JP2017105534A - Pouring device of carbonated drink - Google Patents

Abstract

PROBLEM TO BE SOLVED: To disclose a pouring device of carbonated drink capable of stably providing carbonated drink with a relatively high carbon dioxide density.SOLUTION: A pouring device of carbonated drink is configured to provide in a vertical direction, a circular recess part for introducing calcareous water through a supply valve of calcareous water, on a valve body which can open and close simultaneously the supply valve of the calcareous water and a supply valve of raw beverage liquid, vertically provide a straight tube-state raw beverage liquid nozzle for supplying the raw beverage liquid through the supply valve of the raw beverage liquid, on an inside concentric part of the circular recess part, a canopy which has a gear-shape in plan view is provided on a middle part of the raw beverage liquid nozzle, the raw beverage liquid supplied from the raw beverage liquid nozzle and calcareous water which flows on the canopy are mixed and then the mixture is poured. An upper stage of the canopy has a hollow cylindrical flow rate adjustor which has a cross section circular hole into which the raw beverage liquid nozzle is inserted, and which is fitted to the circular recess part. The flow rate adjustor has a seal ring on an outer peripheral surface and fitted to the circular recess part in a water-tight state, and an inner diameter of the cross section circular hole is a size for forming a pressure reduction channel of the calcareous water with the raw beverage liquid nozzle.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an apparatus for mixing and pouring carbonated water and beverage stock solutions such as shochu and whiskey diluted with carbonated water.

  Carbonated beverages are one of the favorite beverages that have been popular. In restaurants and the like, beverage servers for mixing and supplying carbonated water and beverage stock solutions such as whiskey, shochu, or juice (syrup) are used.

  As a valve device for a beverage server shown in Non-Patent Document 1, a configuration shown in FIG. 5 is known. In this figure, the configuration related to the present invention will be described briefly. When the operation lever 21 of the valve device is operated, the stock lever 22 and the carbonated water lever 23 are simultaneously operated by the lever principle, and both valves are thereby operated. Open and close 24 and 25. Reference numeral 26 denotes a return spring for returning the operation lever 21. When the operation lever 21 is operated, the valves 24 and 25 are pushed open through the stock solution lever 22 and the carbonated water lever 23, and the stock solution and carbonated water are mixed from the upstream block 27 through the orifices 28 and 29, respectively. Part 10 is introduced. In the valve body 10, the stock solution is ejected in a horizontal direction from a supply hole 12 provided in a part of the tip side cylinder of the stock solution supply cylinder 11, while the carbonated water is supplied into the channel 13 in the body, and the carbonated water It flows down from the periphery of the wheel 14 to the mixing cap 15. In the mixing cap 15, the stock solution ejected from the supply hole 12 is mixed with the flowing carbonated water and supplied from the nozzle 16 of the mixing cap 15 to a beverage container or the like.

  On the other hand, in Patent Document 1, in a carbonated water dispensing valve that mixes and dispenses carbonated water and a beverage stock solution, a cylindrical space whose axis is in the vertical direction immediately before the carbonated beverage discharge port in the carbonated water passage. A cylindrical cone is inserted, leaving the carbonated water introduction space at the top, and decompression using an annular gap formed between the inner peripheral wall surface of the cylindrical space portion and the outer peripheral surface of the cylindrical cone as a decompression passage. An apparatus is disclosed. Further, a rectifying portion having a plurality of U-shaped grooves on the outer peripheral surface is provided at the lower part of the cylindrical cone, and carbonated water from the annular gap is guided to the carbonated beverage discharge port through the U-shaped grooves. It is configured. That is, the carbonated water dispensing valve of Patent Document 1 corresponds to a configuration in which a cylindrical cone is added to the valve device of Non-Patent Document 1.

JP-A-10-194393

“Manual Mixing Valve”, [online], Hayakawa Sangyo Co., Ltd. [searched on November 20, 2015], Internet <URL: http://www.hayakawa-sanki.co.jp/products/?id= 1338290677-758575>

  In the valve device of Non-Patent Document 1 shown in FIG. 5, the stock solution ejected from the supply hole 12 provided on the tip side of the stock solution supply cylinder 11 is mixed with the carbonated water flowing down from the carbonated water wheel 14 in the mixing cap 15. A relatively large amount of carbonated water is supplied from the holes around the carbonated water wheel 14 into the mixing cap 15 like a shower, and the stock solution is ejected from the stock solution supply holes 12, so that the carbon dioxide gas escapes. It tends to end up with fine carbonic acid. Then, there is a problem that it is not suitable for consumers who prefer strong carbonic acid.

  On the other hand, in the carbonated water dispensing valve of Patent Document 1, the carbonated water is decompressed in a passage having a sufficient length and cross-sectional area by a gap formed between the cylindrical cone and the cylindrical space portion. Compared with the valve device of Patent Document 1, the escape of carbon dioxide gas is reduced. In addition, since the carbonated water is caused to flow along the wall surface surrounding the rectification unit by the U-shaped groove provided on the outer periphery of the rectification unit at the lower part of the cylindrical cone, the outer peripheral surface of the cylindrical cone and the cylindrical space part The flow of carbonated water from the gap formed between the inner peripheral surface and the carbonated beverage discharge port becomes smooth, and further, the escape of carbon dioxide gas is reduced. As a result, it is possible to provide a relatively strong carbonated carbonated beverage. become.

  However, in the valve of Patent Document 1, when molding the cylindrical space portion or the cylindrical cone, it is difficult to perform high-precision molding that makes the gap between the two uniform. In other words, in order to make the annular gap uniform, ideally both the cylindrical space portion and the cylindrical cone must be perfectly circular, and the cylindrical cone must be assembled accurately and concentrically with respect to the cylindrical space portion. However, such molding and assembly are difficult and often cause errors. In particular, in Patent Document 1, since the cylindrical cone is attached to a straight tubular beverage stock solution supply pipe in an inner seal state, there is a high possibility that the cylindrical cone is attached with a slight inclination. If it does so, while the gap | interval with the cylindrical space part used as the decompression path of carbonated water will not be ensured enough, there exists a subject that a drink undiluted | mixed solution and mixing unevenness will arise.

  Further, since low-temperature (around 3 ° C.) carbonated water flows through the gap between the cylindrical space and the cylindrical cone, these are cooled and thermally contracted. In particular, since the base part forming the cylindrical space is thinner than the cylindrical cone, there is a problem that the shrinkage rate is large, and the gap is partially blocked by the difference in contraction between the two.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to disclose a carbonated drink server dispensing apparatus capable of stably providing a relatively strong carbonated carbonated drink. That is.

  In order to achieve the above-mentioned object, in the present invention, the carbonated water is introduced into the valve body provided with the carbonated water supply valve and the beverage concentrate supply valve so that they can be opened and closed simultaneously via the carbonated water supply valve. A circular recess is provided in the vertical direction, and a straight tubular stock solution nozzle that supplies the beverage stock solution via the beverage stock solution supply valve is provided concentrically on the inner side of the circular recess, and is flat in the middle of the stock nozzle. An apparatus for pouring carbonated beverages, in which a gear-shaped umbrella body is arranged, and carbonated water passing through the umbrella body and a beverage stock solution supplied from the stock solution nozzle are mixed and poured out. The upper stage is provided with a hollow cylindrical flow rate adjusting body having a circular hole in the center through which the stock solution nozzle is inserted and fitted into the circular recess, and the flow rate adjusting body has a seal ring on the outer peripheral surface. While fitting in a watertight manner in the circular recess, the inner diameter of the circular hole in cross section Using means that sized to form a vacuum flow path of the carbonated water to and from the stock solution nozzle.

  According to the above means, the carbonated water is depressurized in the annular pressure reducing channel formed between the circular hole in the cross section of the flow rate adjusting body and the outer periphery of the stock solution nozzle and flows to the umbrella body. For this reason, carbonated water is gently transmitted through the umbrella body, so that the carbonic acid is less likely to escape compared to the non-patent document 1, and a relatively strong carbonated carbonated beverage can be provided.

  Moreover, in the said means, since the flow volume adjustment body is watertightly fitted to the circular recess in the state of the outer seal, the flow rate is more than the case where the cylindrical cone is attached to the stock solution nozzle in the state of the inner seal as in Patent Document 1. It is easy to fit the adjustment body into a circular recess that is straight in the vertical direction. Furthermore, even if the flow rate adjusting body and the circular recess are not perfect circles, errors can be absorbed by the seal ring. Furthermore, since the circular hole of the cross section of the flow rate adjusting body is used as a carbonated water flow path, both of these are simultaneously cooled using a carbonated water flow path between the cylindrical cone and the cylindrical space as in Patent Document 1. The degree of thermal contraction is much smaller than that of the configuration.

  In the above means, the carbonated water that has passed through the flow rate adjusting body travels along the lower umbrella, and finally travels through the stock solution nozzle. Therefore, it is possible to uniformly mix with carbonated water by using a plurality of supply pores for the beverage stock solution provided in the horizontal direction on the peripheral wall below the umbrella body as the stock solution nozzle. At that time, a hollow cylindrical nozzle cap that accommodates the stock solution nozzle together with the umbrella body is detachably attached to the valve body, so that carbonated water passing through the umbrella body and supply pores of the stock solution nozzle are provided. While preventing the beverage stock solution coming out horizontally from splashing around, these can be mixed and the carbonated beverage can be poured downward.

  Furthermore, it is preferable that a hollow cylindrical nozzle cover that covers the supply pores and supplies the beverage stock solution downward is detachably attached to the stock solution nozzle. According to this, since the beverage stock solution does not adhere to the nozzle cap, when the beverage stock solution is changed to another one, it is only necessary to change the nozzle cover without changing the nozzle cap.

  Furthermore, the nozzle cap has a length for accommodating the nozzle cover, and accommodates the nozzle cover through an upper large-diameter portion that accommodates the umbrella inside, and a reduced-diameter step portion from the upper large-diameter portion. And a narrow cross-sectional area capable of rectifying the carbonated water flowing down the umbrella body as a final flow path of carbonated water between the lower small diameter part and the nozzle cover.

  According to this means, the pressure is reduced in the decompression flow channel upstream of the umbrella body, the carbonated water flowing down the umbrella body is rectified at the final stage before mixing with the beverage stock solution, and the donut shape having a narrow cross-sectional area is obtained. Since the foaming is suppressed by the flow path, a carbonated beverage of strong carbonate can be provided more reliably.

  In addition, it is preferable that the final flow path is formed so that the lower small diameter portion of the nozzle cap and the nozzle cover have an equal inner diameter and outer diameter in the length direction. This is because the cross section of the final flow path is uniform in the vertical direction and the carbonated water is rectified into a laminar flow state, so that foaming of carbonated water can be more reliably suppressed.

  The flow rate adjusting body has a concave shape on the upper surface, so that when carbonated water is introduced into the recessed portion, it functions as a buffer to reduce the flow rate and pressure, and the carbonated water is more reliably transferred to the circular hole in the cross section. Can lead to.

  Similarly, the upper surface of the nozzle cover is also recessed in a circular shape, so that when carbonated water is introduced from the umbrella into the recessed portion, the flow rate and pressure function as a buffer, and the carbonated water is finally discharged in a state where there is no air leakage. It can be supplied to the flow path. Note that the buffer function increases as the depth of these recesses increases.

  According to the present invention, the hollow cylindrical flow rate adjusting body that forms the decompression flow path of carbonated water with the stock solution nozzle is fitted into the circular recess on the valve body side in the state of the outer seal. Can be assembled in a concentric state with the stock solution nozzle more securely, and there is almost no heat shrinkage due to low-temperature carbonated water, even if the outer shape of the flow adjustment body and the circular recess are not perfect circles, It can absorb errors. Therefore, the decompression flow path of carbonated water is ensured reliably, and a relatively strong carbonated carbonated beverage can be provided stably.

1 is an exploded sectional view of a carbonated beverage dispensing device according to an embodiment of the present invention. Cross section after assembly Bottom view of umbrella Assembly sectional view of a carbonated beverage dispensing device according to a second embodiment of the present invention An exploded perspective view of the valve device according to Non-Patent Document 1.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is an exploded view of a dispensing device according to an embodiment of the present invention. From the top, 1 is a valve body, 2 is a flow rate adjusting body for carbonated water, 3 is an umbrella body, 4 is a nozzle cover, and 5 is a nozzle cap. It is.

  The valve body 1 includes a carbonated water supply valve and a beverage stock solution supply valve that are opened and closed simultaneously by operation of the operation lever 1a (both not shown). Since such a structure is known from Non-Patent Document 1, Patent Document 1, and the like, detailed description thereof is omitted. A space 1c for initially introducing carbonated water is formed on the secondary side of the carbonated water supply valve via the carbonated water flow path 1b, and a circular recess is formed continuously below the space 1c. 6 is formed in the vertical direction. As shown in FIG. 2, 1d is a base part provided on the lower surface of the valve body 1 for mounting the nozzle cap 5, and a circular recess 6 is formed in the base part.

  Note that carbonated water is introduced from the carbonated water flow path 1b into the space 1c in the upper stage of the circular recess 6 so as to draw a circle.

  On the other hand, a concentrate flow path 1 e is formed on the secondary side of the beverage concentrate supply valve and communicates with the concentrate nozzle 7. The stock solution nozzle 7 is integral with the valve body 1 and is vertically suspended on the inner side of the circular recess 6. Moreover, although the lower surface is obstruct | occluded, the supply pore 7a which discharge | releases a drink stock solution in a horizontal direction is provided in the lower surrounding wall. In the case of this embodiment, a total of four supply pores 7a are provided at intervals of 90 degrees, but the present invention is not limited to this.

  The flow rate adjusting body 2 is a hollow cylindrical member having a circular hole 2a through which the stock solution nozzle 7 is inserted in the center, and its outer diameter is slightly smaller than the inner diameter of the circular recess 6 and is formed on the outer peripheral surface thereof. Is equipped with a seal ring 8 such as an O-ring. With this seal ring 8, the fluid adjustment body 2 can be fitted into the circular recess 6 in a watertight manner. On the other hand, the circular hole 2a in cross section has an inner diameter that creates an annular gap 9 between the stock solution nozzle 7 and the stock solution nozzle 7 as shown in FIG. The annular gap 9 functions as a decompression flow path for carbonated water.

  In this embodiment, a circular recessed portion 2 b having a predetermined depth is formed on the upper surface of the fluid adjusting body 2. The recessed portion 2b is continuous with the space portion 1c into which the carbonated water is initially introduced in a state where the fluid adjusting body 2 is fitted to the circular recessed portion 6, and the carbonated water introduced so as to draw a circle in the space portion 1c. The centrifugal force (flow velocity and pressure) is weakened and reliably led to the circular hole 2a in cross section.

  As shown in FIG. 3, the umbrella body 3 has a gear shape in plan view in which a plurality of U-shaped grooves 3 a are provided at equal intervals on the outer periphery, and an insertion hole 3 b for the stock solution nozzle 7 is formed at the center. Yes. Further, in this embodiment, the upper and lower surfaces are raised in a substantially conical shape, and a plurality of rib-like ridges 3 c are provided radially from the insertion hole 3 b on the lower surface, and the carbonated water that has passed through the fluid regulator 2 is The umbrella 3 flows down from the upper surface to the lower surface along the groove 3a.

  The nozzle cover 4 is attached to the stock solution nozzle 7 so as to cover the supply pores 7a after the flow rate adjusting body 2 and the umbrella body 3 are assembled, and the insertion hole 4a of the stock solution nozzle 7 is formed at the center, The insertion hole 4a is provided with a seal ring 4b such as an O-ring that is inserted into the stock solution nozzle 7 in a watertight manner. The lower half of the insertion hole 4a has a large diameter portion 4c, and the beverage stock solution discharged from the supply pore 7a is collided with the large diameter portion 4c so that the beverage stock solution is supplied downward from the lower surface opening 4d. ing.

  As shown in FIG. 2, the nozzle cap 5 is a hollow cylinder that is attached to the lower surface of the valve body 1 in a state in which the stock solution nozzle 7 to which the flow rate adjusting body 2, the umbrella body 3, and the nozzle cover 4 are attached is accommodated. This is the final nozzle of this apparatus which pours the diluted solution of the beverage stock solution with carbonated water, that is, carbonated beverage, from the lower surface opening 5a as the outer shape slightly narrowed downward.

  According to the pouring device having the above configuration, the flow rate adjusting body 2 is fitted into the circular recess 6 of the valve body 1 while the stock solution nozzle 7 is inserted through the center thereof, and then the umbrella body 3 and the nozzle cover 4 are fitted to the stock solution nozzle 7. The mounting is completed in order, and finally the nozzle cap 5 is mounted (FIG. 2). At this time, since the flow rate adjusting body 2 is fitted in the circular recess 6 in the state of the outer seal, it can be assembled straightly concentrically with the stock solution nozzle 7 as compared with the configuration inserted in the stock solution nozzle 7 in the state of the inner seal. . Further, even if the inner periphery of the circular recess 6 and the outer periphery of the fluid adjustment body 2 are not perfect circles and are slightly distorted, the seal ring 8 absorbs the distortion, and the cross-sectional circular hole 2a of the fluid adjustment body 2 A gap 9, which is a decompression flow path for carbonated water, can be ensured between the stock solution nozzle 7 and the uniform annular state.

After the assembly is completed in this way, the carbonated water is supplied to the valve main body 1, the flow path 1b, and the space 1c by operating the undiluted solution nozzle 7 operating lever 1a to the open side (the back side in the drawing). Then, the gap 9 between the circular hole 2a in section and the stock solution nozzle 7 is sewn and guided to the umbrella body 3 through the upper surface recessed portion 2b of the flow rate adjusting body 2. At this time, since the fluid adjusting body 2 is an outer seal, the carbonated water does not enter the circular recess 6 of the valve body 1. Therefore, the circular recess 6 (the base 1d) is never thermally contracted by low-temperature carbonated water. In addition, the fluid adjusting body 2 also has a circular cross-sectional hole 2a serving as a carbonated water passage having a sufficiently smaller surface area than the outer peripheral surface, and is sufficiently thick from the cross-sectional circular hole 2a to the outer peripheral surface. The body 2 hardly undergoes heat shrinkage due to low-temperature carbonated water, or is a negligible amount. Therefore, the inner diameter of the circular hole 2a is maintained at the time of molding, and the gap 9 with the stock solution nozzle 7 is also secured in a uniform annular shape. Therefore, carbonated water can be stably supplied to the umbrella 3 in a relatively strong carbonated state, and as a result, a relatively strong carbonated carbonated beverage can be stably supplied.

  Moreover, in this embodiment, since the nozzle cover 4 which covers the supply pore 7a is attached to the tip of the stock solution nozzle 7, the beverage stock solution discharged from the supply pore 7a is supplied downward by the nozzle cover 4. Thus, the beverage stock solution does not directly adhere to the nozzle cap 5. Therefore, the carbonated water traveling along the outer periphery of the nozzle cover 4 can be more uniformly mixed with the beverage stock solution. Further, even when the beverage stock solution is changed to another one, the nozzle cover 4 is simply replaced, and the nozzle cap 5 is not required to be cleaned.

  However, the nozzle cover 4 can be omitted, and even in this case, a relatively strong carbonated beverage can be stably supplied.

  FIG. 4 is a carbonated beverage dispensing apparatus according to the second embodiment of the present invention. In addition, about the structure which is common in 1st embodiment, the same code | symbol is attached | subjected, further detailed description is omitted, and the structure and effect which are peculiar to 2nd embodiment different from 1st embodiment are demonstrated hereafter. .

  The characteristic configuration of the second embodiment in contrast to the first embodiment is primarily the internal structure of the nozzle cap 50. As shown in FIG. 4, the nozzle cap 50 has an internal structure of an upper large-diameter portion 52 that accommodates the umbrella body 3 in the upper portion thereof via a reduced diameter step portion 51 with the umbrella body 3 as a boundary, A two-stage configuration having a lower small-diameter portion 53 that accommodates the nozzle cover 4 is provided at the lower portion. Among these, in particular, the inner diameter of the lower small-diameter portion 53 is uniform in the vertical direction, and is in the range of H to the tip tapered portion 4e of the nozzle cover 4 in the figure. The donut-shaped flow path 60 is formed in the upper part.

  The channel 60 is the final channel before the carbonated water flowing down the umbrella 3 is mixed with the beverage stock solution supplied from the nozzle cover 4, and the cross-sectional area thereof is a value that suppresses foaming of the carbonated water. It is set. That is, in order to suppress the foaming of carbonated water, it is preferable to reduce the clearance between the inner diameter of the lower small diameter portion 53 of the nozzle cap 50 and the outer diameter of the nozzle cover 4 to reduce the cross-sectional area.

  Further, in this second embodiment, foaming is performed so that carbonated water flows in a laminar flow state with the cross-sectional area of the channel 60 being equal in the vertical direction so that carbonated water does not cause turbulent flow in the final channel 60. It is suppressed. In addition, in the part (below H) which covers the front-end | tip taper part 4e of the nozzle cover 4, clearance with the lower side small diameter part 53 becomes large, but this part is a part which mixes carbonated water with a drink stock solution. Because of its short length, carbonated water does not escape greatly. However, also in the tip tapered portion 4e, in order to make the clearance with the lower small diameter portion 53 uniform, a part of the lower end of the lower small diameter portion 53 may be a tapered inner diameter portion, or the nozzle cap 50 may be As it is, the outer diameter of the nozzle cover 4 may be the same over the entire length.

  Furthermore, as a second feature of the second embodiment, the depth (step length) of the recessed portion 4f formed on the upper surface of the nozzle cover 4 is made larger than that of the first embodiment. The recessed portion 4f of the nozzle cover 4 is similar to the recessed portion 2b formed on the upper surface of the flow rate adjusting body 2, and reduces the flow rate of carbonated water flowing into the nozzle cover 4 to suppress foaming. The larger the size, the higher the foaming suppression effect of carbonated water.

DESCRIPTION OF SYMBOLS 1 Valve | bulb main body 1a Operation lever 1b Carbonated water flow path 1c Space part 1d Base part 1e Stock solution flow path 2 Flow volume adjusting body 2a Cross-sectional circular hole 2b Recessed part 3 Umbrella body 3a Groove 3b Insertion hole 3c Convex strip 4 Nozzle cover 4a Insertion hole 4b Seal Ring 4c Large diameter portion 4d Lower surface opening 5/50 Nozzle cap 5a Lower surface opening 6 Circular recess 7 Stock solution nozzle 7a Supply pore 8 Seal ring 9 Gap (Reduced flow path of carbonated water)

Claims (7)

A circular recess for introducing the carbonated water through the carbonated water supply valve is provided in a vertical direction in a valve body provided with a carbonated water supply valve and a beverage stock solution supply valve that can be opened and closed simultaneously. A straight-tube stock solution nozzle for supplying the beverage stock solution via the beverage stock solution supply valve is concentrically disposed on the inside, and a gear-shaped umbrella body in a plan view is arranged in the middle of the stock solution nozzle, A carbonated beverage pouring device that mixes and pours carbonated water that travels through an umbrella and a beverage stock solution supplied from the stock solution nozzle, and the stock solution nozzle is inserted into the upper part of the umbrella body in the center. A hollow cylindrical flow rate adjusting body that has a circular hole in section and fits into the circular recess is disposed, and the flow rate adjuster has a seal ring on the outer peripheral surface and is fitted watertight to the circular recess. The inner diameter of the circular hole in the cross section is reduced in pressure between the carbonated water and the stock solution nozzle. Dispensing device of carbonated drinks, characterized in that the sized to form a tract. The stock solution nozzle is provided with a plurality of supply pores of beverage stock solution in the horizontal direction on the peripheral wall below the umbrella body, and the valve body has a hollow cylindrical nozzle cap that houses the stock solution nozzle together with the umbrella body The carbonated beverage pouring device according to claim 1, wherein the beverage is detachably attached. The carbonated beverage pouring device according to claim 2, wherein a hollow cylindrical nozzle cover that covers the supply pores and supplies the beverage stock solution downward is further detachably mounted on the stock solution nozzle. The nozzle cap has a length for accommodating the nozzle cover, and includes an upper large-diameter portion that accommodates the umbrella inside, and a lower side that accommodates the nozzle cover from the upper large-diameter portion via a reduced diameter step portion. The small-diameter portion is provided, and a narrow cross-sectional area capable of rectifying the carbonated water flowing down the umbrella is provided as a final flow path of carbonated water between the lower small-diameter portion and the nozzle cover. Carbonated beverage dispensing device. 5. The carbonated beverage pouring device according to claim 4, wherein the inner diameter of the lower small diameter portion of the nozzle cap and the outer diameter of the nozzle cover in the final flow path are equal to each other in the length direction. The carbonated beverage pouring device according to claim 1, wherein the flow rate adjusting body has a concave upper surface. The carbonated beverage pouring device according to any one of claims 3 to 6, wherein the nozzle cover has an upper surface recessed in a circular shape.

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