KR101855691B1 - Sealing structure of bursting disk for mini oxygen cartridge - Google Patents

Abstract

The present invention improves the rupturable membrane sealing structure so that the rupture membrane can be sealed more securely in a double manner and the oxygen leakage can be prevented by preventing the leakage of oxygen during circulation and storage of the oxygen cartridge, To a rupturable membrane sealing structure of an oxygen cartridge.
An oxygen cartridge (10) comprising: a support (12) formed at a lower portion of an inlet (11); and a pressed fixing portion (13) formed at an upper portion of an inlet (11) and bent inward; A rupturing portion 22 formed on the upper portion of the body portion 21 and a lower outer surface of the body portion 21 which are attached to the inlet 11 of the oxygen cartridge 10 and opened at the lower portion, A connecting portion 24 integrally formed at the lower portion of the body 21 and a tight fitting portion 25 bent downward from the outer periphery of the flange 23, 20); An insertion hole 31 to be fitted in the connection portion 24 of the rupture membrane 20 and a first tight contact portion 32 to correspond to the close contact portion 25 are formed in the inlet 11 and the rupture membrane 20 A primary sealing packing 30 for primarily sealing the lower portion; An insertion hole 41 fitted to the body 21 of the rupturable membrane 20, an elastic groove 42 formed concentrically on the bottom surface of the rupturable membrane 20, a second tight contact portion 43 corresponding to the tight fitting portion 25, And a taper 44 formed on the outer circumferential surface of which the diameter gradually increases from the upper portion to the lower portion. The tapered portion 44 is fixed to the inlet 11 through the crimp fixing portion 13 to divide the upper portion of the inlet 11 and the rupture membrane 20 into two And a secondary seal packing 40 for sealing the secondary seal.

Description

[0001] The present invention relates to a sealing structure of a bursting disk for a miniature oxygen cartridge,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a small-sized oxygen cartridge for supplying oxygen compressed at a high pressure into a cosmetic container, a beverage container, or the like. More particularly, the present invention improves the rupturable membrane sealing structure so that the rupturable membrane can be more securely sealed And also to prevent ruptured products by blocking leakage of oxygen during distribution and storage of the oxygen cartridge by using the oxygen cartridge, thereby protecting the rupture film sealing structure of the small oxygen cartridge.

Generally, a small oxygen cartridge is provided with a rupture membrane ruptured in a rupture bar to supply oxygen to the inside of a cosmetic container, a beverage container, or the like. Such oxygen cartridge is filled with oxygen compressed at a high pressure. At this time, when the oxygen cartridge is pushed into the rupture bar, the rupture membrane is ruptured. At the same time, oxygen is injected into the rupture bar and oxygen compressed at a high pressure ejected from the oxygen cartridge by oxygen pressure is supplied into the interior of a cosmetic container or a beverage container .

As a prior art in which oxygen is supplied to a cosmetic container using a small oxygen cartridge, Korean Patent No. 10-1149904 (Patent Document 1) discloses that a large amount of high-purity oxygen is incorporated into cosmetics An oxygen-containing cosmetic container is disclosed in order to make the original unique nutritional ingredient of the cosmetic product more absorbed to the skin.

In addition, as a prior art for supplying oxygen to a beverage container using a small oxygen cartridge, Korean Patent No. 10-1144182, which is the following patent document, discloses a method of injecting water or a specific water containing a specific material into a storage space of a beverage container There is disclosed an oxygen and carbonated beverage maker capable of easily and conveniently producing and consuming oxygen beverages and carbonated beverages in general households by preparing a beverage by selectively injecting oxygen gas or carbon dioxide gas into the storage space have.

On the other hand, in the case of such a small oxygen cartridge, since a small amount of oxygen is charged, if the rupture membrane sealing of the oxygen cartridge is defective, there is a problem that even if only a small amount of oxygen is leaked, the rupture membrane of the oxygen cartridge must be securely sealed do. That is, when the oxygen cartridge is a large container, there is no problem with the pressure even if there is a slight leak, but sealing is important because a small cartridge will have a low dissolved rate when mixed with the second solution in case of slight leakage. Here, the existing smallest oxygen cartridge is charged with gas of 5 g to 10 g, and the outer size standard of the conventional oxygen cartridge is 65 mm long × 18 mm wide.

For this purpose, Japanese Patent Application Laid-Open No. 97-24517 (Patent Document 3) discloses, as shown in Figs. 1 and 2, a honeycomb structure in which a honeycomb structure is formed in an insertion groove 2 formed in an opening 1a of an oxygen- And the packing 4 is pressed and supported by a plurality of folding support pieces 5 which are integrally connected to the upper end of the opening 1a so as to seal the opening 1a. In which the disposable compressed oxygen container is sealed.

Such a conventional sealing structure has the effect of sealing the upper opening portion of the oxygen container manufactured with a small size so that it can be freely carried, with a sealing plate, and sealing without welding process.

However, in the conventional sealing structure shown in Figs. 1 and 2, only one packing 4 is sandwiched in the sealing plate 3, the packing 4 is pressed and supported by a plurality of bending supporting pieces 5, 3 leak out from the bottom and the inner wall of the concave groove 2 and between the sealing plate 3 and the packing 4 due to the sealing. That is, there is a problem in that it is not possible to securely seal the sealing plate 3 with only one packing 4 structurally. Particularly, a flange of a metal formed at a lower portion of the sealing plate 3, which is a metal, Since the metal support portions formed on the metal plate are in contact with each other, it is difficult to maintain airtightness therebetween. Conventionally, as shown in FIG. 2, the outer surface of the packing 4 and the inner wall of the concave groove 2 are simply in line contact so that the gas is leaked as time elapses with a small contact area, There has been a problem that the amount of oxygen mixed and dissolved in the oxygen container is reduced.

Japanese Patent Application Laid-Open No. 20-0411620, which is a registered trademark of the following Patent Document, discloses a container having a container holding jaw on the inside of an upper portion of a container portion and a container holding portion having at least one gas- And an O-ring which is fastened to the upper surface of the upper projecting-type sealing plate and seals the inside and the outside of the container portion. However, as described above, The upper protruding type seal can not be securely sealed by only one o-ring which is in line contact with the upper protruding type seal.

On the other hand, Korean Patent Application No. 20-0479110, which is a registered trademark of the following Patent Document, discloses a mixing lid assembly which is provided with a packing at the lower part of a rim of a container to close an inlet port of the container. There has been a problem in that the container can not be safely sealed with only one packing which is in line contact with the inner wall.
Particularly, the Korean Registered Utility Model No. 20-0411620 discloses that at least one gas injection groove is formed on the outer circumference and is sealed with only one o-ring on the upper part, so that the upper projecting type seal is sealed with at least one gas injection Since the opening is not sealed with the inner circumferential surface of the inlet of the container, only the o-ring located at the upper portion is sealed and the gas leaks at the time of storage. Therefore, in the case of the small cartridge, the mixing efficiency is low when mixed with the second solution. On the other hand, when the packing provided at the lower part of the rim of the container described in the Korean Registered Utility Model No. 20-0479110 is coupled to the lower portion of the upper projecting-type seal, the upper projecting- Since the ideal gas injection grooves are formed, only the O-ring located at the upper part and the packing located at the lower part are sealed without being sealed with the inner peripheral surface of the inlet of the container. The mixing efficiency is lowered.

Patent Document 1: Registration No. 10-1149904 (Registration date: May 18, 2012) Patent Document 2: Registration No. 10-1144182 (Registration date: May 05, 2012) Patent Document 3: Published Application No. 97-24517 (Published Date: June 20, 1997) Patent Document 4: Registration Utility Model No. 20-0411620 (Registration Date: Mar. 3, 2006) Patent Document 5: Registration Utility Model No. 20-0479110 (Registration date: December 14, 2014)

It is an object of the present invention to overcome the above-mentioned drawbacks of the prior art and to provide a rupture film sealing structure for a small-sized oxygen cartridge which supplies oxygen compressed at a high pressure into a cosmetic container or a beverage container, Thereby making it possible to more securely seal the oxygen cartridge 2 in a double manner and to prevent the defective product by blocking the leakage of oxygen during distribution and storage of the oxygen cartridge through the oxygen cartridge. So that the defect rate can be minimized.

In order to achieve the above object, the present invention provides an oxygen cartridge comprising: an oxygen cartridge having a receiving portion formed at a lower portion of an inlet, and a pressing and fixing portion formed at an upper portion of an inlet and bent inward; A flange formed on a lower outer surface of the body, a connecting portion formed integrally with a lower portion of the body, and a flange formed integrally with the flange, A rupturable membrane having a tightly folded portion beneath the periphery; A primary sealing packing having an insertion hole to be fitted in the connection portion of the rupture membrane and a first contact portion to correspond to the contact portion to primarily seal the lower portion of the inlet and the rupture membrane; A tapered portion formed on an outer circumferential surface having a larger diameter from the upper portion to the lower portion; and a tapered portion formed on the outer surface of the tapered portion, And a secondary sealing packing secured to the inlet through the opening to secondarily seal the top of the rupture membrane with the inlet.

In the present invention, the flange of the rupturable membrane is formed to be inclined downward, and the upper portion of the primary sealing packing and the lower portion of the secondary sealing packing are formed to be inclined so as to correspond to the inclined surface of the flange.

According to the rupture film sealing structure of the small oxygen cartridge of the present invention, a primary sealing packing for hermetically sealing the inlet and the lower portion of the rupture film in the airtight manner is hermetically attached to the lower portion of the flange provided in the rupture film, Since the secondary sealing packing for hermetically sealing the inlet and the upper portion of the rupturable membrane is hermetically attached to the body, the rupture membrane of the oxygen cartridge can be sealed more securely in the upper portion.

In addition, since leakage of oxygen can be cut off twice during distribution and storage of the oxygen cartridge through the primary sealing packing and the secondary sealing packing, it is possible to prevent the product from being defective due to leakage of oxygen structurally .

1 is an exploded perspective view showing a conventional sealing structure.
2 is a cross-sectional view showing the coupled state of FIG. 1;
3 is a perspective view of the present invention.
4 is an exploded perspective view of the present invention.
5A and 5B are cross-sectional views showing a combined state of the present invention.
6 is a cross-sectional view showing the separated state of the present invention.
7 is an enlarged cross-sectional view of a secondary sealing packing according to the present invention.
8 is a sectional view showing another embodiment of the present invention.
9 is a sectional view showing another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the technical structure of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 2 to 9, the rupture film sealing structure of the small oxygen cartridge of the present invention comprises a receiving portion 12 formed at a lower portion of an inlet 11, a receiving portion 12 formed at an upper portion of the inlet 11, An oxygen cartridge (10) provided with a press-fit fixing portion (13); A rupturing portion 22 formed on the upper portion of the body portion 21 and a lower outer surface of the body portion 21 which is attached to the inlet 11 of the oxygen cartridge 10 and opened at the lower portion; A connecting portion 24 integrally formed at the lower portion of the body 21 and a tight fitting portion 25 bent downward from the outer periphery of the flange 23, 20); An insertion hole 31 to be fitted in the connection portion 24 of the rupture membrane 20 and a first tight contact portion 32 to correspond to the close contact portion 25 are formed in the inlet 11 and the rupture membrane 20 A primary sealing packing 30 for primarily sealing the lower portion; An insertion hole 41 fitted to the body 21 of the rupturable membrane 20, an elastic groove 42 formed concentrically on the bottom surface of the rupturable membrane 20, a second tight contact portion 43 corresponding to the tight fitting portion 25, And a taper 44 formed on the outer circumferential surface of which the diameter gradually increases from the upper portion to the lower portion. The tapered portion 44 is fixed to the inlet 11 through the crimp fixing portion 13 to divide the upper portion of the inlet 11 and the rupture membrane 20 into two And a secondary sealing packing 40 for sealing the secondary sealing.

Here, the oxygen cartridge 10 is manufactured in a small size and installed in a cosmetic container, a beverage container, or the like. The oxygen cartridge 10 serves to supply oxygen compressed at a high pressure into a cosmetic container, a beverage container, or the like do. At this time, the oxygen cartridge 10 is filled with oxygen compressed at a high pressure. Meanwhile, the small-size oxygen cartridge 10 according to the present invention is filled with a gas of about 0.2 g to 1 g. The external size of the small oxygen cartridge of the present invention is a size of 30 mm long × 18 mm wide, Since the gas naturally leaks from the oxygen cartridge, the present invention having a small charging capacity of the gas can be double-sealed at the lower part and the upper part of the rupturable membrane 20 in order to prevent such leakage of oxygen .

Since the oxygen cartridge 10 according to the present invention stores a small amount of oxygen, the efficiency is degraded by only a slight leakage of oxygen, so sealing is very important.

The oxygen cartridge 10 is integrally formed with a spout-shaped inlet 11 for installing the oxygen filling and rupturing membrane 20. A primary sealing packing 30 is provided in the lower part of the inlet 11, And a press fitting part 12 for supporting the secondary sealing packing 40 is integrally formed on the upper part of the inlet 11. A press fitting fixing part 13 which is inwardly bent to fix the secondary sealing packing 40 by press- do. At this time, the oxygen cartridge 10 is made of metal.

The rupture membrane 20 is hermetically sealed to the inlet 11 of the oxygen cartridge 10. The rupture membrane 20 is connected to the inlet 11 when the oxygen cartridge 10 is circulated and stored. And the rupture membrane 20 plays a role of rupturing by the rupture bar when oxygen is supplied into the cosmetic container, the beverage container, or the like.

The rupturable membrane 20 is formed with a cylindrical body 21 constituting a lower opened body and a rupturing portion 22 ruptured by the rupturing rod is formed at the upper portion of the body 21 And a flange 23 for supporting the primary sealing packing 30 and the secondary sealing packing 40 in a spaced relationship is integrally formed on the lower outer surface of the body 21, 21 are integrally formed at the lower portion of the flange 23 and open at the top and the bottom of the flange 23. A flange portion 25 bent downward is formed at the outer periphery of the flange 23. At this time, the rupture membrane 20 is made of metal.

According to the present invention, since the connecting portion 24 is integrally formed at the lower portion of the body 21, the insertion hole 31 of the primary sealing packing 30 can be inserted into the connecting portion 24 to be air- have.

According to the present invention, since the contact portion 25, which is bent downward, is formed in the outer periphery of the flange 23 in a surface contact manner, the contact area with the inner wall of the inlet 11 of the oxygen cartridge 10 is increased, do. When the compression bonding portion 13 is compressed, the adhered portion 25 is pressed against the inlet 11 of the oxygen cartridge 10 by the repulsive force of the primary sealing packing 30 and the secondary sealing packing 40 being contracted and restored, Tightly close to the inner wall of the case. At this time, the tight contact portion 25 may be formed in a curved shape as shown in FIG. 5B, and the tight contact portion 25 may be formed as a flat face as shown in FIG.

The primary sealing packing 30 is mounted to the lower portion of the connecting portion 24 and the flange 23 provided in the rupture film 20 and the primary sealing packing 30 is connected to the inlet 11 and the lower portion of the rupturable membrane 20 in a hermetic manner. At the center of the primary sealing packing 30, the connection portion 24 of the rupturable membrane 20 is hermetically sealed at the center of the primary sealing packing 30. The primary sealing packing 30 is made of an elastic material such as silicone or rubber, And the first sealing part 32 is formed on the upper edge of the primary sealing packing 30. The first sealing part 32 corresponds to the sealing part 25 of the rupturable membrane 20.

According to the present invention, since the primary sealing packing 30 is provided with the first adhered portion 32 corresponding to the adhered portion 25 of the rupturable membrane 20, The tight contact portion 25 of the membrane 20 and the first tight contact portion 32 of the primary seal packing 30 are sealed more airtight by the phenomenon of sparking, The inlet 11 of the rupturable membrane 10 and the lower portion of the rupturable membrane 20 are sealed in an airtight manner.

The secondary sealing packing 40 is mounted on the upper portion of the body 21 and the flange 23 provided in the rupture membrane 20 and the secondary sealing packing 40 is connected to the inlet of the oxygen cartridge 10 The primary sealing packing 40 serves to seal the upper portion of the rupture membrane 11 and the rupture membrane 20 in a secondary airtight manner and the primary sealing packing 40 serves to compress the inside of the oxygen cartridge 10, And is firmly and hermetically fixed by the pressing in the state of being fitted in the inlet 11 through the fixing portion 13. The primary sealing packing 40 is made of an elastic material such as silicone or rubber having elasticity. The secondary sealing packing 40 is provided at the center of the body 21 of the rupturable membrane 20 An elastic hole 42 is formed concentrically on the bottom surface of the secondary sealing packing 40 and a sealing portion 25 is formed on the lower edge of the secondary sealing packing 40 And a taper 44 is formed on the outer circumferential surface of the secondary sealing packing 40 so that the diameter increases from the upper portion to the lower portion.

According to the present invention, since the second sealing portion 30 is provided with the second sealing portion 43 corresponding to the sealing portion 25 of the rupturable membrane 20, The tight contact portion 25 of the membrane 20 and the second tight contact portion 43 of the secondary seal packing 40 are further hermetically sealed by the sparking phenomenon, The inlet 11 of the rupturable membrane 10 and the upper portion of the rupturable membrane 20 are secondarily airtightly sealed.

According to the present invention, since the elastic sealing groove 42 and the taper 44 are formed in the secondary sealing packing 40, the elastic groove 42 and the taper 44 The taper 44 rides on the inner wall of the inlet 11 by the resilient groove 42 when the pressing and securing portion 13 is pressed against the outer peripheral surface of the secondary sealing packing 40, The taper 44 of the secondary sealing packing 40 is hermetically sealed to the inner wall of the inlet 11. At this time, the taper 44 is formed such that the lower diameter L1 is larger than the upper diameter L2 by 0.1 to 0.5 mm as shown in FIG.

9, the flange 23 of the rupturable membrane 20 is formed to be inclined downward, and the upper part of the primary sealing packing 30 and the secondary sealing packing (not shown) 40 are inclined to correspond to the inclined surfaces of the flange 23, respectively.

The flange 23 of the rupturable membrane 20 is inclined downward and the upper portion of the primary sealing packing 30 and the lower portion of the secondary sealing packing 40 are connected to the flange 23 The inclined flange 23 is horizontally lifted by the pressing force of the pressing force and the inner wall of the inlet 11 of the oxygen cartridge 10 is exposed to the outside, The flange is inclined downwardly by the cushion force of the primary sealing packing 30 and the secondary sealing packing 40 during the pressing of the pressing and fixing part 13 23 are elastically and tightly adhered to the inner wall of the inlet 11 more airtightly.

The rupturable membrane sealing structure of the small oxygen cartridge of the present invention having such a structure as described above is characterized in that a flange (21) is provided below the trunk portion (21) of the rupturable membrane (20) equipped with the rupturing portion (22) A primary sealing packing 30 for sealing the inlet 11 and the lower portion of the rupture membrane 20 in a hermetic manner is formed at a lower portion of the connecting portion 24 and the flange 23, And the secondary seal packing 40 for sealing the inlet 11 and the upper portion of the rupture film 20 in a hermetic manner is mounted on the upper portion of the body 21 and the flange 23, And can be doubly sealed through the primary seal packing 30 and the secondary seal packing 40 at the bottom and top of the membrane 20.

Therefore, in the present invention, a primary sealing packing 30 for sealing the inlet 11 and the lower portion of the rupturable membrane 20 in a hermetic manner is mounted on the lower portion of the flange 23 provided in the rupturable membrane 20 Since the secondary sealing packing 40 for sealing the inlet 11 and the upper portion of the rupturable membrane 20 in a secondary airtight manner is mounted on the upper portion of the flange 23, ) Can be doubly sealed more securely.

Further, since the present invention can double the leakage of oxygen during circulation and storage of the oxygen cartridge 10 through the primary seal packing 30 and the secondary seal packing 40, There is an advantage that the defective product can be prevented beforehand, and it is possible to minimize the defective rate by increasing the oxygen filling quality of a small amount of oxygen cartridge.

10: oxygen cartridge 11: inlet
12: Support part 13:
20: rupture film 21: body part
22: rupture portion 23: flange
24: connection part 25:
30: Primary seal packing 31: Insertion hole
32: first tight contact portion 40: secondary seal packing
41: insertion hole 42: elastic groove
43: second tight contact portion 44: taper

Claims (2)

An oxygen cartridge 10 having a receiving portion 12 formed at a lower portion of an inlet 11 and a pressing and fixing portion 13 formed at an upper portion of an inlet 11 and bent inward;
A rupturing portion 22 formed on the upper portion of the body portion 21 and a lower outer surface of the body portion 21 which are attached to the inlet 11 of the oxygen cartridge 10 and opened at the lower portion, A connecting portion 24 integrally formed at the lower portion of the body 21 and a tight fitting portion 25 bent downward from the outer periphery of the flange 23, 20);
An insertion hole 31 to be fitted in the connection portion 24 of the rupture membrane 20 and a first tight contact portion 32 to correspond to the close contact portion 25 are formed in the inlet 11 and the rupture membrane 20 A primary sealing packing 30 for primarily sealing the lower portion;
An insertion hole 41 fitted to the body 21 of the rupturable membrane 20, an elastic groove 42 formed concentrically on the bottom surface of the rupturable membrane 20, a second tight contact portion 43 corresponding to the tight fitting portion 25, And a taper 44 formed on the outer circumferential surface of which the diameter gradually increases from the upper portion to the lower portion. The tapered portion 44 is fixed to the inlet 11 through the crimp fixing portion 13 to divide the upper portion of the inlet 11 and the rupture membrane 20 into two And a secondary seal packing (40) for sealing the secondary seal. 2. The method according to claim 1, wherein the flange (23) of the rupturable membrane (20) is formed to be inclined downward and the upper part of the primary sealing packing (30) and the lower part of the secondary sealing packing (40) Wherein the rupture film sealing structure of the small oxygen cartridge is formed so as to be inclined to correspond to the inclined surface.

Images