KR102613780B1 - How to fill compressed air in an aerosol spray container - Google Patents

Abstract

The present invention relates to a method for charging compressed air in an aerosol spray container, wherein the air filled inside the aerosol spray container for various cosmetics, air fresheners, and insecticides is charged using atmospheric air rather than using LPG gas. It is about a technology that reduces costs, lowers the risk of explosion, and greatly improves the capacity of the undiluted solution compared to the capacity of the container.
That is, the present invention includes the steps of preparing a spray container, injecting a certain amount of stock solution into the spray container, compressing and supplying atmospheric air through an air compressor, and storing the supplied atmospheric air in a high pressure tank. A step of receiving atmospheric air stored in the high-pressure tank and removing moisture in an air drying device, filtering foreign substances in the atmospheric air from which the moisture has been removed, and converting the atmospheric air from which the foreign substances have been removed into an undiluted solution. It is characterized in that it consists of the step of injecting the injected spray container at a certain pressure.

Description

{How to fill compressed air in an aerosol spray container}

The present invention relates to a method for charging compressed air in an aerosol spray container, wherein the air filled inside the aerosol spray container for various cosmetics, air fresheners, and insecticides is charged using atmospheric air rather than using LPG gas. It is about a technology that reduces costs, lowers the risk of explosion, and greatly improves the capacity of the undiluted solution compared to the capacity of the container.

In general, most aerosol sprays are filled with a liquid solution (contents) and gaseous gas inside the container, and the solution is discharged to the outside by pressing a nozzle installed on the top of the container. At this time, depending on the type of the concentrate, it is used for various purposes such as mist sprayed on the skin, hair spray, air freshener, and insecticide.

The high-pressure gas filled in the aerosol spray is filled with strong pressure to discharge the raw solution to the outside, and the gas filled in the container so far has been LPG gas.

However, the charging method using LPG gas has a problem in that the container can only be filled with 30% of the total capacity of the container, as shown in Figure 1. Due to the nature of LPG gas, it has no choice but to be filled at a pressure of 4 to 5 bar, so the above ratio must be maintained in order for the undiluted solution to be fully discharged. Therefore, the LPG gas occupies 50% of the container, and the remaining 20% is occupied by the expansion space of the LPG gas.

In addition, due to the risk of explosion of LPG gas, the container must be made of metal material such as aluminum or iron, which leads to an increase in the manufacturing cost of the container.

As related prior art, Patent Registration No. 10-0694795 (Toilet water spray can using oxygen propellant) includes a pressure-sealed container filled with cosmetic water and oxygen as a propellant for spraying the lotion, and a pressure-sealed container provided at the top of the pressure-sealed container. It consists of a valve body, and a technology is disclosed in which oxygen is filled at a rate of 28g to 32g with respect to the filling volume of 350ml of the pressure-tight container.

The above prior art is filled with high-concentration oxygen, and since high-concentration oxygen cannot be produced inside the manufacturing facility, high-concentration oxygen purified outside the manufacturing facility is placed in a dedicated gas container, transported inside the manufacturing facility, and injected into a spray can. There is a problem in that the efficiency of manufacturing decreases and the manufacturing cost increases, and because high concentrations of oxygen also have the risk of explosion, there is a problem that the spray can must be made of metal.

Registration Patent No. 10-0694795 (Toilet spray can using oxygen propellant)

The present invention was developed to solve the above problems. Instead of using existing LPG gas as a high-pressure gas for discharging the raw solution inside an aerosol spray container, it uses a charging device provided in the manufacturing facility itself to replace the high-pressure gas in the atmosphere. It increases productivity by injecting air, lowers the risk of explosion while increasing the capacity of the raw solution, improves stability and space utilization, and prevents deterioration of the raw liquid by going through a purification process rather than directly injecting atmospheric air. The purpose is to provide a method of charging compressed air for an aerosol spray container.

The present invention includes the steps of preparing a spray container, injecting a certain amount of stock solution into the spray container, compressing and supplying atmospheric air through an air compressor, and storing the supplied atmospheric air in a high pressure tank. A step of removing moisture in an air dryer by receiving atmospheric air stored in the high-pressure tank, filtering foreign substances in the atmospheric air from which the moisture has been removed, and injecting the atmospheric air from which the foreign substances have been removed with an undiluted solution. Characterized by the step of injecting into a spray container at a certain pressure.

In addition, in the step of storing in the high-pressure tank, the temperature inside the high-pressure tank is heated to a temperature of 60 to 80 ℃ and supplied to the next process.

Additionally, the step of removing moisture from the air drying device is characterized by condensing and removing moisture from the input atmospheric air through heat exchange with a condenser provided in the air drying device.

In addition, the step of injecting the spray container at a constant pressure is characterized in that the pressure of the atmospheric air filled inside the spray container is injected to a pressure of 9 bar to 10 bar.

In the present invention, the effects obtained through the compressed air charging method of an aerosol spray container using atmospheric air are as follows.

First, there is no risk of explosion. Compared to the previously used LPG gas, there is no risk of explosion and stability can be improved when used.

Second, manufacturing costs can be reduced and productivity can be increased. By injecting air internally within the production facility rather than procuring compressed air from outside, the cost of supplying compressed air can be reduced while continuous air injection is possible, thereby increasing productivity. In addition, since there is no risk of explosion, the container material can be made of plastic, which can greatly reduce the unit cost of the container.

Third, it is harmless to the human body and eco-friendly. Instead of directly injecting atmospheric air, it goes through a moisture removal and foreign matter removal process to prevent deterioration of the raw solution and prevent harm to the human body when used in cosmetics such as mist.

Figure 1 is a diagram showing the durability ratio of a spray container filled with conventional LPG gas.
Figure 2 is a diagram showing a method of charging compressed air for an aerosol spray container of the present invention.
Figure 3 is a diagram showing an example of installation of an air compressor, high pressure tank, and air drying device used in the charging method according to the present invention.
Figure 4 is a view showing the durability ratio of the spray container manufactured by the filling method of the present invention
Figure 5 is a diagram showing an example of installation of an air compressor, high pressure tank, and air drying device applying another embodiment of the charging method according to the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the attached drawings. Also, in describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

The method of charging compressed air for an aerosol spray container of the present invention includes preparing a spray container (S-1) as shown in FIG. 2, and injecting a certain amount of stock solution into the spray container (S-2), A step of compressing and supplying atmospheric air through an air compressor (S-3), a step of storing the supplied atmospheric air in a high pressure tank (S-4), and air drying by receiving atmospheric air stored in the high pressure tank. A step of removing moisture from the device (S-5), a step of filtering foreign substances in the atmospheric air from which the moisture has been removed (S-6), and the atmospheric air from which the foreign substances have been removed is placed in a spray container into which the undiluted solution has been injected. It is characterized by consisting of a pressure injection step (S-7).

The step of preparing the spray container (S-1) is a process of preparing a spray container filled with the undiluted solution and atmospheric air for discharging the undiluted solution. Since conventional LPG gas is not used, a spray container made of a material such as plastic is used. do.

In the step (S-2) of injecting a certain amount of stock solution, the spray container injects the stock solution to be discharged. At this time, the stock solution may contain different ingredients depending on the purpose, such as mist, hair spray, air freshener, or pesticide. In the step (S-2) of injecting a certain amount of stock solution, the injected stock solution is filled to 55 to 65% of the total capacity of the container.

By injecting atmospheric gas through the compressed air charging method of the spray container of the present invention, high pressure compressed air can be charged compared to conventional LPG gas, making it possible to fill a large amount of raw solution.

In the step (S-3) of compressing and supplying the atmospheric air, as shown in FIG. 3, the atmospheric air around the air compressor 100 is sucked in through the air compressor 100 and then compressed into the high pressure tank 200. will be supplied. As such, since the present invention uses atmospheric air, there is no need to provide a separate gas container for injecting compressed air, which can reduce manufacturing costs and increase productivity.

The step (S-4) of storing the atmospheric air in the high-pressure tank is to store the air supplied from the air compressor 100 in a high-pressure state in the high-pressure tank 200. A pressure gauge 210 is installed in the high pressure tank 200 to measure the internal pressure, and a vent valve 220 to control the discharge of internal air is installed to control the pressure. The atmospheric air supplied to the high pressure tank 200 is stored at a high temperature by the operating heat of the air compressor 100.

The temperature of the atmospheric air stored in the high-pressure tank 200 is preferably maintained high. Although the high temperature can be maintained by the operating heat of the air compressor 100, the temperature can be maintained by the heating means provided in the high-pressure tank 200. The temperature inside the high pressure tank 200 can be heated to a temperature of 60 to 80°C to be supplied to the next process. When the temperature is raised to a high temperature in the high pressure tank 200 and supplied to the air drying device 300, the moisture removal effect can be further increased because the heat exchange efficiency increases.

The step (S-5) of removing moisture from the air drying device is a process of receiving atmospheric air stored in the high pressure tank 200 from the air drying device 300 and removing moisture contained in the atmospheric air. Because atmospheric air contains a large amount of moisture and foreign substances compared to purified air, moisture is removed first.

In the step (S-5) of removing moisture from the air drying device 300, the air drying device 300 is equipped with a condenser inside, and the high temperature atmospheric air and the low temperature condenser input into the air drying device 300. By exchanging heat with each other, the moisture contained in the atmospheric air is condensed and removed. Since the condensed water separated through the condensation process also contains foreign substances contained in the atmospheric air, moisture removal and foreign matter are also removed.

Then, through a step (S-6) of filtering foreign substances in the atmospheric air, foreign substances remaining in the atmospheric air from which moisture has been removed are removed. At this time, the filter removes oil components that may be generated as atmospheric air passes through the device, or removes foreign substances such as slight moisture and dust. In order to effectively filter, as shown in the drawing, it is desirable to consist of a first filter unit (400a) and a second filter unit (400b) and sequentially pass through the first filter and the second filter.

Finally, in the step (S-7) of injecting the spray container at a certain pressure, clean atmospheric air from which foreign substances have been removed through the filtering is injected at high pressure into the spray container into which the undiluted solution has been injected. At this time, the proportion of atmospheric air in the spray container is filled by 35 to 45%, which corresponds to the remainder after subtracting the undiluted solution, as shown in FIG. 4.

And in the step (S-7) of injecting the spray container at a constant pressure, the atmospheric air filled inside the spray container is injected so that the pressure is 9 bar to 10 bar. If atmospheric air is charged at a pressure of 9 bar to 10 bar as described above, 55 to 65% of the undiluted solution can be easily discharged.

Figure 5 shows another embodiment of the present invention. In the step (S-6) of filtering foreign substances in the atmospheric air, the filtered air is passed through the moisture detection sensor 500, so that the moisture content is maintained at a certain percent. If it exceeds it, it is returned to the air drying device 300 and moisture is removed again. That is, as shown in the drawing, the moisture detection sensor 500 is installed in the compressed air pipe that passes through the first filter unit 400a and the second filter unit 400b, and the moisture detection sensor 500 is installed at the rear end of the moisture detection sensor 500. A recovery pipe 600 that returns to the drying device 300 is installed. In addition, a three-way valve 610 is installed at the part where the recovery pipe 600 is connected to the compressed air pipe where the moisture detection sensor 500 is installed, so that it is controlled to connect to the recovery pipe 600 when moisture is detected, and when moisture is not detected, the three-way valve 610 is installed. At this time, it is controlled so that it is not connected to the recovery pipe 600.

In addition, a first solenoid valve 700 is installed at the portion supplied from the recovery pipe 600 to the air drying device 300, and a second solenoid valve is installed at the portion supplied from the high pressure tank 200 to the air drying device 300. (800) is installed so that a certain amount of air is supplied to the air drying device (300) by controlling the first solenoid valve (700) and the second solenoid valve (800) when moisture is detected. In other words, assuming that the air supply amount of the air drying device 300 is 100%, the first solenoid valve 700 and the second solenoid valve 800 are controlled to open and close only 50%, so that each half is supplied. It is preferable that the control amounts of the first solenoid valve 700 and the second solenoid valve 800 are controlled in proportion to the amount of moisture measured by the moisture detection sensor 500. As the moisture content of the moisture detection sensor 500 is measured to be higher, the opening and closing amount of the second solenoid valve 800 increases and the opening and closing amount of the first solenoid valve 700 decreases.

In the above, the present invention has been described with reference to the above embodiments, but of course, various modifications are possible within the scope of the technical idea of the present invention.

S-1 ~ S-7: Compressed air charging method for aerosol spray container
100: Air compressor 200: High pressure tank
210: pressure gauge 220: vent valve
300: Air drying device 400a: First filter unit
400b: Second filter unit 500: Moisture detection sensor
600: Recovery pipe 610: Three-way valve
700: 1st solenoid valve 800: 2nd solenoid valve

Claims (4)

Step (S-1) of preparing a spray container,
Injecting a certain amount of stock solution into the spray container (S-2),
A step (S-3) of compressing and supplying atmospheric air through an air compressor,
A step (S-4) of storing the supplied atmospheric air in a high pressure tank,
A step (S-5) of receiving atmospheric air stored in the high-pressure tank and removing moisture in an air dryer,
A step (S-6) of filtering foreign substances in the atmospheric air from which the moisture has been removed,
It consists of a step (S-7) of injecting the atmospheric air from which the foreign substances have been removed at a certain pressure into a spray container into which the undiluted solution has been injected,
In the step (S-4) of storing in the high-pressure tank, the temperature inside the high-pressure tank is heated to a temperature of 60 to 80 ℃ and supplied to the next process. A method of charging compressed air for an aerosol spray container.
delete According to clause 1,
The step (S-5) of removing moisture from the air drying device is a compressed air charging method for an aerosol spray container, characterized in that the moisture in the introduced atmospheric air is condensed and removed through heat exchange with a condenser provided in the air drying device.
According to clause 1,
A method of charging compressed air for an aerosol spray container, characterized in that in the step (S-7) of injecting the spray container at a constant pressure, the pressure of the atmospheric air filled inside the spray container is injected to a pressure of 9 bar to 10 bar.