KR102394049B1 - Carbonatted water producing device and controlling mehtod thereof - Google Patents

Abstract

The carbonated water production apparatus according to an embodiment of the present invention is connected to the storage tank through a storage tank in which cold water is stored, a carbon dioxide cylinder in which carbon dioxide is stored, and a cold water supply path, and is connected to the carbon dioxide cylinder through a carbon dioxide supply path, and from the inside A mixer for generating carbonated water, a pump provided in the cold water supply path to supply cold water from the storage tank to the mixer, coupled to one side of the carbon dioxide cylinder, and respectively connected to the cold water supply path and the carbon dioxide supply path, A regulator capable of adjusting the supply amount of the carbon dioxide according to the pressure of the cold water, a power supply unit for applying a first voltage to the pump, a drain valve installed in a drain passage for draining the carbonated water generated in the mixer, carbonated water generated in the mixer When the extraction valve installed in the extraction flow path for extracting to the outside and the carbonated water generation signal are input, the extraction valve is opened, the drain valve is closed, and the first voltage is applied to the pump by controlling the power supply, , when the carbonated water extraction time according to the carbonated water generation signal elapses, a second voltage is applied to the pump by controlling the power supply unit for a first time from when the carbonated water extraction time has elapsed, and the carbonated water extraction time has elapsed. and a controller that closes the extraction valve when a second time elapses, and opens the drain valve when a third time elapses from when the carbonated water extraction time elapses.

Description

Carbonated water production apparatus and control method thereof

The present invention relates to an apparatus for producing carbonated water and a method for controlling the same.

Recently, water purifiers having various functions have been released so that not only a function of supplying purified water by simply filtering raw water but also a useful component to a person can be added.

As an example, a product has been released in which carbonic acid is supplied to a water purifier so that carbonated drinking water can be conveniently provided when drinking water.

This carbonated water production apparatus is generally composed of a carbon dioxide gas pressure vessel for storing initial carbon dioxide gas, and an air supply unit for supplying carbon dioxide through an orifice. Dissolve to make carbonated water.

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

That is, even if the user wants soft carbonated water or coarse carbonated water, there is a disadvantage in that carbonated water having a desired concentration cannot be provided.

In addition, since carbonated water is provided to the user in a state in which carbonated water is generated in advance and stored in a separate storage tank, there is a problem that a change in concentration may occur in the generated carbonated water.

The following Patent Document 1 relates to a carbonated water purifier, but does not provide a solution to the above-described problem.

Korean Patent Publication No. 10-2013-0044988

The present invention is to solve the problems of the prior art, and it is possible to provide carbonated water of a desired concentration to a user, to supply carbonated water of various concentrations, and to provide the carbonated water, the residual water remaining in the extraction passage. Provided are an apparatus for producing carbonated water capable of removing , and a method for controlling the same.

In addition, there is provided a carbonated water production apparatus capable of directly generating and supplying carbonated water at a user's desired time, and reducing a change in the concentration of the generated carbonated water.

The carbonated water production apparatus according to an embodiment of the present invention is connected to the storage tank through a storage tank in which cold water is stored, a carbon dioxide cylinder in which carbon dioxide is stored, a cold water supply path, and is connected to the carbon dioxide cylinder through a carbon dioxide supply path, and from the inside A mixer for generating carbonated water, a pump provided in the cold water supply path to supply cold water from the storage tank to the mixer, coupled to one side of the carbon dioxide cylinder, and connected to the cold water supply path and the carbon dioxide supply path, respectively, A regulator capable of adjusting the amount of carbon dioxide supplied according to the pressure of the cold water, a power supply unit for applying a first voltage to the pump, a drain valve installed in a drain passage for draining carbonated water generated in the mixer, carbonated water generated in the mixer When the extraction valve installed in the extraction passage for extracting to the outside and the carbonated water generation signal are input, the extraction valve is opened, the drain valve is closed, and a first voltage is applied to the pump by controlling the power supply unit, , when the carbonated water extraction time according to the carbonated water generation signal has elapsed, the power supply unit is controlled to apply a second voltage to the pump for a first time from when the carbonated water extraction time has elapsed, and the carbonated water extraction time has elapsed. and a controller that closes the extraction valve when a second time elapses, and opens the drain valve when a third time elapses from when the carbonated water extraction time elapses.

In an embodiment, the second voltage may be a maximum voltage that can be applied to the pump.

In an embodiment, the first time period may be shorter than the second time period and the third time period.

In an embodiment, the third time period may be longer than or equal to the second time period.

A method for controlling a carbonated water production apparatus according to an embodiment of the present invention includes a mixer for generating carbonated water by mixing cold water and carbon dioxide, a pump for supplying the cold water to the mixer, one end connected to a carbon dioxide cylinder, and supply to the mixer A regulator for supplying carbon dioxide to the mixer according to the pressure of the cold water being used, a drain valve installed in a drain passage for draining carbonated water generated in the mixer, and an extraction valve installed in an extraction passage for extracting carbonated water generated in the mixer to the outside A control method of a carbonated water production apparatus comprising: receiving a carbonated water generation signal; opening the extraction valve and closing the drain valve; and a first voltage applied to the pump during a carbonated water extraction time according to the carbonated water generation signal and when the carbonated water extraction time elapses, after applying a second voltage to the pump for a predetermined time, the drain valve is opened and the extraction valve is closed to remove residual water remaining in the extraction passage. may include the step of

In one embodiment, the removing of the residual water remaining in the extraction passage may include applying a second voltage to the pump for a first time from when the carbonated water extraction time elapses, and when the carbonated water extraction time has elapsed. When the second time elapses, the extraction valve may be closed, and when the third time elapses from the elapse of the carbonated water extraction time, the drain valve may be opened.

In an embodiment, the second voltage may be a maximum voltage that can be applied to the pump.

In an embodiment, the first time period may be shorter than the second time period and the third time period.

In an embodiment, the third time period may be longer than or equal to the second time period.

According to one embodiment of the present invention, carbonated water of a desired concentration can be provided by a user, carbonated water of various concentrations can be supplied, and in providing the carbonated water, by applying a second voltage to the pump after the carbonated water extraction time is over There is a technical effect that can remove the residual water remaining in the extraction passage.

In addition, carbonated water can be immediately generated and supplied at a user's desired time, and there is a technical effect of reducing a change in the concentration of the generated carbonated water.

1 is a view for explaining an apparatus for producing carbonated water according to an embodiment of the present invention.
2 is a cross-sectional view of a resistor provided in an apparatus for producing carbonated water according to an embodiment of the present invention.
FIG. 3 is a graph for explaining a control operation of the control unit of FIG. 1 .
4 is a view for explaining an apparatus for producing carbonated water according to another embodiment of the present invention.
5 is a partial cut-away view of the regulator before cold water is introduced into the regulator provided in the carbonated water production apparatus according to an embodiment of the present invention.
6 is a partial cut-away view of the regulator showing how cold water flows into the regulator provided in the carbonated water production apparatus according to an embodiment of the present invention.
7 and 8 are views showing a modified example of the regulator provided in the carbonated water production apparatus according to an embodiment of the present invention.
9 is a flowchart for explaining an embodiment of a control method of an apparatus for producing carbonated water according to an embodiment of the present invention.
10 is a flowchart for explaining an embodiment of the step of removing residual water in the extraction passage of FIG. 9 .

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

However, the embodiment of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. In addition, the embodiments of the present invention are provided in order to more completely explain the present invention to those of ordinary skill in the art.

Elements having substantially the same configuration and function in the drawings referenced in the present invention will be denoted by the same reference numerals, and shapes and sizes of elements in the drawings may be exaggerated for clearer description.

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

Referring to FIG. 1 , an apparatus for producing carbonated water 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 , and a power supply unit 80 . , a drain valve (V2), an extraction valve (V1) and a control unit 90 may be included.

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

Accordingly, the cold water stored in the storage tank 10 may be supplied to the mixer 30 through the regulator 50 by the pressure of the pump 40 .

The carbon dioxide cylinder 20 may 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 supply path L2. Accordingly, the carbon dioxide cylinder 20 may discharge the stored carbon dioxide to the mixer 30 by the regulator 50 .

The mixer 30 may receive the cold water flowing in from the storage tank 10 and the carbon dioxide discharged from the carbon dioxide cylinder 20 through the regulator 50, and mix the supplied cold water and carbon dioxide to produce carbonated water. there is.

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

Here, 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 may be discharged through the outlet 33 .

In one embodiment, the mixer 30 may include one first inlet 31 and a pair of second inlets 32 . Here, 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 surface of the mixer 30 .

Accordingly, the cold water introduced through the first inlet 31 and the carbon dioxide introduced through the second inlet 32 may cross each other inside the mixer 30, so that the cold water and carbon dioxide are mixed with each other. Carbonated water may be produced.

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

An extraction passage L3 equipped with an extraction valve V1 and a drain passage L4 equipped with a drain valve V2 may be respectively connected to the outlet 33 .

The carbonated water extracted through the extraction passage L3 may be supplied to the user through the carbonated water extraction pipe 70 , and a resistor 60 may be provided between the extraction valve V1 and the carbonated water extraction pipe 70 . Here, the resistor 60 may maintain a predetermined pressure inside the mixer 30 and the extraction passage L3. The resistor 60 will be described in more detail below with reference to FIG. 2 .

The pump 40 may be disposed between the storage tank 10 and the regulator 50 . A constant voltage may be applied to the pump 40 from the power supply unit 80 , and the cold water stored in the storage tank 10 may be pumped by the voltage to be introduced into the mixer 40 through the regulator 50 .

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

In other words, by adjusting the pressure of the cold water passing through the regulator 50 , it is possible to control the amount of carbon dioxide discharged to the mixer 30 through the regulator 50 .

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

The power supply unit 80 may apply a constant voltage to the pump 40 under the control of the control unit 90 . Here, the voltage may be varied under the control of the controller 90 .

The drain valve V2 may be installed in the drain passage L4 , and opening and closing may be controlled by the controller 90 .

The extraction valve V1 may be installed in the extraction passage L3, and opening and closing may be controlled by the control unit 90 .

The controller 90 may control the overall operation of the carbonated water production apparatus.

Specifically, first, when a carbonated water generation signal is input, the control unit 90 may open the extraction valve V1 and close the drain valve V2, and control the power supply unit 80 to supply the pump 40 to the pump 40 . A first voltage V ₁ may be applied. Here, the carbonated water generation signal may include information on the carbonated water extraction time.

When the carbonated water extraction time elapses, the controller 90 may apply a second voltage V ₂ to the pump 40 .

Here, the first voltage (V ₁ ) corresponds to the voltage supplied to the pump 40 to extract carbonated water, and the second voltage (V ₂ ) is a pump ( 40) corresponds to the voltage supplied to

In one embodiment, the second voltage (V ₂ ) may be the maximum voltage that the power supply unit 80 can apply to the pump 40 . The controller 90 may apply the second voltage V ₂ to the pump 40 for a preset time.

Here, when the first voltage (V ₁ ) is the maximum voltage, the control unit 90 maintains the first voltage (V ₁ ) for the preset time even when the carbonated water extraction time elapses, thereby maintaining the second voltage ( V ₂ ) can be substituted for the operation of supplying.

Also, after the preset time has elapsed, the control unit 90 may close the extraction valve V1 and open the drain valve V2 to end the carbonated water generation and extraction operation.

In one embodiment, the control unit 50 may include at least one processing unit and a memory. Here, the processing unit may include, for example, a central processing unit (CPU), a graphic processing unit (GPU), a microprocessor, an Application Specific Integrated Circuit (ASIC), Field Programmable Gate Arrays (FPGA), and the like, It may have a plurality of cores. The memory 1120 may be a volatile memory (eg, RAM, etc.), a non-volatile memory (eg, ROM, flash memory, etc.), or a combination thereof.

In such a carbonated water production apparatus, the cold water and carbon dioxide supplied to the inside of the mixer 30 are mixed while continuously flowing to produce carbonated water, and the produced carbonated water is not stored in the carbonated water production apparatus, but immediately supplied to the user. there is.

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

In the case of a method in which carbonated water is generated in advance, stored in a separate storage space in the device, and later supplied to the user, a predetermined time elapses while the carbonated water is stored. It becomes difficult to supply. In addition, there is also a problem in that carbonated water having a different concentration is supplied every time carbonated water is extracted.

However, since the carbonated water production apparatus according to an embodiment of the present invention generates carbonated water at a user's desired time and directly supplies the carbonated water to the user, carbonated water of a certain concentration can be supplied to the user without changing the concentration.

2 is a cross-sectional view of a resistor provided in an apparatus for producing carbonated water according to an embodiment of the present invention.

A process of maintaining a predetermined pressure in the mixer 30 and the extraction passage L3 by the resistor 60 will be described with reference to FIG. 2 .

The carbonated water generated in the mixer 30 may be supplied to the user through the carbonated water extraction pipe 70 through the extraction passage L3.

At this time, a predetermined pressure is required to generate carbonated water by mixing carbon dioxide and cold water flowing into the mixer 30 . However, in the case of a direct-type carbonated water production apparatus that generates and provides carbonated water directly, it is difficult to form a necessary pressure in the mixer 30 because the extraction valve V1 is open.

In order to solve such a problem, the carbonated water production apparatus according to an embodiment of the present invention may further include a resistor 60 capable of maintaining a predetermined pressure in the mixer 30 and the extraction passage L3.

The resistor 60 may be installed in the extraction passage L3.

The resistor 60 is provided in the hollow cone-shaped cone 61, the carbonated water inlet 62 connected to the extraction passage L3 and provided on the side of the cone 61, and the side of the cone 61, so that the carbonated water extraction pipe ( 70) and connected to the carbonated water outlet 63, and may further include a bushing member 64 that is inserted into the cone 61 to change the size of the flow path through which the carbonated water flows.

Specifically, the cone 61 may be formed such that the outer and inner diameters increase from the carbonated water inlet 62 toward the carbonated water outlet 63 .

The bushing member 64 may also be formed such that its diameter increases from the carbonated water inlet 62 toward the carbonated water outlet 63, and the inner circumferential surface of the cone 61 and the outer circumferential surface of the bushing member 64 may be disposed parallel to each other. .

Accordingly, a flow path through which carbonated water flows is formed between the inner circumferential surface of the cone 61 and the outer circumferential surface of the bushing member 64 .

At this time, since the bushing member 64 is screw-coupled to the cone 61, the distance between the inner circumferential surface of the cone 61 and the outer circumferential surface of the bushing member 64 can be adjusted according to the amount of tightening the bushing member 64. Accordingly, the size of the flow path through which the carbonated water flows may be adjusted.

Therefore, by forming the gap between the inner peripheral surface of the cone 61 and the outer peripheral surface of the bushing member 64 to be smaller than the diameters of the carbonated water inlet 62 and the carbonated water outlet 63, the flow of carbonated water can be hindered, and accordingly, the mixer ( 30) and the pressure in the extraction passage L3 may be maintained at a predetermined pressure.

FIG. 3 is a graph for explaining a control operation of the control unit of FIG. 1 .

Referring to FIG. 3 , when the carbonated water generation signal t _i is input, the control unit 90 controls the power supply unit 80 to apply a first voltage V ₁ to the pump 40 , and the extraction valve V1 ) can be opened, and the discharge valve (V2) can be closed.

Here, when the first voltage V ₁ is applied to the pump 40 and the extraction valve V1 is closed immediately and the discharge valve V2 is opened, the extraction valve V1 and the carbonated water extraction pipe 70 Residual water may remain in between, and after the carbonated water extraction operation is completed, such residual water may flow into the carbonated water extraction pipe 70 to cause dripping water.

In order to solve this problem, in the carbonated water production apparatus according to an embodiment of the present invention, when the carbonated water extraction time t _f elapses, the controller 90 controls the power supply unit 80 to change the carbonated water extraction time t _f . For the first time (t ₁ ), the second voltage (V ₂ ) is applied to the pump ( 40 ), and when the second time ( t ₂ ) has elapsed from when the carbonated water generation signal ( t _i ) is input, the extraction valve ( V1) is closed, and when the third time (t ₃ ) has elapsed from the time when the carbonated water generation signal (t _i ) is input, the discharge valve (V2) is opened, so that the extraction valve (V1) and the carbonated water extraction pipe (70) Residual water remaining in between can be removed.

Here, after the residual water is discharged to the carbonated water extraction pipe 70 by the pressure of the pump 40 by the second voltage V ₂ , the extraction valve V1 is closed and the drain valve V2 is opened. 1 time t ₁ may be shorter than the second time t ₂ and the third time t ₃ .

Also, in order to prevent the residual water from being discharged through the drain valve V2, the third time period t ₃ may be longer than or equal to the second time period t ₂ .

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

Referring to FIG. 4 , first, when a carbonated water generation signal is input, the control unit 90 applies a first voltage V ₁ to the pump 40 , opens the extraction valve V1, and closes the discharge valve V2. can be closed When a first voltage V ₁ is applied to the pump 40, the pump 40 may pump the cold water stored in the storage tank 10 at a pressure corresponding to the first voltage V ₁ , and the pump ( The cold water pumped by 40 may be supplied 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 may mix the cold water and carbon dioxide supplied through the regulator 50 to generate carbonated water and discharge it to the outside through the carbonated water extraction pipe 70 .

When the carbonated water extraction time is over, the control unit 90 applies the second voltage V ₂ to the pump 40 to discharge the residual water remaining in the extraction passage L3 through the carbonated water extraction pipe 70 to the outside. , by closing the extraction valve (V1) and opening the drain valve (V2), it is possible to end the carbonated water extraction operation.

5 is a partial cutaway view of the regulator before cold water is introduced into the regulator provided in the carbonated water production apparatus according to an embodiment of the present invention, and FIG. 6 is a carbonated water production apparatus according to an embodiment of the present invention. It is a partial cutaway view of the regulator showing how cold water flows into the provided regulator.

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

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

The regulator 50 may be coupled to one side of the carbon dioxide cylinder 20 to control the amount of carbon dioxide supplied from the carbon dioxide cylinder 20 to the mixer 30 .

The regulator 50 is provided on the lower side of the main body 51 having an internal space, the cold water inlet 52 and the cold water outlet 53 and the cold water outlet 53 provided on the side part of the main body 51 to communicate with the inner space. and may include a carbon dioxide supply port 54 connected to the carbon dioxide cylinder 20 .

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

A pin 55 for opening or closing the carbon dioxide cylinder 20 is disposed in the inner space of the body 51 , and the pin 55 may be elastically connected to the carbon dioxide cylinder 20 .

Accordingly, when an external force is applied to the pin 55 , the pin 55 is pressed, and accordingly, the carbon dioxide cylinder 20 is opened and carbon dioxide is supplied through the carbon dioxide supply port 54 , and the carbon dioxide is the carbon dioxide supply port. It is supplied to the mixer 30 through the carbon dioxide supply path (L2) connected to (54).

When the external force applied to the pin 55 is removed, the carbon dioxide cylinder 20 is sealed, and thus the supply of carbon dioxide is stopped.

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

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

A sealing member is provided between the outer surface of the plunger 56 and the inner surface of the body 51 to seal the upper and lower sides of the plunger 56, and a pin 55 is disposed on the lower side of the plunger 56 can be

When no external force (that is, the pressure of cold water flowing in the inner space of the body 51) is applied to the plunger 56, no force is applied to the pin 55, so the carbon dioxide cylinder 20 is sealed. can keep

However, when cold water flows into the inner space of the body 51 , the plunger 56 is pressed toward the pin 55 according to the pressure of the cold water, and accordingly, the carbon dioxide cylinder 20 is opened and the carbon dioxide supply port 54 ) through which carbon dioxide is supplied.

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

That is, when the pressure of the cold water is relatively large, the plunger 56 presses the pin 55 relatively strongly, and accordingly, the amount of carbon dioxide supplied to the mixer 30 increases.

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

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

In addition, since the pressure of the cold water is affected by the magnitude of the voltage applied to the pump 40 , the amount of carbon dioxide supplied may be adjusted according to the magnitude of the voltage applied to the pump 40 .

Accordingly, by adjusting the magnitude of the voltage applied to the pump 40 , carbonated water of various concentrations desired by the user (eg, high concentration, medium concentration and low concentration) can be supplied.

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

In a modified embodiment of the regulator 50, except for the elastic member 57 that elastically supports the plunger 56, it is the same as the regulator 50 described with reference to FIGS. 5 and 6, so the description other than the elastic member 57 should be omitted.

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

A pin 55 may be disposed below the plunger 56 , and the plunger 56 may be elastically supported upward by the elastic member 57 in the inner space of the body 51 .

Therefore, when no external force (that is, the pressure of cold water flowing in the inner space of the body 51) is applied to the plunger 56, the plunger 56 is elastically supported by the elastic member 57, so the plunger ( 56) and the pin 55 are kept spaced apart, and the inner space of the body 51 is formed to be relatively narrow.

However, when cold water flows into the inner space of the main body 51, the plunger 56 is pressed toward the pin 55 according to the pressure of the cold water (therefore, the inner space of the main body 51 becomes relatively large) ), thus the carbon dioxide cylinder 20 is opened to supply carbon dioxide through the carbon dioxide supply port 54 .

Hereinafter, a method of controlling the carbonated water production apparatus according to an embodiment of the present invention will be described with reference to FIGS. 7 and 8 .

However, since the control method of the carbonated water production apparatus described below is performed in the carbonated water production apparatus described above with reference to FIGS. 1 to 6 , the same content as or corresponding to the above description will not be redundantly described.

9 is a flowchart for explaining an embodiment of a control method of an apparatus for producing carbonated water according to an embodiment of the present invention.

Referring to FIG. 9 , in the control method of the carbonated water production apparatus according to an embodiment of the present invention, first, the controller 90 may receive a carbonated water generation signal ( S100 ).

Next, the controller 90 may control the extraction valve V1 and the drain valve V2 to open the extraction valve V1 and close the drain valve V2 (S200).

Next, the control unit 90 may control the power supply unit 80 to apply the first voltage V ₁ to the pump 40 during the carbonated water extraction time according to the carbonated water generation signal (S300). Here, steps S200 and S300 may be performed simultaneously.

Next, when the carbonated water extraction time elapses (S400), the control unit 90 controls the power supply unit 80 to apply the second voltage V ₂ to the pump 40 for a predetermined time, and then the extraction valve V1 ) is closed, and the drain valve V2 is opened to discharge the residual water remaining in the extraction passage L3 through the carbonated water extraction pipe 70 (S500).

10 is a flowchart for explaining an embodiment of the step of removing residual water in the extraction passage of FIG. 9 .

Referring to FIG. 10 , in the step S500 of removing the residual water remaining in the extraction passage L3, when the carbonated water extraction time t _f elapses (S400), the control unit 90 controls the power supply unit 80 to apply the second voltage V ₂ to the pump 40 for the first time t ₁ from the carbonated water extraction time t _f (S510, S520), and from when the carbonated water generation signal t _i is input When the second time (t ₂ ) has elapsed (S530), the extraction valve (V1) is closed (S540), and when the third time (t ₃ ) has elapsed from when the carbonated water generation signal (t _i ) is input (S550) ), it is possible to open the discharge valve (V2) (S560).

Here, after the residual water is discharged to the carbonated water extraction pipe 70 by the pressure of the pump 40 by the second voltage V ₂ , the extraction valve V1 is closed and the drain valve V2 is opened. 1 time t ₁ may be shorter than the second time t ₂ and the third time t ₃ .

Also, in order to prevent the residual water from being discharged through the drain valve V2, the third time period t ₃ may be longer than or equal to the second time period t ₂ .

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, but is limited by the claims described below, and the configuration of the present invention may vary within the scope without departing from the technical spirit of the present invention. Those of ordinary skill in the art to which the present invention pertains can easily recognize that it can be changed and modified.

10: storage tank
20: carbon dioxide cylinder
30: mixer
40: pump
50: regulator
60: resistor
70: carbonated water extraction tube
80: power supply
90: control unit

Claims (11)

storage tanks in which cold water is stored;
a carbon dioxide cylinder in which carbon dioxide is stored;
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 the cold water from the storage tank to the mixer;
a regulator coupled to one side of the carbon dioxide cylinder, connected to the cold water supply path and the carbon dioxide supply path, respectively, and capable of adjusting the supply amount of the carbon dioxide according to the pressure of the cold water;
a power supply for applying a first voltage to the pump;
a drain valve installed in a drain passage for draining the carbonated water generated in the mixer;
an extraction valve installed in the extraction passage for extracting the carbonated water generated in the mixer to the outside; and
When the carbonated water generation signal is input, the extraction valve is opened, the drain valve is closed, the power supply unit is controlled to apply a first voltage to the pump, and when the carbonated water extraction time according to the carbonated water generation signal elapses , a second voltage is applied to the pump by controlling the power supply unit for a first time from when the carbonated water extraction time elapses, and when a second time elapses from when the carbonated water extraction time elapses, the extraction valve is closed a control unit that closes and opens the drain valve when a third time elapses from when the carbonated water extraction time elapses; A carbonated water production apparatus comprising a.
According to claim 1, wherein the second voltage,
A carbonated water production apparatus that is the maximum voltage that can be applied to the pump.
According to claim 1, wherein the first time,
The carbonated water production apparatus shorter than the second time and the third time.
According to claim 1, wherein the third time period,
The carbonated water production apparatus longer than or equal to the second time period.
According to claim 1, wherein the mixer,
and 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.
According to claim 1,
The apparatus for producing carbonated water is provided with a resistor capable of maintaining the pressure in the mixer and the extraction passage at a predetermined pressure in the extraction passage.
A mixer for mixing cold water and carbon dioxide to produce carbonated water, a pump for supplying the cold water to the mixer, a regulator connected to a carbon dioxide cylinder on one side and supplying carbon dioxide to the mixer according to the pressure of the cold water supplied to the mixer, the A method for controlling a carbonated water production apparatus comprising: a drain valve installed in a drain passage for draining carbonated water generated in a mixer; and an extraction valve installed in an extraction passage for extracting carbonated water generated in the mixer to the outside;
receiving a carbonated water generation signal;
opening the extraction valve and closing the drain valve;
applying a first voltage to the pump during a carbonated water extraction time according to the carbonated water generation signal; and
When the carbonated water extraction time elapses, applying a second voltage to the pump for a predetermined time, opening the drain valve, and closing the extraction valve to remove residual water remaining in the extraction passage; includes A method of controlling a carbonated water production apparatus.
According to claim 7, wherein the step of removing the residual water remaining in the extraction passage,
A second voltage is applied to the pump for a first time from when the carbonated water extraction time elapses, and when a second time elapses from when the carbonated water extraction time elapses, the extraction valve is closed, and the carbonated water extraction time When a third time elapses from the elapsed time, the control method of the carbonated water production apparatus opens the drain valve.
The method of claim 8, wherein the second voltage is
A method of controlling a carbonated water production apparatus that is the maximum voltage that can be applied to the pump.
The method of claim 8, wherein the first time is,
A method of controlling the carbonated water production apparatus shorter than the second time and the third time.
According to claim 8, wherein the third time period,
A method of controlling the carbonated water production apparatus longer than or equal to the second time period.

Images