KR20140074695A - Device for making carbonated drink - Google Patents

Abstract

Disclosed is a manufacturing device of carbonated soft drink, which can manufacture carbonated soft drink with a high quality having abundant carbonated gas dissolved. The disclosed manufacturing device of carbonated soft drink comprises a fixed volumetric part accommodating drink, having an upper opening part formed to be open so as to inject drink, and fixing the volume; a container having a variable volumetric part connected to the fixed volumetric part and changing the volume; a cover combined to the container to be separable, sealing the upper opening part of the container, and having a carbonated gas injection unit so as to inject carbonated gas into the container; and a carbonated gas supply unit connected to the carbonated gas injection unit and injecting high pressure carbonated gas higher than the atmosphere into the container via the cover.

Description

Device for making carbonated drink

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a carbonated beverage maker capable of easily producing carbonated drinks at home, restaurants, and the like.

There are carbonated beverages and carbonated beverages mass-produced at the beverage production plant, but carbonated beverage makers are also known that can easily manufacture their own unique carbonated beverages at home or at restaurants. A typical carbonated drink maker is provided with a container capable of containing beverages and a carbon dioxide gas injector for injecting carbon dioxide gas (CO ₂ ) into the container. A beverage such as drinking water or juice is put into the container and a carbonic acid gas To make a carbonated beverage. However, before the carbon dioxide gas is injected, the container is already filled with a large amount of air with the beverage, so that even if the carbon dioxide gas is injected into the container, it is difficult to make a carbonated beverage having a small amount of carbonic acid gas dissolved therein.

The present invention provides a carbonated beverage maker capable of producing a carbonated beverage of good quality with a large amount of carbonic acid dissolved therein.

The present invention also provides a carbonated beverage maker capable of easily producing a carbonated drink at a home or a restaurant.

The present invention relates to a beverage dispenser for a beverage dispenser, the beverage dispenser comprising: a beverage dispenser for dispensing beverage, the beverage dispenser having an upper opening opened to allow the beverage to be introduced therein and having a fixed volume that is unchanged in volume, A cover having a container portion having a volume portion; a cover detachably coupled to the container and sealing a top opening of the container, the cover having a carbon dioxide gas injecting portion formed to inject carbon dioxide gas into the container; And a carbonic acid gas supply unit connected to the carbonic acid gas injection unit and injecting a carbonic gas having a higher pressure than a normal pressure into the container through the cover.

The carbonated beverage manufacturing machine of the present invention further includes a housing made of a hard material detachably coupled to the cover to contain the container by suppressing over-expansion of the container .

The carbonated beverage maker of the present invention further comprises a housing support portion supporting a bottom of the housing and a container support having a protruding portion protruding upward from the housing support portion, The projection of the support may enter the interior of the housing through the lower opening of the housing to support the bottom of the container such that the variable volume is not inflated.

The variable volume portion may include bellows that expand in a downward direction as the pressure increases.

The carbon dioxide gas supply unit includes a gas tank containing carbon dioxide gas, a gas hose extending from the gas tank to the carbonic acid gas injection unit and capable of flowing carbon dioxide gas, And a valve for controlling the flow rate of the carbonic acid gas.

The carbon dioxide gas supply unit may further include a pressure gauge that measures and displays the pressure of the carbon dioxide gas discharged from the gas tank to the gas hose.

According to the carbonated beverage maker of the present invention, the air remaining in the container can be minimized before the carbon dioxide gas is injected, so that a carbonated beverage of good quality in which the flavor of the carbon dioxide gas is strongly felt can be produced.

Further, according to the carbonated drink manufacturing machine of the present invention, a carbonated drink can be easily manufactured at home or a restaurant, and a unique carbonated drink which can not be found in an existing carbonated drink produced by mass production can be manufactured by mixing various materials such as fruits and coffee have.

1 is an exploded perspective view showing a carbonated drink manufacturing apparatus according to an embodiment of the present invention.
2 to 5 are sectional views sequentially showing a carbonated drink manufacturing process using the carbonated beverage maker of FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a carbonated drink manufacturing machine according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The terminology used herein is a term used to properly express the preferred embodiment of the present invention, which may vary depending on the intention of the user or operator or the custom in the field to which the present invention belongs. Therefore, the definitions of these terms should be based on the contents throughout this specification.

1 is an exploded perspective view showing a carbonated drink manufacturing apparatus according to an embodiment of the present invention. 1, a carbonated beverage maker 10 according to an embodiment of the present invention is a device that can easily produce a carbonated beverage in a home or a restaurant, and includes a container 27, a cover 11, A housing 37, a container support 42, and a carbon dioxide gas supply unit 50. In the container 27, for example, drinking water such as drinking water, fruit juice is accommodated. The container 27 is in the form of a cylinder, and the upper opening 33 is opened so that drinking water can be injected. The container 27 has a fixed volume 28 that is constantly unchanged in volume and a variable volume 30 that is connected to the fixed volume 28 and is of variable volume. 1, the variable volume portion 30 is connected under the fixed volume portion 28, but the present invention is not necessarily limited thereto.

The variable volume portion 30 has a bellows 31 that expands downward as the pressure inside the container 27 increases. The bellows 31 shown in FIG. 1 is not limited to the five-stage bellows, but the bellows included in the present invention is not necessarily limited to the five-stage bellows. In addition, the variable volume portion 30 is not necessarily limited to a bellows, but may be replaced with another type of collapsible vessel. The container 27 may be made of silicone resin or other plastic material. Alternatively, the fixed volume portion 28 may be made of a metal material such as stainless steel, for example, and the variable volume portion 30 may be made of a flexible material such as silicone resin. Alternatively, only the folded and stretched portion of the bellows 31 may be made of a flexible material such as silicone resin, and the other portion may be made of a hard material such as a metal material.

The cover 11 is detachably coupled to the container 27 and seals the upper opening 33 of the container 27 when the container is joined. An upper end thread portion 34 is formed on the outer periphery of the upper end of the container 27 in which the upper opening 33 is formed so that the cover 11 and the container 27 are engaged. A lower female threaded portion is formed on the lower side of the cover 11 so as to engage with the upper male threaded portion 34. [ The rigidity of the periphery of the upper opening 33 is maintained under the upper end male thread portion 34 of the container 27 when the cover 11 and the container 27 are engaged and the rigidity between the cover 11 and the container 27 A flange 35 is provided to secure the sealing.

The cover 11 is provided with a carbon dioxide gas injection unit 20 formed to be capable of injecting carbon dioxide (CO ₂ ) into the container 27 coupled to the cover 11. The carbonic acid gas injecting unit 20 includes an injection hole 22 formed through a cover 11 on one side of the cover 11 and a distal threaded portion 21 formed to be able to engage with the carbonic acid gas supply unit 50. [ Respectively. The cover 11 also has a beverage discharge portion 17 formed so as to discharge the manufactured carbonated beverage out of the container 27. The beverage discharging portion 17 covers the cover 11 in the container 27 so as to prevent the beverage from being blown out to the outside due to the carbonic acid filled in the container 27 when the cover 11 is separated from the container 27 And discharges the carbonic acid in the container 27 partially to the outside before the separation from the container 27. [ The beverage discharge portion 17 includes a discharge hole 19 formed through the cover 11 at the central portion of the cover 11 and a distal threaded portion 18 formed to be coupled to the beverage discharge port cap 25 do. The beverage outlet cap 25 is detachably coupled to the beverage outlet 17 and seals the outlet aperture 19 unopened during the carbonated beverage production process. Although not shown, a female threaded portion is formed on the inside of the beverage discharge cap 25 so as to engage with the end threaded portion 18. The cover 11 may be made of, for example, a metal material such as stainless steel or a hard plastic material.

The housing 37 is detachably coupled to the cover 11 to enclose the container 27 to suppress over-expansion of the container 27. The housing 37 is in the form of a cylinder and has an upper opening 38 opened upward to allow the container 27 to be inserted and a lower opening 40 opened lower to allow the container support 42 to pass therethrough do. The cover 11 is fitted in the upper opening 38 of the housing 37 so as to close the upper opening 38 of the housing 37 so that when the cover 11 and the housing 37 are engaged, The lower outer circumferential surface 14 is in close contact with the upper inner circumferential surface of the housing 37 and the upper end 39 of the housing 37 is horizontally inserted into the outer jaw 13 of the cover 11 radially projecting from the center of the cover 11 So that the cover 11 is not inserted deeply into the inside of the housing 37. The housing 37 is made of, for example, a metal material such as stainless steel or a rigid material such as hard plastic or glass.

The container support base 42 has a disk-shaped housing support 45 for supporting the bottom of the housing 37 and a protrusion 43 protruding upward from the housing support 45. The outer diameter of the projecting portion 43 is smaller than the inner diameter of the lower opening 40 so as to be able to enter the inside of the housing 37 through the lower opening 40. The protruding portion 43 enters the interior of the housing 37 through the lower opening 40 to support the bottom of the container 27 so that the variable volume portion 30 is not inflated. The container support table 42 is made of, for example, a rigid plastic material.

The carbonic acid gas supply unit 50 is connected to the carbonic acid gas injecting unit 20 of the cover 11 to supply carbon dioxide gas (CO ₂ ) of high pressure higher than normal pressure to the inside of the container 27 Lt; / RTI > The carbonic acid gas supply unit 50 includes a gas tank 51 containing high-pressure carbon dioxide (CO ₂ ) and a gas tank 51 extending from the gas tank 51 to the carbonic acid gas injection unit 20 of the cover 11. hose (57). The carbon dioxide gas (CO ₂ ) can flow from the gas tank 51 to the carbonic acid gas injection unit 20 through the inside of the gas hose 57. A connector 59 is detachably connected to the distal end thread portion 21 of the carbonic gas injection portion 20 at the distal end of the gas hose 57. Although not shown, a female screw portion engaged with the distal male thread portion 21 is formed on the inside of the connector 59.

The carbonic acid gas supply unit 50 includes a valve 52 for regulating the flow rate of carbon dioxide gas (CO ₂ ) discharged from the gas tank 51 to the gas hose 57, And a pressure gauge 55 for measuring and displaying the pressure of carbon dioxide (CO ₂ ) discharged to the gas hose 57. When turning the dial 53 to adjust the degree of opening of the valve 52 the flow rate of carbon dioxide gas (CO ₂₎ are discharged to the gas hose 57 from the gas tank 51 is adjusted, the pressure of carbon dioxide (CO ₂₎ Is confirmed by the pressure gauge 55. Therefore, it is possible to prevent degradation of the carbonated beverage due to breakage of the container 27 or the cover 11 due to excess pressure of the supplied carbon dioxide (CO ₂ ), or underpressure of the supplied carbon dioxide (CO ₂ ) .

2 to 5 are sectional views sequentially showing a carbonated drink manufacturing process using the carbonated beverage manufacturing machine of FIG. 1. Hereinafter, referring to FIGS. 2 to 5, a carbonated beverage manufacturing machine 10 Explain the method. 2, the container support 42 is fitted to the housing 37 such that the protrusion 43 protrudes upward through the lower opening 40 of the housing 37. At this time, the bottom of the housing 38 is supported by the bottom support 45 of the container support 42. The container 27 is folded so that the volume of the variable volume portion 30 is minimized and inserted into the housing 37 through the upper opening 38 of the housing 37 so as to be inserted into the protrusion 43 to the bottom of the container 27. Next, the beverage 2 is filled into the container 27 through the upper opening 33 of the container 33. Then, The beverage 2 may be, for example, drinking water, fruit juice, or alcohol. The variable volume portion 30 is supported by the protruding portion 43 so that the volume of the variable volume portion 30 is not inflated because the bellows 31 is inflated despite the load of the beverage 2 to be filled.

3, the cover 11 is coupled to the container 27 such that the upper opening 33 (see FIG. 1) of the container 27 is closed and sealed. It can be engaged by turning the upper end male thread portion 34 of the container 27 and the female threaded portion (not shown) of the cover 11 into rotation with respect to the other side. When the cover 11 and the container 27 are combined, the water level L1 of the drinking water 2 remains in the container 27 when the drinking water 2 is filled to such a degree as to touch or almost touch the lower surface of the cover 11. [ Air can be minimized and a carbonated drink having a high content of carbon dioxide gas can be obtained.

Then, the cover 11 and the housing 37 are engaged. The cover 11 can be easily joined to the housing 37 by aligning the cover 11 with respect to the upper opening 38 (see Fig. 2) of the housing 37 and lowering it downward. The beverage outlet 17 of the cover 11 is closed and sealed by the outlet cap 25 and the connector 59 of the carbonic acid gas supply unit 50 is connected to the carbonic acid gas injection unit 20 of the cover 11, Lt; / RTI > Next, the container support 42 is pulled out from the lower opening 40 of the housing 37 and separated from the housing 37, and the dial 53 of the carbonic acid gas supply unit 50 is turned appropriately The carbon dioxide gas (CO ₂ ) starts to be injected into the container 27 through the injection hole 22 of the carbonic acid gas injection unit 20 at a pressure higher than the atmospheric pressure.

4, carbon dioxide (CO ₂ ) is continuously injected into the container 27 through the injection hole 22, so that the pressure inside the container 27 rises and the variable volume portion 30 expands (CO ₂ ) is dissolved in the beverage ₂ (refer to FIG. ₂ ) to become the carbonated beverage 5. As the amount of carbon dioxide gas (CO ₂ ) injected into the container 27 increases, the carbonic acid gas (CO ₂ ) dissolved increases and the carbonic acid concentration of the carbonated beverage 5 increases. The water level L2 of the carbonated beverage 5 becomes lower than the water level L1 before the carbon dioxide gas (CO ₂ ) injection (refer to FIG. 3) as the variable volume portion 30 expands, and the high- (CO ₂ ) is filled.

5, when the variable volume portion 30 is appropriately inflated and is no longer inflated, the valve 52 is rotated in a direction opposite to that when the dial 53 of the carbonic acid gas supply unit 50 is supplied, Thereby shutting off the supply of gas (CO ₂ ). If carbon dioxide (CO ₂₎ when supplying carbon dioxide gas (CO ₂₎ is, or introduced into the container 27 to the excessively high pressure return too much dial 53 state, the carbon dioxide (CO ₂₎ supply interruption is too The container 37 is prevented from excessive expansion of the container 27 so that the container 27 or the cover 11 is prevented from being ruptured or damaged due to pressure. Therefore, the carbonated beverage can be safely produced using the carbonated drink maker 10 (see Fig. 1).

Next, the beverage discharging portion cap 25 is separated from the beverage discharging portion 17 to open the discharging through hole 19 and the carbonated beverage 5 contained in the container 27 through the discharging through hole 19 is discharged to the outside The carbonated beverage 5 may be transferred to the cup (not shown) or the glass (not shown), and the carbonated beverage 5 may be fed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

10: Carbonate drink maker 11: cover
17: Drink discharge part 20: Carbonic acid gas injection part
25: beverage outlet cap 27: container
28: Fixed volume section 30: Variable volume section
31: Bellows 37: Housing
40: lower opening 42:
43: protruding portion 45: housing supporting portion
50: Carbonic acid gas supply unit 55: Pressure gauge

Claims (4)

And a variable volume portion which is connected to the fixed volume portion and whose volume is variable so that the upper opening is opened so as to allow the beverage to be poured therein and the volume A container;
A cover detachably coupled to the container and sealing the upper opening of the container, the cover having a carbonic acid gas injection unit formed to inject carbon dioxide gas into the container; And
And a housing made of a hard material detachably coupled to the cover to contain the container by suppressing over-expansion of the container. The carbonated beverage producing machine according to claim 1,
Further comprising: a housing support portion supporting the bottom of the housing; and a container support having a protruding portion protruding upward from the housing support portion,
Wherein the protrusion of the container support is configured to support the bottom of the container so that the variable volume does not enter the interior of the housing through a lower opening formed in the bottom of the housing. 3. The method of claim 2,
Wherein the variable volume portion has bellows that expand in a downward direction as pressure increases. The carbonated beverage producing machine according to claim 1,
Further comprising a carbonic acid gas supply unit connected to the carbonic acid gas injection unit and injecting carbonic gas having a higher pressure than normal pressure into the container through the cover.

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