KR101522820B1 - A carbonated water mixing apparatus - Google Patents

Abstract

Provided is a carbonated water mixing apparatus. According to an embodiment of the present invention, the carbonated water mixing apparatus comprises: a mixing portion for mixing original water and carbon dioxide, and manufacturing carbonated water; a storage tank connected to the mixing portion through a transfer line, storing the carbonated water, manufactured in the mixing portion, for a certain amount, and discharging outside through a discharge line; and a compressing portion installed in the transfer line, and compressing the carbonated water which is transferred to the storage tank from the mixing portion. The storage tank is arranged to make a lower side sunk in cold water stored in a cold water tank of a water purifier, and the carbonated water entered in the storage tank is naturally cooled through the cold water stored in the cold water tank. The compressing portion comprises: an expansion portion having a wider cross-sectional area than a cross-sectional area of the transfer line, and mixing the carbonated water for a second time through swirl; and a first connecting portion and a second connecting portion having a narrower cross-sectional area than the cross-sectional area of the transfer line, and respectively connecting the expansion portion to the transfer line. The cross-sectional area of the first connecting portion, discharging the carbonated water to the storage tank from the expansion portion, is relatively bigger than the cross-sectional area of the second connecting portion, supplying the carbonated water to the expansion portion from the mixing portion, and is relatively smaller than the cross-sectional area of the transfer line.

Description

[0001] The present invention relates to a carbonated water mixing apparatus,

The present invention relates to a carbonated water mixing apparatus.

Generally, a water purifier is a device that allows drinking water to be purified by supplying water through a separate water tank or a water supply facility installed in the room.

Most water purifiers are installed in public places such as restaurants, companies, hospitals, banks, etc. In recent years, consumers are increasingly assuming the installation of water purifiers with lower reliability. In addition to the function of providing cold and hot water, a water purifier for providing carbonated water has appeared, and carbonated water packed in a separate container can be purchased in the market.

However, the commercially available carbonated water is difficult to maintain the storage environment constantly during the distribution process, and the carbonate level is low, so that the taste of the consumer is not satisfied. Moreover, consumers in European countries prefer carbonated water with a high carbonation level, which has limited the ability to satisfy consumer needs with containerized carbonated water.

A conventional water purifier for providing carbonated water stores carbon dioxide and water in a mixed state, and supplies the stored carbonated water when the user wants to receive carbonated water. However, as the storage time of the water already mixed with the carbonic acid gas becomes longer, the carbonic acid level of the carbonated water becomes lower.

To solve this problem, Korean Patent Laid-Open No. 10-2013-0044988 discloses a method of supplying carbonated water by injecting carbon dioxide gas into a mixer in which water is stored when a user wishes to supply carbonated water and mixing the carbonated gas. However, in the above patent, since the water mixed with the carbonic acid gas is simply mixed by the pressure of the carbonic gas supplied in the rectified state stored in the mixer, not only the solubility of the carbonic acid gas is low but also the mixed carbonated water is not completely discharged There is a problem that it is difficult to supply carbonated water of a constant quality because it is mixed with carbonated water.

Further, since water is mixed with the carbonic acid gas in a state where water is retained in the mixer, the temperature of the carbonic acid produced is lukewarm and a separate cooling device for cooling the carbonic acid water is required to solve the problem. There was a problem.

One embodiment of the present invention is to provide a carbonated water mixing apparatus

According to one aspect of the present invention, there is provided a mixing unit for mixing carbon dioxide with raw water to produce carbonated water; A storage tank connected to the mixing portion through a transfer line to store a predetermined amount of carbonated water produced in the mixing portion and discharged to the outside through a discharge line; And a pressurizing unit provided on the transfer line for pressurizing the carbonic acid water transferred from the mixing unit to the storage tank side, wherein the storage tank is disposed so as to be submerged in the cold water stored in the cold water tank of the water purifier, Wherein the carbonic acid water introduced into the tank side is naturally cooled through cold water stored in the cold water tank, the pressurizing portion has a cross-sectional area wider than the cross-sectional area of the transfer line and has an enlarged portion for mixing the carbonated water with the vapors through a vortex, Wherein the cross-sectional area of the first connection portion for discharging the carbonated water from the enlargement portion to the storage tank side is larger than the cross-sectional area of the enlargement portion in the mixing portion, the first connection portion and the second connection portion connecting the enlarged portion to the transfer line, Is larger than the cross-sectional area of the second connection portion for supplying the carbonic acid water to the sub- Instead of being cross-sectional area to provide the carbonated water mixing device which is provided to be smaller relatively.

At this time, the mixing unit includes a cover having a raw water inlet through which raw water flows and a carbon dioxide inlet through which carbon dioxide flows; A first cylinder having a mixing space for mixing raw water supplied through a raw water inlet and a carbonic acid gas inlet with carbonic acid gas and having at least one discharge port through which carbonated water mixed with raw water and carbonic acid gas is discharged; And a second cylinder having a storage space for storing a predetermined amount of carbonated water discharged through the discharge port.

At this time, the upper part of the mixing part may have at least one outlet communicating with the storage space so that the carbonated water stored in the storage space can be discharged upward.

At this time, the discharge port is coupled with a discharge pipe extending a certain length to the lower part, and the discharge pipe may be provided so that at least a part including the lower end is submerged in the carbonated water stored in the storage space.

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At this time, the raw water flowing into the mixing portion may be cold water stored in the cold water tank of the purifier.

At this time, a discharge line for discharging the carbonated water stored in the storage tank is connected to the storage tank, and a cold water supply line connected to the cold water tank of the water purifier is connected to the discharge line at the middle of the length, And the concentration of the carbonic acid water discharged to the outside can be adjusted.

At this time, a water level sensor for adjusting the amount of carbonated water stored in the storage tank may be provided.

The carbonated water mixing apparatus according to an embodiment of the present invention can always produce cool carbonated water even without an additional cooling apparatus and can obtain carbonated water having a concentration suitable for each individual taste.

1 is an overall schematic view showing a carbonated water mixing apparatus according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view showing a detailed configuration of a mixing portion in a carbonated water mixing apparatus according to an embodiment of the present invention. FIG.
3 is a schematic view showing a detailed configuration of a pressurizing unit in a carbonated water mixing apparatus according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

 1 is an overall schematic view showing a carbonated water mixing apparatus 100 according to an embodiment of the present invention. Hereinafter, a carbonated water mixing apparatus 100 according to an embodiment of the present invention will be described in detail with reference to the drawings.

Referring to FIG. 1, a carbonated water mixing apparatus 100 according to an embodiment of the present invention includes a mixing section 110 and a storage tank 120.

The mixing unit 110 mixes raw water supplied from the outside with carbonic acid gas to produce carbonated water.

Here, the raw water flowing into the mixing unit 110 may be purified water supplied from the water purifier, or the cold water stored in the cold water tank 10 of the purifier.

1 and 2, the mixing unit 110 includes a raw water inlet 119b and a carbonic acid gas inlet 119a through which raw water and carbonic acid gas are supplied from the outside, respectively, and the carbonic acid gas and raw water And a mixing space (S1) in which they are mixed with each other.

That is, the mixing unit 110 includes a first tubular body 111 and a second tubular body 112 having an inner space and the first tubular body 111 is disposed inside the second tubular body 112 Respectively. At this time, between the outer surface of the first cylinder 111 and the inner surface of the second cylinder 112, a storage space S2 in which a predetermined amount of carbonated water produced by mixing carbon dioxide and raw water are stored is provided.

A lid 113 is detachably coupled to an upper side of the first cylinder 111 to seal the opened upper portion of the first cylinder 111. That is, the lid 113 and the first cylinder 111 may be formed with threaded portions corresponding to each other on the contact surface, thereby increasing the sealing force through the threaded connection.

The lid 113 is provided with the raw water inlet 119b and the carbonic acid gas inlet 119a so that raw water and carbonic acid gas are introduced into the inside of the first cylinder 111, respectively.

The carbonic acid gas and the raw water flowing into the first cylinder 111 through the raw water inlet 119b and the carbonic acid gas inlet 119a are discharged from the mixing space S1 provided in the first cylinder 111 They are mixed with each other and made of carbonated water. At this time, at least one discharge port 118 communicating with the storage space S2 is provided in the first cylinder 111 so that the carbonated water produced in the mixing space S1 can be moved toward the storage space S2. do.

The carbonic acid gas and the raw water supplied to the mixing space S1 through the carbonic acid gas inlet 119a and the raw water inlet 119b are supplied to the mixing space S1 through the carbonic acid gas inlet 119a and the raw water inlet 119b. But it may be guided through the first supply pipe 114 and the second supply pipe 115 connected to the carbonic acid gas inlet 119a and the raw water inlet 119b, respectively.

The first supply pipe 114 and the second supply pipe 115 have closed ends 114a and 115a at their lower ends and the carbon dioxide gas and raw water are supplied to the closed ends 114a and 115a, And at least one air blow-out port 114b, 115b for blowing air to the side S1.

At this time, the first supply pipe (114) is provided to have a relatively longer length than the second supply pipe (115), and is arranged to have a shorter distance from the bottom surface of the first cylinder (111). This is because the relatively high-pressure carbonic acid gas is ejected through the air outlet 114b and then collides with the bottom surface of the first cylinder 111 and is scattered, thereby dissolving well in the raw water supplied through the second supply pipe 115 The raw water supplied at a relatively low pressure is prevented from flowing back through the second supply pipe 115 in the mixing process with the carbonic acid gas and smoothly flows toward the mixing space S1 through the air outlet 115b So that it can be discharged.

In addition, the discharge port 118 is formed at a position spaced upward from the bottom surface of the first cylinder 111 by a predetermined height, so that the carbonated water mixed in the mixing space S1 is directly discharged through the discharge port 118 So that it can be moved after staying for a predetermined time without being moved to the space S2 side.

The discharge port 118 is located at a lower position than the lower end of the discharge pipe 116 when the discharge pipe 116 is provided at the discharge port 119c and is connected to the storage space S2 through the discharge port 118. [ So that the carbonated water moved to the side of the discharge pipe 116 is not immediately discharged through the discharge pipe 116.

Meanwhile, carbonic acid gas may be supplied to the mixing space S1 through the carbonic acid gas inlet 119a while a predetermined amount of the raw water supplied through the raw water inlet 119b is stored and mixed with each other. However, The carbon dioxide gas and the raw water may be simultaneously introduced into the mixing space S1 and mixed with each other.

At this time, a bottom plate of the first cylinder 111 may be provided with a plurality of projections 117 having a plurality of protrusions so that carbon dioxide gas supplied from the first supply tube 114 may be scattered and scattered. As a result, the carbon dioxide gas ejected from the first supply pipe 114 collides with the non-oxidized plate 117 whose surface is uneven by the plurality of protrusions, so that atomization is promoted and the raw water supplied from the second supply pipe 115 The solubility can be increased.

Accordingly, even if the raw water and the carbonic acid gas are mixed with each other in a direct water system in the mixing space S1, carbon dioxide gas is atomized through the scattering plate 117 to increase the solubility of the carbonic acid gas in the raw water A high quality carbonate level can be ensured.

The second cylinder 112 provides a space for temporarily storing carbonated water produced in the mixing space S1. The second cylinder 112 is provided in a shape of an enclosure having a storage space S2 in which an upper portion thereof is opened, and the first cylinder 111 is detachably coupled to the opened upper side. That is, it is preferable that threaded portions corresponding to the first tubular body 111 and the second tubular body 112 are formed on the contact surfaces, so that the sealing force can be increased.

The carbonated water discharged through the discharge port 118 of the mixing space S1 is discharged into the storage space S2 formed between the outer surface of the first cylinder 111 and the inner surface of the second cylinder 112 A certain amount is stored.

At least one outlet 119c communicating with the storage space S2 is provided in the second cylinder 112 so that the carbonated water stored in the storage space S2 can be discharged to the outside.

The outlet 119c may be provided on the lower side of the second cylinder 112 but may be provided on the upper side of the second cylinder 112 so that the carbonated water stored in the storage space S2 may be discharged upward do.

The discharge port 119c is connected to a discharge tube 116 having a predetermined length and at least a portion including a lower end thereof is submerged in the carbonated water stored in the storage space S2.

Accordingly, even if the carbonated water is not completely filled in the storage space S2, at least a part of the discharge pipe 116 including the lower end is immersed in the carbonated water stored in the storage space S2, So that it can be discharged to the outside.

In addition, when the storage space S2 is fully filled with carbonated water, the carbonated water can be discharged to the outside through the discharge pipe 116 by the internal pressure, and the carbonated water stored in the storage space S2 When the gas is not in the full water state, the gas space separated from the carbonated water can be filled in the free space side where the carbonated water is not stored. By the pressure of the separated gas and the inflow pressure of the carbonated water supplied through the discharge port 118, So that it can be smoothly discharged upward through the discharge tube 116.

Here, the discharge pipe 116 is open at its lower end, so that the carbonated water stored in the storage space S2 can smoothly move upwards along the discharge pipe 116.

The carbonic acid gas supplied to the mixing space S1 through the carbonic acid gas inlet 119a is supplied through the carbonic acid gas supply unit 140 connected to the carbonic acid gas inlet 119a and the carbonic acid gas supply line 165 do.

The carbonic acid gas supply unit 140 may include a decompression unit 142 to maintain a constant pressure of carbon dioxide gas flowing into the mixing space S1.

1, the carbonic acid gas supply unit 140 includes a gas container 141 in which a predetermined amount of the carbonic acid gas is stored, and a gas container 141 for discharging the carbon dioxide gas ejected from the gas container at a predetermined pressure. And a decompression unit 142 for regulating the discharge pressure of the carbonic acid gas discharged from the decompression unit.

The decompression unit 142 includes a main body 144 having an internal space and having an inlet 143 for introducing carbon dioxide gas ejected from the gas container 141 into the internal space, 143 for adjusting the opening area of the blocking member 145 and a spring member 146 disposed on the upper side of the blocking member 145 to adjust the position of the blocking member 145 through elastic force. A carbonic acid gas supply line 165 connected to the carbonic acid gas inlet 119a is connected to one side of the main body 144.

The carbonic acid gas ejected from the gas container 141 is moved to the inner space of the main body 144 through the inlet 143 and then flows into the mixing space S1 through the carbonic acid gas supply line 165 .

At this time, the carbonic acid gas ejected from the gas container 141 is restricted in the movement height of the blocking member 145 by the elastic force of the spring member 146, so that the pressure of the carbon dioxide gas flowing into the inner space side is kept constant .

The storage tank 120 discharges carbonated water stored in the storage tank 120 to the outside through a discharge line 162 connected to one side of the storage tank 120 in which a predetermined amount of the carbonated water produced in the mixing unit 110 is stored.

The storage tank 120 is provided in an enclosure having an internal space 122 and is connected to the discharge port 119c of the mixing unit 110 through a transfer line 161, And carbonated water flows through the transfer line 161.

The carbonated water produced in the mixing unit 110 is moved to the inner space 122 side of the storage tank 120 through the transfer line 161 and stored for a predetermined amount, So that it is possible to sufficiently supply the required amount of the carbonated water of good quality.

Here, a first valve 151 may be provided on the discharge line 162 to open and close the flow passage of the discharge line 162.

At this time, the storage tank 120 is disposed so as to be submerged in the cold water tank 10 provided in the known water purifier, so that the carbonated water stored in the storage tank 120 is cooled by the cold water of the cold water tank 10 .

Therefore, in the carbonated water mixing apparatus 100 according to the embodiment of the present invention, when the carbonated water produced in the mixing section 110 is stored in the storage tank 120 and cooled by the cold water of the cold water tank 10 So that the user can always obtain carbonated water having a temperature substantially equal to the temperature of the cold water without having to provide a separate cooling device for cooling the carbonated water.

The storage tank 120 is detachably coupled to or integrally formed with the lid 12 covering the upper portion of the cold water tank 10 so that when the cold water tank 10 and the lid 12 are engaged, So that the storage tank 120 can be disposed inside the cold water tank 10.

The cold water tank 10 is connected to the raw water inlet 119b of the mixing unit 110 through the cold water supply line 163 so that the cold water stored in the cold water tank 10 is discharged from the mixing unit 110 It can be used as raw water to be mixed with carbon dioxide gas.

In addition, a second valve 152 for opening and closing the flow path of the cold water supply line 163 is provided on the cold water supply line 163 to allow or block the supply of the cold water to the mixing part 110 side.

In this case, the storage tank 120 is provided therein with water level sensing means 124 for sensing the amount of carbonated water stored in the storage tank 120 and controlling the amount of carbonated water produced in the mixing portion 110 May be provided.

Here, the water level sensing means 124 may be provided in the form of a float to be raised or lowered according to a water level, or a variety of known sensors such as a level sensor and an optical sensor may be used.

When the predetermined amount of carbonated water is stored in the storage tank 120, the first valve 151 is operated to cool the mixing unit 110 along the cold water supply line 163 in the cold water tank 10, When the amount of the carbonic acid water stored in the storage tank 120 becomes smaller than the predetermined amount by using the carbonated water, the second valve 152 is operated, The cold water is introduced into the water tank 110 to produce carbonated water.

Therefore, the predetermined amount of carbonated water is always stored in the storage tank 120, and the carbonated water stored in the storage tank 120 through the cold water of the cold water tank 10 can be maintained in a constantly cooled state .

Meanwhile, the cold water supply line 163 may be connected to a discharge line 162 through which carbonated water is discharged to the outside through a separate branch line 164 in the middle of the length. At this time, a third valve 153 is provided on the branch line 164 to allow or block the inflow of cold water to the discharge line 162 side.

When the user discharges the carbonated water stored in the storage tank 120 through the discharge line 162, the cold water not mixed with the carbonic acid gas is discharged through the discharge line 162 through the branch line 164 So that the concentration of the carbonic acid water finally discharged to the outside can be adjusted.

Thus, the user can easily acquire carbonated water satisfying an appropriate concentration desired by the user.

Here, the first valve 151, the second valve 152, and the third valve 153 may be a known solenoid valve, and the operation of the first valve 151, the second valve 152, and the third valve 153 may be controlled by a controller provided in the water purifier.

In the meantime, the carbonated water mixing apparatus 100 according to the embodiment of the present invention presses and mixes the carbonated water discharged from the mixing unit 110 on the transfer line 161 again, and then transfers the mixed water to the storage tank 120 side A pressure unit 130 for increasing the concentration of carbonated water stored in the storage tank 120 may be provided.

As shown in FIG. 3, the pressure unit 130 is provided in a known orifice shape so that the carbonic acid water can be mixed again through the change of the sectional area of the channel during the movement process.

The pressing unit 130 sequentially arranges the first connecting unit 131, the enlarging unit 132 and the second connecting unit 133 in the middle of the length of the transfer line 161.

The first connection part 131 and the second connection part 133 are provided to have a cross sectional area relatively smaller than the cross sectional area of the transfer line 161 so that the speed can be increased in the process of passing the carbonated water, The enlarged portion 132 disposed between the connection portion 131 and the second connection portion 133 is provided to have a relatively larger cross sectional area than the first connection portion 131 and the second connection portion 133.

The carbonated water discharged to the upper portion through the discharge port 119c of the mixing portion 110 flows into the enlarged portion 132 in a state where the speed is increased while passing through the second connection portion 133, A vortex is generated inside the enlarged portion 132 having the above-described shape. And then is transferred to the storage tank 120 along the transfer line 161 through the first connection part 131. [

In this case, the first connection part 131 is relatively larger in cross-sectional area than the second connection part 133 and has a relatively smaller cross-sectional area than the transfer line 161. Therefore, the carbonated water flowing along the transfer line 161 after being mixed in the enlarging unit 132 can smoothly move to the storage tank 120 side.

The carbonated water mixing apparatus according to an embodiment of the present invention can always produce cool carbonated water even without an additional cooling apparatus and can obtain carbonated water having a concentration suitable for each individual taste.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: Carbonated water mixing device
110: mixing part 111: first cylinder
112: second cylinder 113: cover
114: first supply pipe 114a: closed end
114b: air outlet 115: second supply pipe
115a: sealing end 115b: air outlet
116: Discharge tube 117:
118: discharge port 119a: carbon dioxide gas inlet
119b: raw water inlet 119c: outlet
120: Storage tank 122: Inner space
124: Water level sensing means 130:
131: first connection part 132: enlarged part
133: second connection part 140: carbon dioxide gas supply part
141: Gas container 142: Pressure reducing section
143: inlet 144:
145: blocking member 146: spring member
151: first valve 152: second valve
153: third valve 161: transfer line
162: discharge line 163: cold water supply line
164: branch line 165: carbon dioxide gas supply line

Claims (10)

A mixing unit for mixing the raw water and the carbonic acid gas to produce carbonated water;
A storage tank connected to the mixing portion through a transfer line to store a predetermined amount of carbonated water produced in the mixing portion and discharged to the outside through a discharge line; And
And a pressurizing unit provided on the transfer line for pressurizing carbonated water transferred from the mixing unit to the storage tank,
The storage tank is disposed so that the lower side thereof is submerged in cold water stored in the cold water tank of the water purifier so that the carbonated water flowing into the storage tank side is naturally cooled through the cold water stored in the cold water tank,
Wherein the pressing portion has a wider cross section than the cross-sectional area of the transfer line and has a widening portion for mixing the carbonated water with the vortex through a second flow and a cross-sectional area that is narrower than the cross-sectional area of the transfer line, A connection portion and a second connection portion,
Sectional area of the first connection part for discharging the carbonated water from the enlargement part toward the storage tank is relatively larger than the cross-sectional area of the second connection part for supplying the carbonated water to the enlarged part side in the mixing part and relatively smaller than the cross- Water mixing device. The method according to claim 1,
The mixing unit
A cover having a raw water inlet through which raw water flows and a carbonic acid gas inlet through which carbon dioxide flows;
A first cylinder having a mixing space for mixing raw water supplied through a raw water inlet and a carbonic acid gas inlet with carbonic acid gas and having at least one discharge port through which carbonated water mixed with raw water and carbonic acid gas is discharged; And
And a second cylinder having a storage space for storing a predetermined amount of carbonated water discharged through the discharge port. 3. The method of claim 2,
And at least one outlet communicating with the storage space so that carbonated water stored in the storage space can be discharged upwardly on an upper side of the mixing section. The method of claim 3,
Wherein the discharge port is connected to a discharge pipe extending a predetermined length to the lower portion, and at least a part of the discharge pipe including the lower end is provided to be submerged in the carbonated water stored in the storage space. delete delete delete The method according to claim 1,
And the raw water flowing into the mixing portion side is cold water stored in a cold water tank of the water purifier. The method according to claim 1,
The discharge line is connected to a cold water supply line connected to the cold water tank of the water purifier in the middle of the length, and the cold water is supplied through the cold water supply line. And the concentration of the carbonated water discharged to the outside is controlled. The method according to claim 1,
And a water level sensor for controlling the amount of carbonic acid stored in the storage tank.

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