KR101713246B1 - Beverage container of mixed oxygen - Google Patents

Abstract

The present invention relates to a beverage container mixing oxygen, capable of improving a dissolved oxygen rate by injecting oxygen by strong pressure while a nozzle unit is sunken in a beverage and of preventing the oxygen supplied to the beverage in the beverage container from reversely flowing to the outside through a rupture rod. The beverage container mixing oxygen also can prevent the rupture rod from being ruptured as an oxygen capsule unnecessarily descends during storage or a distribution process. According to the present invention, the beverage container mixing oxygen includes: a beverage container unit (100) accommodating the beverage by having an inlet (110) with an open upper part; an oxygen injection cap (200) connected to the inlet (110) to be separated and including the rupture rod (210), a connection pipe (220) supporting the rupture rod (210), an insertion unit (230) inserted into the inlet (110), a capsule accommodating space (240) formed in the insertion unit (230), and an opening display ring (250); the nozzle unit (300) formed in the connection pipe (220) of an integral type or a separation type and opened by the pressure when the oxygen is injected while the nozzle unit (300) is sunken in the beverage; the oxygen capsule (400) including a rupture layer (410) ruptured in the rupture rod (210) and mounted on the capsule accommodating space (240) to supply the oxygen into the beverage container (100); and an oxygen supply cap (500) separating the rupture rod (210) and the rupture layer (410) by being connected to the oxygen injection cap (200) to be separated and including a safety ring (510) damaged when the oxygen is injected.

Description

BEVERAGE CONTAINER OF MIXED OXYGEN}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oxygen mixed beverage container for supplying oxygen to beverage in a beverage container, and more particularly, to an oxygen mixed beverage container for supplying oxygen to beverage in a beverage container, It is possible to prevent the oxygen supplied to the beverage in the beverage container from flowing back to the outside through the rupture bar and to prevent the rupture membrane from being ruptured due to the unnecessary lowering of the oxygen capsule during the distribution process or storage, It is about the container.

Generally, as is well known, oxygen not only breathes but also decomposes various fatigue substances, smoothes metabolism, improves muscle and cardiopulmonary function, and is an indispensable gas for human life.

In recent years, such oxygen has been proved to accelerate the detoxifying action of the liver and secretion of digestive enzymes when drinking high-concentrated oxygenated water through clinical experiments. Thus, a portable oxygenated water generating device capable of dissolving oxygen in water at a high concentration Is disclosed in Korean Patent Laid-Open No. 10-2012-0041401.

On the other hand, in the case of fruit drinks, bottled water or carbonated beverages, they are stored and stored in beverage containers made of glass bottles or plastic materials. However, in order to smoothly circulate and metabolize the human body by maintaining a high concentration of dissolved oxygen, There is a problem in that a device for injecting oxygen is not provided.

Accordingly, there is a need to provide an oxygen injection device that includes an oxygen injection cap detachably coupled to an injection port of a beverage container and having a rupture bar, an oxygen capsule for supplying oxygen into the interior of the beverage container, And an oxygen supply cap having a capsule mounting portion in which an oxygen capsule is fitted so as to be detachably coupled to the oxygen supply cap.

In such an oxygen injecting apparatus of the beverage container, when the oxygen capsule is pushed into the rupture bar, the rupture membrane is ruptured. At the same time, oxygen is supplied to the inside of the beverage container while being ejected into the rupture bar. Therefore, Therefore, when you drink it, it supplies oxygen to the blood to help the blood circulation and metabolism smoothly.

However, in the conventional oxygen injecting apparatus, since the rupture bar is always kept open, oxygen supplied to the beverage in the beverage container flows back to the outside through the rupture bar.

To this end, as shown in FIG. 1, the Japanese Patent Laid-Open No. 10-1622949 discloses a method in which a pressurized gas containing oxygen is connected to containers C1 and C2 filled with a liquid material into containers C1 and C2 CLAIMS 1. A compressed gas supply apparatus adapted to be charged; A container engaging portion 13 that is detachably coupled to the container C1 and a pressurizing engaging portion 15 which is opposed to the container engaging portion 13 while being partitioned and exposed to the outside of the container C1 A main cap 11 formed on the lower surface of the main cap 11; A hollow opening pin 20 provided in the main cap 11 and communicating with the inside and outside of the container C1; A pressure cap 12 coupled to the main cap 11 so as to be detachably coupled to the press-fitting portion 15; An inflator (19) provided in the form of a closed container mounted to the pressure cap (12), the inflator (19) being filled with a compressed gas therein and opened by the open pin (20); And a check valve 22 provided in the main cap 11 and provided to prevent backflow of the compressed gas ejected from the inflator 19 in a state of being located inside the container C1 In the compressed gas supply device.

Such a conventional compressed gas supply device can be reused by being attached to another container C1 of the same size as required by the main cap 11 attached to and detached from the container C1, Since the inflator 19 is built in the separate pressurizing cap 12, the inflator 19 can be stably supported by the pressure cap 12 to provide convenience of opening operation. Further, Since the check valve 22 is provided in the main cap 11, it is possible to prevent the compressed gas supplied by the inflator 19 from flowing back to the outside of the container C1.

However, as shown in Fig. 1, when the inflator 19 is opened, since the high-pressure compressed gas strongly urges the elastic band 26 and opens the discharge hole 25 as shown in Fig. 1, So that the compressed gas can not be blown up to the depth of the liquid material in the container C1. As a result, the mixing ratio of the compressed gas and the liquid material is lowered. 1, since a space is formed between the check valve 22 and the liquid material and the compressed gas is ejected in a state where the discharge hole 25 is spaced apart from the liquid material, the liquid material is not ejected to the depth of the liquid material Since the amount of the compressed gas remaining in the space portion between the discharge hole 25 and the liquid material is greater than the amount of the compressed gas mixed in the liquid material, the compressed gas remaining in the space portion when the main cap 11 is opened, So that the mixing rate is lowered.

Also, as shown in FIG. 1, since the conventional compressed gas supply apparatus lacks a safety structure for preventing the pressure cap 12 from falling unnecessarily between the main cap 11 and the pressure cap 12, There is a problem that the inflator 19 is unnecessarily opened due to carelessness or the like and the compressed gas is blown out.

Patent Document 1: Published Patent No. 10-2012-0041401 (Published Date: May 05, 2012) Patent Document 2: Registration No. 10-1622949 (Registration date: 2016.06.08)

An object of the present invention is to provide an oxygen mixed beverage container capable of increasing the oxygen dissolution rate by ejecting oxygen with a strong pressure while the nozzle body is immersed in beverage, .

It is another object of the present invention to provide an oxygen mixed beverage container in which oxygen supplied to beverage in a beverage container can be prevented from flowing back to the outside through the burst bar.

It is another object of the present invention to provide an oxygen mixed beverage container which can prevent oxygen capsules from unnecessarily falling down during distribution or storage to prevent the rupture membrane from being ruptured.

To achieve the above object, according to the present invention, there is provided a beverage container including a beverage container, And a detachable coupling member which is detachably coupled to the injection port and includes a rupturable rod, a connection pipe for supporting the rupturable rod, a fitting portion to be inserted into the injection port, a capsule accommodating space formed inside the fitting portion, Oxygen injection cap; A nozzle body integrally or separately formed in the connection pipe and opened by a pressure at the time of an oxygen inlet in a state of being immersed in beverage; An oxygen capsule attached to the capsule accommodating space to supply oxygen into the beverage container, the oxygen capsule having a rupture membrane ruptured to the rupture bar; And an oxygen supply cap detachably coupled to the oxygen injection cap to separate the rupture bar and the rupture membrane from each other and to have a safety ring broken when the oxygen barrier is broken.

Further, the present invention may further include a backflow prevention safety cover having an incision part connected to the nozzle body and opened by an oxygen injection pressure.

In addition, the present invention further includes a powder capsule containing an additive which is contained in the safety cover and is injected into beverage through an open mouth cutting unit.

In the present invention, the beverage container is capable of withstanding the instantaneous pressure that is ejected from the oxygen capsule.

Further, in the present invention, a thin film portion or a cut portion is formed at the bottom of the nozzle body to be opened when the oxygen nozzle is opened.

In the present invention, the nozzle body is composed of a check valve to prevent backflow.

According to the oxygen mixed beverage container of the present invention, since the nozzle body is opened by the pressure of the oxygen inlet when the bottle is immersed in the drinking water and oxygen is discharged, the oxygen can be structurally ejected with a strong pressure and a space is formed between the nozzle body and the beverage Therefore, there is an effect that the oxygen dissolution rate can be increased by strongly jetting oxygen to the depth of the drinking water.

In addition, when the rupture membrane of the oxygen capsule is ruptured, since the high-pressure oxygen opens while opening the incision of the safety cover, the oxygen pressure is not exhausted unlike the conventional structure when the safety cover is structurally opened. So that the oxygen dissolution rate can be increased.

In addition, since the nozzle body is formed in the connecting pipe for supporting the rupturable bar, and the back cover for preventing backflow is provided only in the nozzle body, the oxygen supplied to the beverage in the beverage container flows back to the outside through the rupture bar There is an effect that it can be prevented.

In addition, since the rupture membrane of oxygen capsules is normally spaced apart from the oxygen supply cap at the lower part of the oxygen supply cap, the oxygen ring is structurally lowered unnecessarily during the circulation or storage, thereby preventing the rupture membrane from being ruptured There is an effect that can be done.

1 is a sectional view showing a conventional compressed gas supply device.
2 is a perspective view of the present invention.
3 is an exploded perspective view of the present invention.
4 is a cross-sectional view showing the separated state of the present invention.
5A and 5B are sectional views showing an operating state of the present invention.
6 is a perspective view showing a cut portion of the nozzle body according to the present invention.
7 is an exploded perspective view showing another combination of the nozzle body and the safety cover according to 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 7, the oxygen mixed beverage container according to the present invention includes a beverage container 100 having an inlet 110 having an open upper portion to receive beverage; A connection pipe 220 detachably coupled to the injection port 110 and supporting the rupturing rod 210, the rupturing rod 210, a fitting part 230 fitted into the injection port 110, An oxygen injection cap 200 having a capsule receiving space 240 formed in the interior of the unit 230, and a unsealing indication ring 250; A nozzle body 300 integrally or separately formed in the connection pipe 220 and opened by the pressure of the oxygen inlet when it is immersed in the drinking water; An oxygen capsule 400 mounted on the capsule accommodating space 240 to supply oxygen into the beverage container 100 with the rupture membrane 410 ruptured in the rupture bar 210; And an oxygen supply cap 500 detachably coupled to the oxygen injection cap 200 to separate the rupture bar 210 from the rupture membrane 410 and to have a safety ring 510 that is broken when the oxygen bar is broken It is a basic feature of the technical structure.

According to the present invention, there is further provided a backflow prevention safety cover 600 having an incision 610 connected to the nozzle body 300 and opened by an oxygen inlet pressure.

According to the present invention, there is further provided a powder capsule 700 housed in the safety cover 600 and containing an additive to be injected into beverage through the open mouth cutting unit 610.

In the present invention, oxygen is supplied to beverage water contained in the beverage container 100 to help health, and oxygen supplied to the beverage in the beverage container 100 after oxygen injection flows backward through the burst bar 210 The present invention relates to a beverage container 100, an oxygen injection cap 200, a nozzle body 300, an oxygen capsule 400, an oxygen supply cap 500, a safety cover 600, (700). At this time, it is found that the safety cover 600 and the powder capsule 700 can be selectively used as needed.

The beverage container 100 stores, stores and sells various kinds of fruit beverages, bottled water or various carbonated beverages. An injection port 110 is formed in the upper part of the beverage container 100 so that beverage can be injected and discharged And a male screw 111 is formed on the outer diameter of the injection port 110. At this time, the beverage container 100 is made of PET bottles or glass bottles.

According to the present invention, the beverage container (100) is characterized by being able to withstand the instantaneous pressure of the oxygen capsule (400). At this time, according to the present invention, the beverage container 100 which can withstand high pressure and internal pressure of 3 kg bar or more and oxygen dissolved amount of 30 ppm (PART PER MILLION) due to the instantaneous pressure ejected from the oxygen capsule 400 is used. That is, in the oxygen capsule 400, a strong oxygen pressure of 3 kg bar or more at the moment of rupture of the rupture membrane 410 is sprayed into the beverage of the beverage container 100, whereby the amount of oxygen dissolved in the beverage container 100 is increased up to 30 PPM Therefore, in the present invention, the beverage container 100 capable of withstanding an internal pressure of 30 PPM or more is used. For reference, a conventional common water bottle can not be used because it can not withstand the oxygen pressure of the oxygen capsule 400 and explodes.

The oxygen injection cap 200 is detachably coupled to the injection port 110 of the beverage container 100 and the rupture membrane 410 of the oxygen capsule 400 is ruptured at the center of the oxygen injection cap 200. And a rupture bar 210 for supplying oxygen to the inside of the beverage container 100 at the same time. At this time, the rupture bar 210 may be made of a metal material so that the rupture film 410 can be easily ruptured.

At the lower center of the oxygen injection cap 200, a coupling pipe 220 for supporting the burst bar 210 is integrally formed.

The connection pipe 220 is integrally formed at the lower center of the oxygen injection cap 200 to support the rupturing rod 210. A discharge hole is formed in the connection pipe 220 to discharge oxygen therein . At this time, the nozzle body 300 is integrally or separably formed in the connection pipe 220.

The oxygen injection cap 200 is formed with a fitting portion 230 to be inserted into the injection port 110 and a capsule receiving space 240 for accommodating the oxygen capsule 400 is inserted into the fitting portion 230 . A plurality of support pieces 241 for holding the center of the oxygen capsule 400 are radially protruded in the upper portion of the inner diameter of the capsule accommodation space 240. The support pieces 241 are formed on the outer surface of the oxygen capsule 400 As shown in FIG. 4 shows that the lower portion of the fitting portion 230 is formed so as to protrude further downward than the lower end of the oxygen injection cap 200. As shown in FIG.

The opening indication ring 250 is provided below the oxygen injection cap 200. The open indication ring 250 is integrally formed with the oxygen injection cap 200 to indicate the opening state of the first beverage container 100. The open indication ring 250 is formed of a And is connected to the lower part by a plurality of perforated lines 251.

The nozzle body 300 is formed integrally or separately in the connection pipe 220. The nozzle body 300 is opened by the pressure of the oxygen inlet when it is immersed in drinking water and discharges oxygen. At this time, since the nozzle body 300 is opened by the pressure of the oxygen inlet while being submerged in the drinking water and oxygen is discharged, the oxygen can be structurally ejected with a strong pressure, and a space is formed between the nozzle body 300 and the drinking water So that oxygen can be injected strongly to the depth of the drinking water to increase the oxygen dissolution rate.

When the nozzle body 300 is formed integrally with the coupling tube 220 and is formed in a detachable shape, the nozzle body 300 is tightly coupled to the coupling tube 220 without being forced into the coupling tube 220. 5 and FIGS. 6A and 6B, the outer diameter of the outer circumferential surface of the connection tube 220 is adjusted so that the nozzle body 300 inserted into the connection tube 220 does not escape by the pressure ejected from the oxygen capsule 400. At this time, And a locking protrusion 221 and an engaging groove 301 which are coupled to each other at a lower portion of the inner diameter of the nozzle body 300 so as to be tightly coupled to each other.

According to the present invention, a thin film portion 310 or a cut-out portion 320 is formed at the bottom of the nozzle body 300 and is opened by a pressure ejected from the oxygen capsule 400 at the time of the oxygen occlusion.

3 to 5B, the thin film portion 310 may be formed at the bottom of the nozzle body 300 to be opened to discharge oxygen while being ruptured due to pressure during oxygen spouting. have.

According to another embodiment of the present invention, as shown in FIG. 6, a cruciform cutout 320 may be formed at the bottom of the nozzle body 300, .

According to another embodiment of the present invention, the nozzle body 300 is formed of a check valve. At this time, when the nozzle body 300 is a check valve, the nozzle body 300 itself performs a backflow prevention action. Thus, when the nozzle body 300 is a check valve, the safety cover 600 It is possible to prevent the oxygen supplied to the beverage in the beverage container 100 from flowing back to the outside through the burst bar 210. [

The oxygen capsule 400 is provided with a rupture membrane 410 ruptured in the rupturing rod 210 to supply oxygen into the beverage container 100. Oxygen And the oxygen capsule 400 is mounted in the capsule receiving space 240 of the oxygen injection cap 200. [ At this time, when the oxygen capsule 400 is pushed into the rupturing rod 210, the rupturing membrane 410 is ruptured. At the same time, oxygen is discharged into the rupturing rod 210 and discharged to the nozzle body 300 with oxygen pressure The oxygen compressed and compressed at a high pressure ejected from the oxygen capsule 400 is ejected from the rupture bar 210 and the nozzle body 300 And the safety cover 600 to the inside of the beverage container 100.

According to an embodiment of the present invention, oxygen can be supplied to the beverage in the beverage container 100 by mounting the oxygen capsule 400 storing oxygen in the oxygen injection cap 200 as described above, It is apparent that the injection cap 200 may be equipped with a carbon dioxide capsule storing carbon dioxide to supply carbon dioxide to the beverage in the beverage container 100. [

The oxygen supply cap 500 is detachably coupled to the oxygen injection cap 200 to discharge oxygen. The oxygen supply cap 500 separates the rupture bar 210 and the rupture membrane 410 from the lower part of the oxygen supply cap 500 And a safety ring 510 which is broken when the oxygen cylinder is opened. 5A, since the rupture membrane 410 of the oxygen capsule 400 and the rupture bar 210 are spaced apart from each other by the safety ring 510, The oxygen capsule 400 can be undesirably lowered to prevent the rupture membrane 410 from being ruptured. 5B, when the oxygen supply cap 500 is rotated in the descending direction, the oxygen supply cap 500 is lowered to break the safety ring 510, and at the same time, The rupture membrane 410 of the oxygen capsule 400 is ruptured by the rupture bar 210 while descending.

The safety ring 510 is integrally formed with the oxygen supply cap 500 to inform the state of the initial oxygen capsule 400. The safety ring 510 includes a plurality of And the safety ring 510 is provided with a cut-out portion 512 for easily cutting the perforated line 511. At this time, the safety ring 510 functions to prevent the oxygen capsule 400 from descending unnecessarily during the circulation or storage and to prevent the rupture membrane 410 from being ruptured.

5A, when the safety ring 510 is attached, the oxygen supply cap 500 can not rotate in the downward direction, so that the rupture membrane 410 of the oxygen capsule 400 is not ruptured unnecessarily In order to rupture the rupture membrane 410 of the oxygen capsule 400, it is necessary to hold the oxygen supply cap 500 so that the safety ring 510 is broken as shown in FIG. 5B, The rupture membrane 410 of the oxygen capsule 400 can be ruptured.

The oxygen supply cap 500 protrudes from the center portion of the oxygen supply cap 500 to securely lower the oxygen capsule 400 when the oxygen capsule 400 is in contact with the upper portion of the oxygen capsule 400, A through hole 530 for discharging the compressed air generated at the time of descending to the outside is formed.

According to the present invention, the inner diameter of the oxygen injection cap 200 is formed with a female screw 200a to be coupled with the male screw 111 formed at the outer diameter of the injection port 110. The outer diameter of the oxygen injection cap 200, A male screw 200b and a female screw 500a which are coupled to each other are formed on the inner circumference of the housing 500.

The safety cover 600 is connected to the nozzle body 300. The safety cover 600 is provided with a cut-out portion 610 which is opened by an oxygen pressure. In this case, since the high-pressure oxygen is opened while opening the cut portion 610 of the safety cover 600 when the oxygen capsule 400 is opened, unlike the conventional case, the cut portion 610 of the safety cover 600, The oxygen pressure is not exhausted, so oxygen can be injected to the depth of the drinking water to increase the oxygen dissolution rate.

The safety cover 600 is rigidly and hermetically connected to the nozzle body 300. The safety cover 600 is formed with an incision 610 so as to be opened while being opened by the oxygen pressure only when the oxygen barrier is opened . At this time, the safety cover 600 functions as a check valve. The safety cover 600 is opened when the incision portion 610 is opened by the oxygen pressure discharged to the nozzle body 300 only at the time of entering the oxygen cylinder , The cut portion 610 of the safety cover 600 is normally kept in a closed state while being elastically contacted without being opened. That is, the incision portion 610 of the safety cover 600 is opened and closed by the pressure, and the incision portion 610 of the safety cover 660 is opened by the external pressure and is closed by the internal pressure. Accordingly, it is possible to prevent the gas supplied to the beverage in the beverage container 100 from flowing back to the outside through the burst bar 210.

4 and 5A and 5B, in order to prevent the safety cover 600 from being detached from the nozzle body 300 by the pressure during the oxygen spouting, A locking protrusion 330 and a locking protrusion 620 are coupled to each other and are firmly coupled to each other at the center of the outer diameter of the safety cover 600 and the inner diameter of the safety cover 600.

7, in order to prevent the safety cover 600 from being detached from the nozzle body 300 by the pressure during the oxygen spouting, the outer diameter of the nozzle body 300 and the outer diameter of the safety cover 600 The male screw 340 and the female screw 630, which are screwed together, are tightly coupled to the inner diameter of the female screw 600.

The powder capsule 700 is selectively embedded in the safety cover 600. The powder capsule 700 is introduced into the beverage through the cutout 610 of the safety cover 600 opened by the pressure of the oxygen inlet . At this time, an additive such as a functional food powder, various vitamins powder, a nutrient, a minerals and the like is accommodated in the powder cap method 700.

Therefore, according to the present invention, since oxygen is discharged while the nozzle body 300 is opened by the pressure of the oxygen inlet when it is immersed in the drinking water, oxygen can be structurally ejected with a strong pressure, There is an advantage that the oxygen dissolution rate can be increased by strongly jetting oxygen to the depth of the drinking water.

In addition, since the high-pressure oxygen is opened by opening the cut-out portion 610 of the safety cover 600 while the rupture membrane 410 of the oxygen capsule 400 ruptures, the safety cover 600 The oxygen pressure is not consumed unlike the conventional method. Therefore, oxygen is sprayed up to the depth of the drinking water to increase the oxygen dissolution rate.

In the present invention, since the nozzle body 300 is formed in the connection pipe 220 for supporting the burst barrel 210 and the safety cover 600 for preventing backflow is provided in the nozzle body 300, The oxygen supplied to the beverage in the beverage container 100 structurally can be prevented from flowing back to the outside through the burst bar 210. [

In addition, since the safety ring 510 is provided in the lower part of the oxygen supply cap 500 to separate the rupture bar 210 and the rupture membrane 510 of the oxygen capsule 400 from each other, There is an advantage that the oxygen capsule 400 is undesirably lowered during the distribution process or storage to prevent the rupture membrane 510 from being ruptured.

100: beverage container 110: inlet
200: oxygen injection cap 210: bursting rod
220: connector tube 230:
240: Capsule receiving space 250: Opening indication ring
300: nozzle body 310: thin film part
320: incision section 400: oxygen capsule
410: rupture membrane 500: oxygen supply cap
510: Safety ring 600: Safety cover
610: incision part 700: powder capsule

Claims (6)

A beverage container (100) having an inlet (110) with an open upper portion for receiving beverage; A connection pipe 220 detachably coupled to the injection port 110 to support the burst bar 210 and the burst bar 210 and an oxygen supply unit 210 including a capsule accommodating space 240 and a release indication ring 250, An injection cap 200; A nozzle body 300 integrally or separately formed in the coupling pipe 220 and opened by a pressure of the oxygen inlet; An oxygen capsule 400 mounted on the capsule accommodating space 240 to supply oxygen into the beverage container 100 with the rupture membrane 410 ruptured in the rupture bar 210; And an oxygen supply cap (500) detachably coupled to the oxygen injection cap (200) to inject oxygen,
The fitting part 230 inserted into the injection hole 110 is formed in the oxygen injection cap 200 so as to protrude further downward than the lower edge of the oxygen injection cap 200 to be connected to the lower part of the fitting part 230 A tube 220 is formed,
The nozzle body 300 is opened by the pressure of the oxygen inlet when it is immersed in the beverage contained in the beverage container 100,
The safety ring 510 is connected to the oxygen supply cap 500 by a plurality of perforated lines 511 at the lower part of the oxygen supply cap 500,
A through hole 530 is formed at one side of the upper portion of the oxygen supply cap 500 to discharge compressed air generated when the oxygen supply cap 500 descends,
Wherein the nozzle body (300) is connected to a safety cover (600) for preventing backflow, the cutaway portion (610) being opened by an oxygen inlet pressure. delete The oxygen mixed beverage container according to claim 1, further comprising a powder capsule (700) housed in the safety cover (600) and containing an additive to be injected into beverage through an oxygen occlusion incision (610). The beverage container of claim 1, wherein the beverage container (100) is capable of withstanding the instantaneous pressure ejected from the oxygen capsule (400). The oxygen mixed beverage container according to claim 1, wherein a thin film portion (310) or a cut portion (320) is formed at the bottom of the nozzle body (300) to be opened when an oxygen cylinder is opened. The oxygen mixed beverage container according to claim 1, wherein the nozzle body (300) comprises a check valve.

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