KR20160134965A - Carbonatted water producing device - Google Patents

Abstract

The present invention relates to a carbonated water production device. According to an embodiment of the present invention, provided is a carbonated water production device comprising: a storage tank in which cold water is stored; a carbon dioxide cylinder in which carbon dioxide is stored; a mixer which is connected to the storage tank via a cold water supply passage, which is connected to the carbon dioxide cylinder via a carbon dioxide supply passage, and in which carbonated water is generated; a pump which is provided on the cold water supply passage, and which supplies the cold water of the storage tank to the mixer; a regulator which is coupled to one side of the carbon dioxide cylinder, which is connected to the cold water supply passage and the carbon dioxide supply passage, and which regulates the amount of carbon dioxide to be supplied based on pressure of the cold water; a power supply unit which applies voltage to the pump; a voltage detection unit which detects the voltage applied to the pump; a current detection unit which detects current flowing through the pump; and a control unit which, when a carbonated water generation signal is input, controls the power supply unit to apply voltage to the pump, receives feedbacks of the detected voltage and current and calculates power of the pump, and adjusts magnitude of voltage, to be applied to the pump by the power supply unit, based on the calculated power.

Description

[0001] CARBONATTED WATER PRODUCING DEVICE [0002]

The present invention relates to a carbonated water generating apparatus.

Recently, a water purifier has a function of not only supplying raw water by filtering raw water, but also a water purifier having various functions so that useful ingredients can be added to human being.

For example, a product has been introduced that allows carbon dioxide to be supplied to a water purifier so that carbonated drinking water can be easily supplied when drinking water.

Such a carbonated water producing apparatus generally comprises a carbon dioxide gas pressure vessel for storing initial carbon dioxide gas and an air supply unit for supplying carbon dioxide through an orifice so that carbon dioxide is supplied through the orifice to the vessel to generate bubbles, To produce carbonated water.

However, the conventional carbonated water producing apparatus has a problem that it is difficult to produce carbonated water by selecting the concentration of carbon dioxide gas.

That is, even if the user desires soft carbonated water or tough carbonated water, the user can not provide carbonated water with a desired concentration.

Further, since carbonated water is generated in advance and stored in a separate storage tank, carbonated water is provided to the user, so that there is a problem that the concentration may vary from the generated carbonated water.

The following patent document 1 relates to a carbonated water purifier, but does not provide a solution to the above-mentioned problem.

Korean Patent Laid-Open No. 10-2013-0044988

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a carbonated water producing apparatus capable of supplying carbonated water of a desired concentration and supplying carbonated water of various concentrations.

Also, the present invention provides a carbonated water producing apparatus capable of generating and supplying carbonated water immediately at a desired time, and reducing the concentration change of the generated carbonated water.

The carbonated water producing apparatus according to an embodiment of the present invention is connected to the storage tank through which the cold water is stored, the carbon dioxide cylinder stored with the carbon dioxide, and the cold water supply path, is connected to the carbon dioxide cylinder through the carbon dioxide supply path, A pump for generating carbonated water; a pump provided in the cold water supply path for supplying cold water of the storage tank to the mixer; a pump connected to one side of the carbon dioxide cylinder and connected to the cold water supply path and the carbon dioxide supply path, A regulator capable of regulating a supply amount of the carbon dioxide according to the pressure of the cold water, a power supply for applying a voltage to the pump, a voltage detector for detecting a voltage applied to the pump, a current detector for detecting a current flowing in the pump, When a signal is input, the power supply unit is controlled A controller for applying a voltage to the pump, calculating a power of the pump by feeding back the detected voltage and current, and adjusting a magnitude of a voltage applied to the pump by the power supply unit in accordance with the calculated power .

In one embodiment, the control unit may store information on a target concentration of carbonated water corresponding to the carbonated water generation signal, and may control the power supply unit so that the calculated power becomes the target power, Can be adjusted.

In one embodiment, the carbonated water producing apparatus may further include a first inlet connected to the cold water supply path, a second inlet connected to the carbon dioxide supply path, and an outlet connected to the extraction path.

In one embodiment, the apparatus may further include a carbonated water generation signal input unit for outputting the carbonated water generation signal according to the carbonated water generation input to the control unit.

In one embodiment, the carbonated water generating signal input section may include a plurality of carbon dioxide concentration input sections for generating carbonated water having different target concentrations.

In one embodiment, the plurality of carbonic acid concentration inputs may be capable of adjusting the magnitude of the target concentration set in each of the carbonic acid concentration input units.

In one embodiment, when a signal for controlling the magnitude of the target concentration is input from the plurality of carbonic acid concentration input units, the control unit sets the previously stored target power corresponding to the preset target concentration to the adjusted target concentration The target power can be changed and stored.

In one embodiment, when a signal for controlling the magnitude of the target concentration is inputted from one of the plurality of carbonic acid concentration input units, the control unit sets the target power for the other carbonic acid concentration input unit by the changed value of the changed target power Can be changed and stored.

According to an embodiment of the present invention, a user is provided with carbonated water of a desired concentration by feeding back a voltage applied to a pump and a current corresponding thereto, and performing power control of the pump based on the feedback voltage and the current, The predetermined carbonic acid concentration can be adjusted to a user desired carbonic acid concentration, and the user can supply carbonic acid water having various concentrations desired.

Also, the user can generate and supply carbonated water immediately at a desired time, and the concentration change of the generated carbonated water can be reduced.

1 is a view for explaining a carbonated water producing apparatus according to an embodiment of the present invention.
2 is a view for explaining a carbonated water producing apparatus according to another embodiment of the present invention.
3 is a view for explaining the operation of the carbonated water producing apparatus according to an embodiment of the present invention.
4 is a view for explaining an embodiment of the carbonated water generating signal input unit of FIG.
5 is a partial cutaway view of a regulator showing a state before cold water is introduced into a regulator provided in a carbonated water producing apparatus according to an embodiment of the present invention.
6 is a partial cutaway view of a regulator in which cold water flows into a regulator provided in a carbonated water producing apparatus according to an embodiment of the present invention.
7 and 8 are views showing a modified embodiment of the regulator provided in the carbonated water producing apparatus according to the embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art.

In the drawings referred to in the present invention, elements having substantially the same configuration and function will be denoted by the same reference numerals, and the shapes and sizes of the elements and the like in the drawings may be exaggerated for clarity.

FIG. 1 is a view for explaining a carbonated water producing apparatus according to an embodiment of the present invention, and FIG. 2 is a view for explaining a carbonated water producing apparatus according to another embodiment of the present invention.

1, a carbonated water producing apparatus according to an embodiment of the present invention includes a storage tank 10, a carbon dioxide cylinder 20, a mixer 30, a pump 40, a regulator 50, a power supply unit 60, A voltage detector 70, a current detector 80, and a controller 90. Here, the carbonated water producing apparatus may further include a resistor 100. The carbonated water producing apparatus may further include a carbonated water extracting pipe 110.

In one embodiment, the carbonated water producing apparatus may further include a carbonated water generating signal input unit 120, as shown in FIG.

The storage tank 10 may store cold water. The storage tank 10 may be connected to the mixer 30 by a cold water supply path L1 and the pump 40 and the regulator 50 may be provided in the cold water supply path L1.

The cold water stored in the storage tank 10 can be supplied to the mixer 30 via the regulator 50 by the pressure of the pump 40. [

The carbon dioxide cylinder 20 can store carbon dioxide therein. Here, the carbon dioxide cylinder 20 may be connected to the mixer 30 and the regulator 50 by the carbon dioxide feed path L2. Accordingly, the carbon dioxide cylinder 20 can discharge the stored carbon dioxide to the mixer 30 by the regulator 50.

The mixer 30 can receive the cold water flowing from the storage tank 10 and the carbon dioxide discharged from the carbon dioxide cylinder 20 through the regulator 50. The mixed cooler 30 mixes the supplied cold water with carbon dioxide to generate carbonated water have.

In one embodiment, the mixer 30 may be provided with a first inlet 31, a second inlet 32 and an outlet 33.

In the mixer 30, cold water may be introduced through the first inlet 31, and carbon dioxide may be introduced through the second inlet 32. In addition, the generated carbonated water can be discharged through the discharge port 33.

In one embodiment, the mixer 30 may include one first inlet 31 and a second pair of inlets 32. The first inlet 31 may be disposed on the upper portion of the mixer 30 and the pair of second inlets 32 may be disposed on the side portion of the mixer 30.

Accordingly, the cold water flowing through the first inlet 31 and the carbon dioxide flowing through the second inlet 32 may cross each other in the mixer 30, and the cold water and the carbon dioxide are mixed with each other Carbonated water can be generated.

On the other hand, the check valve 31a is provided on the first inlet 31 side of the mixer 30 to prevent the cold water from flowing backward from the mixer 30. [

The discharge port L3 connected to the extraction valve V1 and the drainage line L4 provided with the drain valve V2 may be connected to the discharge port 33, respectively.

The carbonated water extracted through the extraction channel L3 may be supplied to the user through the carbonated water extraction pipe 110 and the resistor 100 may be provided between the extraction valve V1 and the carbonated water extraction pipe 110. [ Here, the resistor 100 can maintain a predetermined pressure in the mixer 30 and the extraction passage L3.

In the process of generating and supplying carbonated water, the extraction valve V1 can be kept open and the drain valve V2 can be kept closed. After the supply of the carbonated water to the user is completed, the extraction valve V1 is closed and the drain valve V2 is opened so that the inside of the cold water supply path L1, the carbon dioxide supply path L2 and the mixer 30 The pressure can be released.

On the other hand, the extraction valve V1 can be opened when the pump 40 is operated in conjunction with the pump 40. [

Since the cold water supply passage L1, the carbon dioxide supply passage L2, the mixer 30 and the extraction passage L3 are connected to each other in the carbonated water producing apparatus according to the embodiment of the present invention, when the extraction valve V1 is opened The entire flow path (except for the drainage flow path L4) in the carbonated water producing device can be opened with respect to the outside air (hereinafter referred to as outside air).

Therefore, in the carbonated water producing apparatus, the cold water supplied into the mixer 30 and the carbon dioxide are mixed while flowing continuously to generate the carbonated water, and the generated carbonated water is not stored in the carbonated water producing apparatus It can be supplied to the user immediately.

That is, the carbonated water producing apparatus according to an embodiment of the present invention may be a direct carbonated water producing apparatus in which the generated carbonated water is directly supplied to a user, and thus a separate storage space for storing the generated carbonated water is required not.

In the case where the carbonated water is generated in advance and stored in a separate storage space in the apparatus and then supplied to the user, the predetermined period of time is elapsed while the carbonated water is stored. Therefore, the concentration of the carbonated water is changed, It becomes difficult to supply. Another problem is that carbonated water of different concentration is supplied every time the carbonated water is extracted.

However, the apparatus for producing carbonated water according to an embodiment of the present invention can generate carbonated water at a desired time and supply the generated carbonated water directly to the user, so that the user can supply the user with a constant concentration of carbonated water without changing the concentration.

The pump 40 may be disposed between the storage tank 10 and the regulator 50. The pump 40 may be supplied with a predetermined voltage from the power supply unit 60 and may pump the cold water stored in the storage tank 10 into the mixer 40 through the regulator 50.

The regulator 50 is coupled to one side of the gas cylinder and can be connected to the cold water supply path L1 and the carbon dioxide supply path L2 of the storage tank 10 respectively and is connected to the regulator 50 through the pump 40 The carbon dioxide stored in the carbon dioxide cylinder 20 can be discharged to the mixer 30 by the pressure of the cold water supplied to the mixer 30. [

Here, the pressure of the cold water passing through the regulator 50 may be proportional to the supply amount of the carbon dioxide supplied to the mixer 30.

In other words, by regulating the pressure of the cold water passing through the regulator 50, the amount of carbon dioxide discharged into the mixer 30 through the regulator 50 can be regulated.

The regulator 50 will be described in more detail below with reference to FIGS. 5 to 6. FIG.

The power supply unit 60 may apply a constant voltage to the pump 40 under the control of the controller 90. Here, the voltage may be varied under the control of the controller 90.

The voltage detector 70 may detect the voltage applied to the pump 40 and feed back the detected voltage to the controller 90. Here, the voltage detector 70 may be a voltage sensor that detects the voltage applied to the pump 40, and any known sensor may be used as long as the voltage detector 70 can detect the voltage.

The current detector 80 detects the current flowing by the voltage applied to the pump 40 and can feed back the detected current to the controller 90. Here, the current detector 80 may be a current sensor that detects the current, and any known sensor may be used as long as it is capable of detecting a voltage.

When the carbonated water generation signal is input, the controller 90 controls the power supply unit 60 to apply a constant voltage to the pump 40. [ Here, the controller 90 can feed back the voltage applied to the pump 40 and the current flowing to the pump 40 from the voltage detector 70 and the current detector 80, and the feedback voltage and current Power control can be performed so that predetermined power can be supplied to the pump 40 by adjusting the voltage to be supplied to the pump 40. [ Here, the controller 90 may store information on the target concentration of carbonated water corresponding to the carbonated water generating signal.

Specifically, when the carbonated water generation signal is input, the control unit 90 controls the power supply unit 60 so that a target electric power corresponding to the target concentration contained in the carbonated water generation signal is supplied to the pump 40 To the pump (40).

At this time, the voltage applied to the pump 40 and thus the current flowing to the pump 40 is controlled by the extraction valve V1 and the carbonic acid water extraction so as to provide a constant pressure to the inside of the mixer 30, A change in pressure caused by the resistor 100 provided between the tube 110, and the like.

In this case, the pump 40 is supplied with a power different from the target power, and thus the generated carbonic acid concentration of the generated carbonic acid also becomes different from the target concentration.

In order to solve such a problem, the control unit 90 can calculate the electric power provided to the pump 40 by using the voltage and current fed back from the voltage detecting unit 70 and the current detecting unit 80, By adjusting the magnitude of the voltage applied to the pump 40 by the power supply 60 when the power is different from the target power, the target power can be provided to the pump 40.

Accordingly, the carbonated water producing apparatus according to an embodiment of the present invention can supply the user with carbonated water having a predetermined concentration.

In one embodiment, the control unit 90 may include at least one processing unit and memory. The processing unit may include a central processing unit (CPU), a graphics processing unit (GPU), a microprocessor, an application specific integrated circuit (ASIC), a field programmable gate array (FPGA) And may have a plurality of cores. The memory 1120 can be a volatile memory (e.g., RAM, etc.), a non-volatile memory (e.g., ROM, flash memory, etc.) or a combination thereof.

The carbonated water generation signal input unit 120 may receive a carbonated water generation signal for generating carbonated water from a user and provide the carbonated water generation signal to the control unit 90.

The carbonated water generating signal input unit 120 will be described in more detail below with reference to FIG.

3 is a view for explaining the operation of the carbonated water producing apparatus according to an embodiment of the present invention.

3, when power is first supplied to the pump 40, the pump 40 can supply the cold water stored in the storage tank 10 to the mixer 30 through the regulator 50. [ At this time, the carbon dioxide stored in the carbon dioxide cylinder 20 may be supplied to the mixer 30 by the pressure of the cold water passing through the regulator 50.

The mixer 30 mixes the cold water and the carbon dioxide supplied through the regulator 50 to generate carbonated water and discharge the carbonated water through the carbonated water extraction pipe 110 to the outside.

4 is a view for explaining an embodiment of the carbonated water generating signal input unit of FIG.

4, the carbonated water generation signal input unit 120 according to an embodiment of the present invention may include a plurality of carbon dioxide concentration input units 122, 124, and 126.

The plurality of carbonic acid concentration input units 122, 124, and 126 may provide input means to the user to generate carbonate water of different target concentrations.

In one embodiment, the plurality of carbonic acid concentration input sections 122, 124, and 126 include a first carbonic acid concentration input section 122 for outputting a carbonic acid water generation signal for generating carbonic acid water having a high carbonic acid concentration (for example, 6000 ppm or more) A second carbonic acid concentration input section 124 for outputting a carbonic acid water generation signal for generating a carbonic acid water having a bicarbonate concentration (for example, 5500 ppm) to the control section 90 and a second carbonic acid concentration input section 124 for generating a carbonic acid water having a low carbonic acid concentration And a third carbonic acid concentration input unit 126 for outputting the generated signal to the control unit 90.

Here, the controller 90 may store the target power corresponding to each of the carbonated water generation signals input from the plurality of carbonic acid concentration input units 122, 124, and 126.

In one embodiment, the plurality of carbonic acid concentration inputs 122, 124, and 126 may adjust the magnitude of the target concentration set in each carbonic acid concentration input. When a signal for controlling the magnitude of the target concentration is input from the plurality of carbonic acid concentration input sections 122, 124, and 126, the control section 90 controls the input signals of the respective carbonic acid concentration input sections 122, 124, The target power corresponding to the adjusted target concentration can be changed and stored.

For example, when the target concentration set in the third carbonic acid concentration input unit 126 is 5000 ppm and the target power corresponding to the target concentration is 43 W, the user selects the third carbonic acid concentration input unit 126 The carbon dioxide concentration input unit 126 can adjust the set target concentration to 5200 ppm.

In this case, the third carbonic acid concentration input unit 126 may output a signal for controlling the magnitude of the target concentration from 5000 ppm to 5200 ppm to the control unit 90, and the control unit 90 sets the target power to 43W To a target power corresponding to 5200 ppm (for example, 45W).

After the target concentration is adjusted as described above, if the user provides the carbonate water generation input through the third carbonate concentration input unit 126, the third carbonate concentration input unit 126 outputs the carbonated water generation signal to the control unit 90 The control unit 90 supplies the changed target stored power of 45 W to the third carbonic acid concentration input unit 126 in accordance with the carbonic acid water generation signal input from the third carbonic acid concentration input unit 126 Power control can be performed.

In one embodiment, the plurality of carbonic acid concentration inputs 122, 124, 126 may each limit the adjustment range so that they can be adjusted only within a predetermined range.

For example, when the carbonic acid concentration of the first carbonic acid concentration input unit 122 is 6000 ppm and the carbonic acid concentration of the third carbonic acid concentration input unit 126 is 5000 ppm, the carbonic acid concentration control range of the second carbonic acid concentration input unit 124 May be limited to less than 5000 and less than 6000 ppm.

In one embodiment, when the target power of the carbonic acid concentration input unit is changed by adjusting the target concentration of any one of the plurality of carbonic acid concentration input units 122, 124, and 126, the target power Can be changed by the changed value of the changed carbonic acid concentration input unit and stored.

For example, if the carbonic acid concentration of the first carbonic acid concentration input section 122 is 6000 ppm, the target electric power corresponding thereto is 53 W, the carbonic acid concentration of the second carbonic acid concentration input section 124 is 5500 ppm, The carbonic acid concentration of the third carbonic acid concentration input section 126 is adjusted to 5500 ppm when the electric power is 48 W and the carbonic acid concentration of the third carbonic acid concentration input section 126 is 5000 ppm and the corresponding target electric power is 43 W The control unit 90 can adjust the target power corresponding to the third carbonic acid concentration input unit 126 to 48 W and adjust the target power corresponding to the second carbonic acid concentration input unit 124 to 53 W, The target power corresponding to the first carbonic acid concentration input unit 126 can be adjusted to 56 W. [

FIG. 5 is a partial cut-away view of a regulator showing a state before cold water flows into a regulator provided in a carbonated water producing apparatus according to an embodiment of the present invention, and FIG. 6 is a sectional view of a regenerator provided in a carbonated water producing apparatus according to an embodiment of the present invention Fig. 3 is a partial cutaway view of a regulator showing the inflow of cold water into a provided regulator. Fig.

7 and 8 are views showing a modified embodiment of a regulator provided in a carbonated water producing apparatus according to an embodiment of the present invention.

First, the operation of the regulator 50 will be described with reference to Figs. 5 and 6. Fig.

The regulator 50 is coupled to one side of the carbon dioxide cylinder 20 to regulate the amount of carbon dioxide supplied from the carbon dioxide cylinder 20 to the mixer 30. [

The regulator 50 includes a main body 51 having an internal space, a cold water inlet 52 provided at a side portion of the main body 51 to communicate with the internal space, a cold water outlet 53 and a cold water outlet 53 And a carbon dioxide supply port 54 connected to the carbon dioxide cylinder 20.

The cold water inlet port 52 and the cold water outlet port 53 are connected to the cold water supply path L1 and the cold water in the storage tank 10 is received by the cold water inlet port 52 by the pressure of the pump 40, 53). At this time, the inner space of the main body 51 can function as a channel through which cold water flows.

The inner space of the main body 51 is provided with a pin 55 for opening or closing the carbon dioxide cylinder 20 and the pin 55 can be elastically connected to the carbon dioxide cylinder 20.

Accordingly, when an external force is applied to the pin 55, the pin 55 is pushed, whereby the carbon dioxide cylinder 20 is opened and carbon dioxide is supplied through the carbon dioxide supply port 54. Carbon dioxide is supplied to the carbon dioxide supply port Is supplied to the mixer (30) through the carbon dioxide feed path (L2) connected to the feed pipe (54).

When the external force applied to the pin 55 is removed, the carbon dioxide cylinder 20 is closed, thereby stopping the supply of carbon dioxide.

At this time, when the external force applied to the pin 55 is removed, the pin 55 returns to the original position (the position before the external force is applied to the pin 55) by the internal pressure of the carbon dioxide cylinder 20 .

A plunger 56 may be provided in the inner space of the main body 51 as a medium for applying a force to the pin 55.

A seal member is provided between the outer surface of the plunger 56 and the inner surface of the main body 51 to seal the upper and lower sides of the plunger 56. A pin 55 is disposed below the plunger 56 .

When the external force (that is, the pressure of the cold water flowing in the internal space of the main body 51) is not applied to the plunger 56, the pin 55 is not subjected to the force, so that the carbon dioxide cylinder 20 is in the closed state Lt; / RTI >

However, when the cold water flows into the internal space of the main body 51, the plunger 56 is pushed toward the pin 55 according to the pressure of the cold water, so that the carbon dioxide cylinder 20 is opened and the carbon dioxide supply port 54 ) To be supplied with carbon dioxide.

Here, the force by which the plunger 56 presses the pin 55 can be changed according to the magnitude of the pressure of the cold water flowing in the inner space of the main body 51. [

That is, when the pressure of the cold water is relatively large, the plunger 56 presses the pin 55 relatively firmly, thereby increasing the supply amount of the carbon dioxide supplied to the mixer 30.

In addition, when the pressure of the cold water is relatively small, the plunger 56 presses the pin 55 relatively weakly, thereby decreasing the supply amount of the carbon dioxide supplied to the mixer 30.

Since the supply amount of the carbon dioxide supplied to the mixer 30 is affected by the pressure of the cold water, the supply amount of the carbon dioxide can be adjusted by adjusting the pressure of the cold water supplied by the operation of the pump 40.

Also, since the pressure of the cold water is affected by the magnitude of the voltage applied to the pump 40, the supply amount of the carbon dioxide can be adjusted according to the magnitude of the voltage applied to the pump 40.

Therefore, by controlling the magnitude of the voltage applied to the pump 40, the user can supply carbonated water having various concentrations (for example, high concentration, medium concentration, low concentration) desired by the user.

Next, a modified embodiment of the regulator 50 will be described with reference to Figs. 7 and 8. Fig.

5 and 6 except for the elastic member 57 that elastically supports the plunger 56 in the modified embodiment of the regulator 50. The description of the elastic member 57 other than the elastic member 57 Is omitted.

A plunger 56 may be provided in the inner space of the main body 51 as a medium for applying a force to the pin 55.

A pin 55 may be disposed under the plunger 56 and the plunger 56 may be resiliently supported upward by the elastic member 57 in the inner space of the main body 51.

Therefore, when the external force (that is, the pressure of cold water flowing in the internal space of the main body 51) is not applied to the plunger 56, the plunger 56 is resiliently supported by the elastic member 57, 56 and the pin 55 remain spaced apart from each other, and the internal space of the main body 51 is formed to be relatively narrow.

However, when the cold water flows into the internal space of the main body 51, the plunger 56 is pressed toward the pin 55 according to the pressure of the cold water (accordingly, the internal space of the main body 51 becomes relatively large , So that the carbon dioxide cylinder 20 is opened and carbon dioxide is supplied through the carbon dioxide supply port 54.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the particular forms disclosed. 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.

10: Storage tank
20: Carbon dioxide cylinder
30: Mixer
40: pump
50: Regulator
60: Power supply
70: Voltage detector
80: current detector
90:
100: Resistor
110: carbonated water extraction pipe

Claims (9)

A storage tank in which cold water is stored;
A carbon dioxide cylinder storing carbon dioxide;
A mixer connected to the storage tank through a cold water supply path, connected to the carbon dioxide cylinder through a carbon dioxide supply path, and generating carbonated water therein;
A pump provided in the cold water supply path to supply cold water of the storage tank to the mixer;
A regulator coupled to one side of the carbon dioxide cylinder and connected to the cold water supply path and the carbon dioxide supply path and capable of controlling the supply amount of the carbon dioxide according to the pressure of the cold water;
A power supply for applying a voltage to the pump;
A voltage detector for detecting a voltage applied to the pump;
A current detector for detecting a current flowing through the pump; And
The control unit controls the power supply unit to apply a voltage to the pump when the carbonated water generating signal is input, calculates the power of the pump by feeding back the detected voltage and current, and controls the power supply unit A controller for adjusting a magnitude of a voltage applied to the pump;
And a water tank.
The apparatus of claim 1,
The control unit controls the power supply unit to adjust the magnitude of the voltage applied to the pump so that the calculated power corresponds to the target power corresponding to the target concentration A device for producing carbonated water.
The method according to claim 1,
An extraction valve having an extraction valve connected to the mixer to supply the carbonated water and to maintain an open state during the production and supply of the carbonated water; Further comprising:
4. The apparatus of claim 3,
A first inlet connected to the cold water supply path, a second inlet connected to the carbon dioxide supply path, and an outlet connected to the extraction flow path.
The method according to claim 1,
A carbonated water generation signal input unit for outputting the carbonated water generation signal according to the carbonated water generation input to the control unit; Further comprising:
[6] The apparatus of claim 5,
A plurality of carbonic acid concentration input units for generating carbonated water having different target concentrations; And a water tank.
7. The apparatus according to claim 6, wherein the plurality of carbonic acid concentration inputs include:
And the size of the target concentration set in each of the carbonic acid concentration input units can be adjusted.
8. The apparatus of claim 7,
When a signal for controlling the magnitude of the target concentration is input from the plurality of carbonic acid concentration input units,
And stores the pre-stored target power corresponding to the predetermined target concentration by changing the target power according to the adjusted target concentration.
9. The apparatus according to claim 8,
When a signal for controlling the magnitude of the target concentration is input from any one of the plurality of carbonic acid concentration input units,
And changes the target power for another carbonic acid concentration input unit by the changed value of the changed target power.

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