KR20140040395A - Refrigerator and controlling method for the same - Google Patents

Abstract

The present invention relates to a refrigerator and a method for controlling the same. The present invention includes: a first step for closing a feed valve on an outlet for opening and closing the flow path of water transferred to an ice machine or a dispenser; a second step for closing a first feed valve for opening and closing the flow path of water flowing in from an external water source, after a predetermined time elapses; a third step for determining the amount of transferred water, using a flux sensor, for a predetermined time; and a fourth step for notifying a user of a water leakage when the transferred amount of water for the designated time is larger than a preset value. [Reference numerals] (AA) Start; (BB,CC) Yes; (S12) Closing a second feed valve; (S20) After a predetermined time; (S30) Closing a first feed valve; (S40) Predetermined flux detected in a flux sensor > Preset value; (S50) Notify to users

Description

Refrigerator and Controlling Method {Refrigerator and Controlling Method for the same}

The present invention relates to a refrigerator and a control method thereof, and more particularly, to a refrigerator and a control method thereof capable of detecting whether water supplied through a dispenser or an ice maker is leaked from an external water supply.

The refrigerator is for refrigerating and freezing storage of the stored matter, and a compressor, a condenser, an evaporator, and an expansion device are provided in the main body of the refrigerator for its operation.

In addition, the inside of the main body of the refrigerator is provided with a refrigerating chamber for refrigeration storage, and a freezing chamber for freezing storage, the evaporator serves to inject cold air into the refrigerating chamber and the freezing chamber.

Front doors of the refrigerating compartment and the freezing compartment are mounted, and the door or the refrigerating compartment / freezer is equipped with an ice maker for providing ice and a dispenser for water supply.

The main body and the door are provided with a water supply pipe for guiding water to the ice maker and the dispenser, and the water moves along the water supply pipe to reach the ice maker or the dispenser for the manufacture of ice and the extraction of drinking water.

Since various components are placed while the water reaches the dispenser or ice maker, there is a problem in that components leak. Since the refrigerator is supplied with electricity, various problems such as an electric shock or a fire caused by a short circuit may occur when a leak occurs.

Therefore, research has been conducted on a technique for quickly detecting leaks when leaks occur.

The present invention is to solve the above problems, the present invention is to provide a refrigerator and a control method that can detect whether or not the water is generated while the water supplied from the external water source is moved inside the refrigerator.

Another object of the present invention is to provide a refrigerator and a method of controlling the same, in which a leak can be quickly notified to a user when a leak occurs inside the refrigerator.

In addition, the present invention provides a refrigerator and a control method thereof capable of determining whether a leak occurs at a flow path supplied to a dispenser or a flow path supplied to an ice maker.

In order to achieve the above object, the present invention provides a first water supply valve for opening and closing the flow path of water flowing into the refrigerator from the external water supply; An outlet side water supply valve for opening and closing a flow path of water moved to an ice maker or a dispenser; A flow rate sensor disposed between the first water supply valve and the outlet side water supply valve to measure a flow rate of the moved water; And a control unit configured to close the outlet water supply valve according to a predetermined period or a user's instruction, close the first water supply valve after a predetermined time has elapsed, and receive a signal regarding the amount of water moved through the flow sensor for a predetermined time. And the control unit closes the first water supply valve by determining that a leak occurs when the amount of water moved by the flow sensor exceeds a set amount.

In particular, the outlet side water supply valve may include a second water supply valve for opening and closing a flow path for supplying water to the ice maker, and a third water supply valve for opening and closing a flow path for supplying water to the dispenser.

The controller may control the second water supply valve and the third water supply valve to be closed with a time difference.

Alternatively, the control unit may adjust to close the second water supply valve and the third water supply valve at the same time.

And if the amount of water moved by the flow sensor exceeds the set amount, it is possible to further include a display unit for showing information about the leak on the screen.

On the other hand, if the amount of water moved by the flow sensor exceeds a set amount, it may further include an alarm unit for notifying the leak by sound.

A flow path control valve may be provided between the first water supply valve and the outlet water supply valve to selectively or simultaneously guide water in the direction of the ice maker and the dispenser.

In another aspect, the present invention comprises a first step of closing the outlet side water supply valve for opening and closing the flow path of water moved to the ice maker or the dispenser; A second step of closing a first water supply valve for opening and closing a flow path of water flowing from an external water supply source after a predetermined time elapses; Determining a flow rate of the water moved by the flow sensor; And a fourth step of notifying the user of leakage when the flow rate of the moved water is greater than the set value.

On the other hand, the outlet side water supply valve includes a second water supply valve for opening and closing the flow path for supplying water to the ice maker, and a third water supply valve for opening and closing the flow path for supplying water to the dispenser, in the first step, It is possible to close at least one of the second feed valve or the third feed valve.

In the first step, one of the second water supply valve and the third water supply valve may be closed, and the other may be closed.

Meanwhile, in the first step, the second water supply valve and the third water supply valve may be closed at the same time.

In the fourth step, the user may be notified of the leak using the screen of the display unit, or in the fourth step, the user may be notified of the leak using the sound of the alarm unit.

According to the present invention, it is possible to detect whether water is generated while the water supplied from the external water source is moved inside the refrigerator.

In addition, according to the present invention, it is possible to determine whether the location of the leakage occurring inside the refrigerator is a flow path supplied to the dispenser or a flow path supplied to the ice maker.

In addition, according to the present invention, because the user can quickly recognize whether or not the leakage occurs, it is possible to quickly cope with the leakage occurs.

Since the leak can be determined whenever water is supplied from an external water supply, the leak can be frequently judged, so that the risk of leakage can be easily detected.

1 is a perspective view of a refrigerator according to the present invention;
2 is a front view of the refrigerator according to the present invention;
3 is a structural diagram of a flow sensor according to the present invention;
4 is a block diagram according to the present invention.
5 is a control flowchart for detecting leakage of water supplied to an ice maker.
6 is a control flowchart for detecting leakage of water supplied to the dispenser.
7 is a control flowchart of detecting leakage of water inside a refrigerator.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

1, the refrigerator according to the present invention includes a main body 1, a storage room 3 provided in the main body 1, and a door 5 for opening and closing the storage room.

The door 5 is rotatably disposed in the main body 1, an ice making chamber 23 in which ice is iced and stored in the door 5, and a dispenser in which water is extracted (see FIG. 2 and 40). Is installed.

The ice making chamber 23 is provided with an ice maker 26 for ice making ice and an ice storage box 29 for storing the iced ice from the ice maker.

A water tank 13 for storing the water to be supplied to the dispenser 40 is provided under the ice making chamber 23. One side of the water tank 13 is provided with a flow path control valve 33 for selectively or simultaneously guiding water toward the dispenser 40 and the ice maker 26.

The flow path control valve 33 may include a three-way valve, and one discharge part may be connected to the water tank 13, and the other discharge part may be connected to the ice maker 26. In this case, the flow path control valve 33 may supply water to the water tank 13 and the ice maker 26 selectively or simultaneously.

In addition, a flow rate sensor 100 capable of calculating a flow rate of water is provided at an inlet side of the flow path control valve 33. The flow rate sensor 100 measures the flow rate of the water supplied to the ice maker 26 or the dispenser 40 when the flow control valve 33 guides the water to the ice maker 26 or the dispenser 40. It is a device to measure.

The flow sensor 100 is mounted to the water supply hose 57, the water supply hose 57 is connected to the external water supply source 10, between the flow sensor 100 and the external water supply source 10 A primary water supply valve 16 and a filter 19 for filtering water are provided.

The first water supply valve 16 opens and closes a flow path through which water is introduced into the refrigerator from the external water supply source 10. That is, when the first water supply valve 16 opens the flow path, water may flow into the refrigerator from the external water supply source 10, and when the first water supply valve 16 closes the flow path, the external water supply source ( 10) Water cannot flow into the refrigerator.

An outlet water valve for opening and closing a flow path of water to be moved to the ice maker 26 or the dispenser 40 may be provided. At this time, the outlet-side water supply valve includes a second water supply valve (70) and a third water supply valve (80) to be described below.

Here, the water supply hose 57 is disposed along one side of the main body 1 and penetrates through the hinge device 60 connecting the door 5 and the main body 1 to the side along the side of the door 5. It is connected to the flow sensor 100 and the flow control valve 33.

In addition, a first connection hose 55 connected to one discharge part of the flow path control valve 33 is connected to the water tank 33 and the dispenser (see FIGS. 2 and 40). At this time, the first connection hose (55) is provided with a third water supply valve (80) for opening and closing the water flow path to be moved to the dispenser (40). When the third water supply valve 80 opens the flow path, water can be supplied to the dispenser 40 through the first connection hose 55.

In addition, the second connection hose 56 connected to the other discharge part of the flow path control valve 33 is disposed to rise along one side of the door 5 and transfers water to the ice making tray 27. Is placed. At this time, the second connection hose (56) is provided with a second water supply valve (70) for opening and closing the flow channel of water to be moved to the ice maker (26). When the second water supply valve 70 opens the flow path, water can be supplied to the ice maker 26 through the second connection hose 56.

Here, the space inside the ice-making chamber 23 is closed by an ice-making chamber door (not shown) rotatably provided on one side wall of the ice-making chamber 23, thereby being partitioned from the inside of the storage chamber 3 .

As shown in FIG. 2, the dispenser 40 is mounted on the front of the door 5, and the water tank 13, the flow path control valve 33, and the flow rate are provided on the rear of the door 5. The sensor 100 is provided.

As described above, when the user presses the water intake lever 42 of the dispenser 40, the first water supply valve 16 opens the flow path and flows into the refrigerator. After passing through the flow path control valve 33 and the water tank 13, the water flow is moved to the first connection hose 55 provided above the water intake lever 42, and the third water supply valve 80 opens the flow path. It is opened and discharged through the dispenser 40 to be contained in a container such as a cup.

On the other hand, the second connection hose 56 branched from the flow path control valve 33 to the ice maker 26 is disposed along the side wall of the door 5, the outlet portion of the second connection hose 56 It is disposed toward the ice tray 27 of the ice maker 26.

In this arrangement, the water flowing into the ice maker 26 is introduced into the refrigerator by opening the flow path of the first water supply valve 16. Then, the second water supply valve 70 opens the flow path and falls to the ice making tray 27 while passing through the flow path control valve 33 and passing through the second connection hose 56. ) Is accepted inside.

When water is supplied in the direction of the ice making tray 27, the flow rate sensor 100 is used to measure the amount of water supplied and to determine whether a proper amount is supplied.

Meanwhile, even when water is supplied to the dispenser 40, since the water passes through the flow sensor 100, the amount of water moved by the flow sensor 100 may be measured.

The front of the refrigerator may be provided with a display unit 200 that can provide a user with a variety of information on the screen. In this case, the display 200 may provide information to the user through a text or a picture to the user through a screen.

In addition, the front of the refrigerator may be provided with an alarm unit 210 that can provide information to the user by sound. In this case, the alarm unit 210 may be configured together with the display unit 200, and may be provided at the rear of the display unit 200 to provide information to the user using various types of sounds.

As shown in FIG. 3, the flow sensor 100 includes a body part 110 having a space 105 through which water flows and flows therein, and is rotatably provided in the space 105. An impeller 120 including two blades 122, a signal generator 130 provided at an end of one of the blades 122, and an inner wall of the space 105. It includes a signal detector 140 for detecting a signal generated by the generator 130.

Here, the signal generator 130 is preferably composed of a magnet, the signal detector 140 is preferably composed of a Hall sensor for sensing the magnetism of the magnet.

The body portion 110 includes an inlet portion 111 through which water is introduced and an outlet portion 112 through which the water flows out, and the outlet portion 112 is provided at an upper portion of the body portion 110 to control the flow path. It is preferably arranged to face the bottom of the valve 33.

The reason for arranging the outlet 112 as described above is to prevent bubbles from being generated when water is discharged from the outlet 112.

Under such a configuration, when water flows into the inlet 111, the flow of water flows out of the outlet 112 after rotating the impeller 120. In this case, when the impeller 120 rotates, the signal generator mounted at the end of the blade 122 also rotates along the blade 122.

Accordingly, when the end of the blade on which the signal generator 130 is mounted faces the signal detector 140, the signal detector 140 detects the presence of the signal generator 130.

After that, when the impeller 120 rotates once and the end of the blade on which the signal generator 130 is mounted again faces the signal detector 140, the signal detector 140 is the signal generator. The presence of 130 is detected again.

As a result, the control unit (FIGS. 4 and 150) to which the signal detection unit 140 is connected recognizes that the impeller 120 has rotated once.

In this case, multiplying the flow rate of the water of the predetermined amount causing the rotation of the impeller by the rotational speed of the impeller 120, it is possible to calculate the flow rate of the water flowing into the ice maker 26 or the dispenser 40.

Referring to FIG. 4, the controller 150 according to the present invention may receive a signal regarding the amount of water moved by the flow sensor 100. Therefore, it is possible to adjust the amount of water moved so that an appropriate amount of water can be supplied to the ice maker 26.

The controller 150 may control the opening and closing of the first water supply valve 16, the second water supply valve 70, and the third water supply valve 80.

For example, when a signal for supplying water to the ice maker 26 is generated, water may be supplied by opening a flow path between the first water supply valve 16 and the second water supply valve 70. When the water is sufficiently supplied to the ice maker 26, both the first water supply valve 16 and the second water supply valve 70 are closed.

In this case, the controller 150 may close the second water supply valve 70 and close the first water supply valve 16 after a predetermined time elapses. That is, instead of closing the second water feed valve 70 and the first water feed valve 16 simultaneously, the second water feed valve 70 and the first water feed valve 16 are sequentially closed. This is because water leakage can be detected by closing the water supply valves sequentially.

On the other hand, the leak detection by the controller 150 may be made according to an instruction or a certain period by the user. That is, it is possible to set a cycle at which a user detects a leak in the refrigerator at a specific moment, or the manufacturer of the refrigerator initially detects a leak in the refrigerator without a user's instruction.

In particular, the controller 150 may control the first water supply valve 16 not to open when a leak in the refrigerator is detected. If it is determined that a leak occurs in the refrigerator, the leak occurs when the first water supply valve 16 is opened.

On the other hand, when a signal for supplying water to the dispenser 40 is generated, water may be supplied by opening the flow path between the first water supply valve 16 and the third water supply valve 80. When the water is sufficiently supplied to the dispenser 40, both the first water supply valve 16 and the third water supply valve 80 are closed.

In this case, the controller 150 may close the third water supply valve 80 and close the first water supply valve 16 after a predetermined time elapses. That is, instead of closing the third water supply valve 80 and the first water supply valve 16 simultaneously, the third water supply valve 80 and the first water supply valve 16 are sequentially closed. This is because water leakage can be detected by closing the water supply valves sequentially.

Meanwhile, the controller 150 may simultaneously close the second water supply valve 70 and the third water supply valve 80. When water needs to be simultaneously supplied to the dispenser 40 and the ice maker 26, the second water supply valve 70 and the third water supply valve 80 may be opened together. When sufficient water is supplied to both the dispenser 40 and the ice maker 26, the second water supply valve 70 and the water supply unit may be used to stop the water supplied to the dispenser 40 and the ice maker 26 simultaneously. The third water supply valve 80 is closed at the same time. In this case, the controller 150 may close the second water supply valve 70 and the third water supply valve 80 and close the first water supply valve 16 after a predetermined time has elapsed.

The controller 150 may adjust the second water supply valve 70 and the third water supply valve 80 to have a time difference. When water needs to be simultaneously supplied to the dispenser 40 and the ice maker 26, the second water supply valve 70 and the third water supply valve 80 may be opened together.

However, when water is sufficiently supplied to the dispenser 40 first, the second water supply valve 70 is closed first, and water is continuously supplied to the ice maker 26 so that the water is supplied to the ice maker 26. The third water supply valve 80 may be closed.

On the other hand, if water is sufficiently supplied to the ice maker 26 first, the third water supply valve 80 is first closed, and water is continuously supplied to the dispenser 40 to supply the water to the dispenser 40. The secondary water supply valve 70 can be closed.

However, in both cases described above, it is preferable that the first water supply valve 16 is closed last compared to the second water supply valve 70 and the third water supply valve 80.

The controller 150 may transmit a signal regarding various information generated in the refrigerator to the display unit 200 or the alarm unit 210 so that the corresponding information may be delivered to the user. In particular, when it is determined that a leak occurs in the refrigerator based on the information measured by the flow sensor 100, the controller 150 transmits the information regarding the leak to the user through the display unit 200 or the alarm unit 210. Can be forwarded to

Hereinafter, the control flow of the refrigerator according to the present invention will be described.

A process of detecting leakage of water supplied to the ice maker will be described with reference to FIG. 5.

When a signal indicating that water needs to be supplied to the ice maker 26 is generated, the second water supply valve 70 and the first water supply valve 16 are opened so that water from the external water supply source 10 is supplied to the first water supply. Passes through the valve 16, the filter 19, the water supply hose 57, the flow sensor 100. In this case, since the water is not supplied to the dispenser 40, the third water supply valve 80 maintains the closed flow path.

In addition, the flow path of the water from the flow path control valve 33 is guided to the ice maker 26, and passes through the second connection hose 56, and water may be supplied through the second water supply valve 70.

When sufficient water is supplied to the ice maker 26, the second water supply valve 70 is closed (S12).

Then, it is determined whether a predetermined time has elapsed (S20). In this case, the predetermined time may be about 10 seconds.

When a predetermined time elapses, the first water feed valve 16 is closed (S30). That is, instead of closing the second water feed valve 70 and the first water feed valve 16 simultaneously, the second water feed valve 70 and the first water feed valve 16 are sequentially closed.

At this time, the flow rate sensor 100 detects a predetermined flow rate moved through the flow sensor 100 (S40). Since the flow rate sensor 100 is disposed in a section through which water passes between the second water supply valve 70 and the first water supply valve 16, the flow rate sensor even though the second water supply valve 70 is closed. Through 100, it may be detected whether water is continuously supplied.

When the predetermined flow rate detected by the flow sensor 100 exceeds a set value, it is determined that a leak occurs in the flow path of water supplied to the second water feed valve 70, and the display unit 200 displays information about the leak. ) Or the alarm unit 210 (S50). Therefore, the user can cope with the leakage by the information accordingly.

In particular, in this case, the display unit 200 or the alarm unit 210 preferably informs the user of specific information that a leak occurred in the flow path supplied from the external water supply source 10 to the ice maker 26.

On the other hand, when the predetermined flow rate detected by the flow sensor 100 is less than the set value, it is determined that no leakage occurs in the flow path of the water supplied to the second water feed valve 70.

At this time, the set value for the predetermined flow rate may be set by the user or a manufacturer manufacturing the refrigerator. For example, the set value may adopt a relatively small value if you want to manage the leak more strictly, and may adopt a relatively large value if you want to manage loosely without frequent repairs.

On the other hand, since the water supplied from the external water supply source 10 may have a water pressure varying within a predetermined range, even if the second water supply valve 70 is closed, the water is instantaneously or temporarily, but the first water supply valve 16 is closed. Can be fed through). In addition, even if no leakage occurs due to various factors such as air that may be included in the flow path, the water may be moved by the range below the set value through the flow sensor 100.

The flow rate sensor 100 is a rear end of the flow rate sensor 100, that is, a flow path from the flow rate sensor 100 to the ice maker 26, that is, the flow path control valve 33 and the second connection hose 56. And leaks from the second water supply valve 70 may be accurately detected. This is because the flow rate sensor 100 may measure the amount of water discharged to the outlet of the flow rate sensor 100.

On the other hand, if the position of the flow sensor 100 is disposed between the first water supply valve 16 and the filter 19, the filter in the section that can accurately measure the leakage by the flow sensor 100 (19) may also be included.

A process of detecting leakage of water supplied to the dispenser will be described with reference to FIG. 6.

When a signal indicating that water needs to be supplied to the dispenser 40 is generated, the third water supply valve 80 and the first water supply valve 16 are opened so that water from the external water supply source 10 is supplied to the first water supply. Passes through the valve 16, the filter 19, the water supply hose 57, the flow sensor 100. In this case, since water is not supplied to the ice maker 26, the second water supply valve 70 maintains the flow path closed.

Then, the flow path of water from the flow path control valve 33 is guided to the dispenser 40, and after passing through the first connecting hose 56 and the water tank 13, the third water supply valve 80 Water can be supplied through.

When sufficient water is supplied to the dispenser 40, the third water supply valve 80 is closed (S14).

Then, it is determined whether a predetermined time has elapsed (S20). In this case, the predetermined time may be about 10 seconds.

When a predetermined time elapses, the first water feed valve 16 is closed (S30). That is, instead of closing the third water supply valve 80 and the first water supply valve 16 simultaneously, the third water supply valve 80 and the first water supply valve 16 are sequentially closed.

At this time, the flow rate sensor 100 detects a predetermined flow rate moved through the flow sensor 100 (S40). Since the flow rate sensor 100 is disposed in a section where water passes between the third water supply valve 80 and the first water supply valve 16, the flow rate sensor even though the second water supply valve 70 is closed. Through 100, it may be detected whether water is continuously supplied.

When the predetermined flow rate detected by the flow sensor 100 exceeds a set value, it is determined that a leak occurs in the flow path of the water supplied to the third water supply valve 80, and the display unit 200 displays information about the leak. ) Or the alarm unit 210 (S50). Therefore, the user can cope with the leakage by the information accordingly.

In particular, in this case, the display unit 200 or the alarm unit 210 preferably informs the user of specific information that a leak occurred in a flow path supplied from the external water supply source 10 to the dispenser 40.

On the other hand, when the predetermined flow rate detected by the flow rate sensor 100 is smaller than the set value, it may be determined that no leakage occurs in the flow path of the water supplied to the third water supply valve 80.

At this time, the set value for the predetermined flow rate may be set by the user or a manufacturer manufacturing the refrigerator. For example, the set value may adopt a relatively small value if you want to manage the leak more strictly, and may adopt a relatively large value if you want to manage loosely without frequent repairs.

On the other hand, since the water supplied from the external water supply source 10 may have a water pressure varying within a predetermined range, even if the third water supply valve 80 is closed, the water is temporarily or temporarily transferred to the first water supply valve 16. Can be fed through). In addition, even if no leakage occurs due to various factors such as air that may be included in the flow path, the water may be moved by the range below the set value through the flow sensor 100.

In particular, the flow sensor 100 is a rear end of the flow sensor 100, that is, the flow path from the flow sensor 100 to the dispenser 40, that is, the flow control valve 33 and the first connection hose 55. ), The leak in the water tank 13 and the third water supply valve 80 can be accurately detected. This is because the flow rate sensor 100 may measure the amount of water discharged to the outlet of the flow rate sensor 100.

On the other hand, if the position of the flow sensor 100 is disposed between the first water supply valve 16 and the filter 19, the filter in the section that can accurately measure the leakage by the flow sensor 100 (19) may also be included.

A process of detecting leakage of water in the refrigerator will be described with reference to FIG. 7. In FIG. 7, descriptions of the same contents in FIGS. 5 and 6 will be omitted.

5 and 6 illustrate a situation in which water must be supplied to the dispenser 40 and the ice maker 26 separately, while in FIG. 7, water is simultaneously supplied to the dispenser 40 and the ice maker 26. Explain the situation that should be

When a situation in which water is to be supplied to the dispenser 40 and the ice maker 26 simultaneously occurs, the first water supply valve 16, the second water supply valve 70, and the third water supply valve 80 simultaneously By opening, water may be simultaneously supplied to the dispenser 40 and the ice maker 26. At this time, the flow path control valve 33 is preferably in the form that can open both flow paths so that water can be supplied to the ice maker 26 and the dispenser 40 at the same time.

At this time, since the water is sufficiently supplied to the dispenser 40 and the ice maker 26, it may be necessary to stop the supply at the same time.

In this case, the outlet side water supply valve is closed (S10). In particular, the first water supply valve 16 and the second water supply valve 70 are closed at the same time.

And the process of S20, S30, S40 mentioned above is performed, since it is the same as the above-mentioned content, detailed content is abbreviate | omitted.

At this time, in the process of supplying water from the external water supply source 10 to the inside of the refrigerator, it is possible to detect whether the water leaks as a whole. That is, in FIG. 5, it is determined whether the water supplied to the ice maker is leaked, and in FIG. 6, it is determined whether the water supplied to the dispenser is leaked, but in the above-described example, the leakage of the water supplied to the ice maker and the dispenser can be sensed together. That is, it may be determined whether the water leaked into the refrigerator is leaked.

Of course, it is also important to determine whether the leakage of water is the part moving to the dispenser or the ice maker, but it is also important to detect the leakage to prevent electric shock due to leakage. Therefore, in this example, it is possible to determine whether the water leaks.

On the other hand, unlike the above-described example, even if the situation that the water to be supplied to the dispenser 40 and the ice maker 26 at the same time occurs, sufficient water first to any one of the dispenser 40 and the ice maker 26. Although supplied, there may be cases where the other one needs to be continuously supplied with water. For example, the ice maker 26 is sufficiently supplied with water, but the dispenser 40 has to be supplied with water for a predetermined time.

Then, the second water supply valve 70 may be closed first among the outlet side water supply valves (S10). On the other hand, since the third water supply valve 80 is open, water flowing through the first water supply valve 16 may continue to be supplied to the dispenser 40. In this case, the third water supply valve 80 closes the flow path after supplying sufficient water to the dispenser 40.

And the process of S20, S30, S40 mentioned above is performed. In the process of supplying water from the external water supply source 10 to the inside of the refrigerator, it may be detected whether water is leaked as a whole.

In both of the above examples, the first water supply valve 16 is closed later than the second water supply valve 70 and the third water supply valve 80. In other words, when the flow rate is detected by the flow sensor 100 even though the outlet water supply valve is closed, it may be determined that the flow rate is leaked.

In the process according to FIG. 7, the alarm unit 210 or the display unit 200 may provide information regarding a leak (S50). In this case, however, it is preferable that the water supply from the external water supply source 10 be informed that a leak occurs while being guided to the ice maker 26 or the dispenser 40.

It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

10: external water source 16: first water supply valve
19: filter 26: ice maker
40: dispenser 70: second water supply valve
80: third water supply valve 100: flow sensor
150: control unit 200: display unit
210: alarm unit

Claims (13)

A first water supply valve for opening and closing a flow path of water introduced into the refrigerator from an external water supply;
An outlet side water supply valve for opening and closing a flow path of water moved to an ice maker or a dispenser;
A flow rate sensor disposed between the first water supply valve and the outlet side water supply valve to measure a flow rate of the moved water; And
A control unit which closes the outlet water supply valve by a predetermined period or a user's instruction and closes the first water supply valve after a predetermined time has elapsed, and receives a signal regarding the amount of water moved through the flow sensor for a predetermined time; Including,
And the control unit closes the first water supply valve by determining that leakage occurs when the amount of water moved by the flow sensor exceeds a set amount. The method of claim 1,
The outlet side water supply valve includes a second water supply valve for opening and closing a flow path for supplying water to the ice maker, and a third water supply valve for opening and closing a flow path for supplying water to the dispenser. 3. The method of claim 2,
The control unit is a refrigerator, characterized in that to adjust the second water supply valve and the third water supply valve to close with a time difference. 3. The method of claim 2,
The control unit is a refrigerator, characterized in that to adjust to close the second water supply valve and the third water supply valve at the same time. The method of claim 1,
If the amount of water moved by the flow sensor exceeds the set amount, the refrigerator further comprises a display unit for displaying information about the leak on the screen. The method of claim 1,
The refrigerator further comprises an alarm unit for notifying leakage by sound when the amount of water moved by the flow sensor exceeds a set amount. The method of claim 1,
And a flow path control valve for selectively or simultaneously guiding water in the direction of the ice maker and the dispenser between the first water supply valve and the outlet side water supply valve. A first step of closing the outlet side water supply valve for opening and closing the flow path of the water moved to the ice maker or dispenser;
A second step of closing a first water supply valve for opening and closing a flow path of water flowing from an external water supply source after a predetermined time elapses;
Determining a flow rate of water moved by the flow sensor for a predetermined time; And
And a fourth step of notifying the user of leakage when the flow rate of the water moved for a predetermined time is greater than the set value. 9. The method of claim 8,
The outlet side water supply valve includes a second water supply valve for opening and closing a flow path for supplying water to the ice maker, and a third water supply valve for opening and closing a flow path for supplying water to the dispenser,
In the first step,
And controlling at least one of the second water supply valve and the third water supply valve. 10. The method of claim 9,
In the first step,
The control method of the refrigerator, characterized in that for closing the other one of the second water supply valve and the third water supply valve. 10. The method of claim 9,
In the first step,
And controlling the second water supply valve and the third water supply valve at the same time. 9. The method of claim 8,
In the fourth step, the control method of the refrigerator, characterized in that notifying the user of the leak using the screen of the display unit. 9. The method of claim 8,
In the fourth step, the control method of the refrigerator, characterized in that notifying the user of the leak using the sound of the alarm unit.

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