation pressure or rupture force of the aerosol container to prevent the risk of deformation and rupture.

Another effect of the present invention is to prevent the risk of property damage or human life by ejecting the gas before the deformation pressure and the burst pressure of the aerosol container to prevent the risk of deformation and rupture.

In addition, the sealing body in the present invention by replacing the O-ring (Rubber seal) of the rubber material used in the conventional overpressure safety device with a ball for bearing to enhance durability and chemical resistance In addition, by reducing the parts and production process, it is possible to maximize the economic effect by lowering the manufacturing cost and productivity of the aerosol container.

Claims (4)

An aerosol container having a container body, a sealing cap coupled to the container body, a support member coupled to the upper sealing cap, and a nozzle assembly installed at a center of an inner surface of the support member to inject a gas filled therein. The nozzle assembly has a predetermined space portion formed therein, the upper portion is open, the lower portion is a gas inlet is formed in the nozzle body which is supported on the inner center of the support member; A gas inlet for injecting the gas introduced into the space portion of the nozzle body and a gas injection port for injecting the gas introduced into the gas inlet to the outside are formed, and a predetermined space is formed therein so that the lower side is opened to form the nozzle. An upper valve stem installed in a space of the body; A lower valve stem which is formed in close contact with a lower surface of the upper valve stem through a gas inlet formed through the gas inlet so that the gas flows into the space of the upper valve stem; A sealing body installed above the gas inlet of the lower valve stem to open and close the gas inlet of the lower valve stem; An overpressure safety spring in which elasticity is installed between the upper end surface of the inner space of the upper valve stem and the upper end surface of the seal body so that the force is always in close contact with the upper portion of the gas inlet of the lower valve stem. ; An elastic spring elastically acting between a lower end of the lower valve stem and a space inner lower end of the nozzle body; An opening / closing ring of a rubber material that is supported between the support member and the nozzle body upper end in a state of being fitted on the outer circumference of the gas inlet of the upper valve stem to open and close the gas inlet by an up / down action of the upper valve stem; When the internal pressure of the aerosol container is increased to a predetermined pressure or more, and a force that overcomes the elastic force of the overpressure safety spring acts, the sealing body is raised by internal pressure, and the gas inlet of the lower valve stem is opened to discharge the filled gas to the outside air. When the pressure inside the aerosol container becomes lower than the elastic force of the overpressure safety spring through the discharge of the overpressure gas, the sealing body is repositioned to close the gas inlet of the lower valve stem to block the discharge of the gas. Overpressure safety device of the aerosol container, characterized in that it is made to be. The method of claim 1, wherein the elastic force of the overpressure safety spring is formed to be smaller than the burst pressure of the aerosol container so that when the internal pressure of the aerosol container is higher than a predetermined pressure, the seal is moved upwards before the burst pressure of the aerosol container. The gas inlet of the lower valve stem can be opened, and when the internal pressure of the aerosol container is lowered to a predetermined pressure or less, the sealing body is returned to the overpressure safety of the aerosol container, characterized in that the gas inlet of the lower valve stem can be closed. Device. The overpressure safety device of an aerosol container according to claim 1, wherein the seal is formed of a ball for bearing having excellent durability, sealability, chemical resistance and gas resistance. The overpressure safety device of an aerosol container according to claim 2, wherein the elastic force of the overpressure safety spring is smaller than the burst pressure of the aerosol container.