KR101962130B1 - A refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator. The present invention relates to an ice- A dispenser for taking out water; And a flow control valve for selectively guiding water in the direction of the ice maker and the dispenser, wherein the flow control valve includes a flow sensor for sensing a flow rate of water, And the amount of water supplied to the ice maker is measured at a position supplied to the ice maker.
According to the present invention, an appropriate amount of water supplied to the ice maker can be maintained irrespective of the water supply pressure of the external water source, so that the ice can be smoothly iced and iced.

Description

A refrigerator

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a refrigerator, and more particularly, to a refrigerator capable of accurately regulating an amount of water supplied to an ice maker.

The refrigerator is used for refrigeration and freeze storage of stored products. A compressor, a condenser, an evaporator, and an expansion device are provided in the main body of the refrigerator for the operation.

The main body of the refrigerator is provided with a refrigerating chamber for storing refrigerating and a freezing chamber for freezing storage. The evaporator injects cold air into the refrigerating chamber and the freezing chamber.

A door for opening and closing the refrigerator compartment and the freezer compartment is mounted on the front of the refrigerator compartment and the freezer compartment and a dispenser for supplying ice and a dispenser for supplying water are installed in the door or the freezer compartment / freezer compartment.

The main body and the door are provided with a water supply pipe for guiding water to the ice maker and the dispenser. Water is moved along the water supply pipe to reach the ice maker or the dispenser for the production of ice and the extraction of drinking water.

In order to freeze the ice, a predetermined amount of water must be supplied to the ice-making tray of the ice maker. In the conventional refrigerator, it is common that water is supplied for a predetermined time without accurately calculating or sensing the amount of water.

In particular, when the refrigerator is installed in a region where the water pressure is relatively high or low due to a difference in the water pressure difference between the areas where the refrigerators are installed, there is a problem that the amount of water supplied for a predetermined time exceeds or falls below the reference value.

If the amount of water supplied to the ice maker exceeds the proper amount of water, the ice is larger than the normal designed ice size, resulting in ice that is not completely frozen, causing ice to melt inside the ice container, causing the ice tray to be twisted In case of ice machine, the ice machine may not be able to move.

On the other hand, when the water supply amount is less than the appropriate water supply amount, there is a problem that defrosting and defective freezing are caused.

The present invention provides a refrigerator in which an amount of water flowing into an ice maker can be continuously maintained in an appropriate amount irrespective of a water pressure of a water supply pipe connected to a refrigerator.

The present invention also provides a refrigerator which can accurately measure the amount of water flowing into an ice maker.

According to an aspect of the present invention, there is provided an ice maker comprising: an ice maker; A dispenser for taking out water; And a flow control valve for selectively guiding water in the direction of the ice maker and the dispenser, wherein the flow control valve includes a flow sensor for sensing a flow rate of water, And the amount of water supplied to the ice maker is measured at a position provided to the ice maker.

In particular, the flow control valve includes an inlet pipe connected to the water supply hose; A first discharge pipe connected to the dispenser; And a second discharge pipe connected to the ice maker, and the flow rate sensor may be provided in the second discharge pipe.

In this case, the second discharge pipe may include a flow rate regulating member for regulating a supply amount of water to be discharged, and the flow rate sensor may be disposed at a rear end of the flow rate regulating member.

Meanwhile, the flow rate sensor includes a body portion in which a predetermined space is formed; An impeller rotatably installed in the body and having a plurality of blades; A signal generating unit provided at an end of one of the plurality of blades; And a signal sensing unit provided in the body to sense a signal generated by the signal generating unit.

Of course, the signal generator may be composed of a magnet, and the signal sensing unit may be a hall sensor for sensing the magnetism of the magnet.

The calculation of the flow rate may be performed based on the number of rotations of the impeller, and the number of rotations may be calculated by the number of times the signal sensing unit detects the signal generated by the signal generating unit as the impeller rotates.

The flow rate regulating member includes a body portion whose outer tube is deformed according to the pressure of water to be supplied and a through hole formed at the center of the body portion. When the body portion is deformed, the diameter of the through hole can be changed.

In particular, the diameter of the through-hole can be reduced when the pressure of water supplied is increased.

On the other hand, when the diameter of the through-hole is reduced, the amount of water discharged can be reduced.

The pressure of the water supplied to the flow sensor can be kept constant than the pressure of water supplied from the external water source.

At this time, it is preferable that the flow rate sensor measures the amount of water discharged from the flow control valve to the ice maker.

And a water supply valve provided between the flow control valve and the external water supply source for guiding water from the external water supply source to the flow control valve.

Further, the flow sensor and the flow control valve can be mounted on the door of the refrigerator.

According to the present invention, it is possible to more accurately measure the amount of water supplied to the ice maker.

Further, since the present invention measures only the amount of water supplied to the ice maker, the frequency of use of the flow sensor can be reduced, thereby improving the component reliability of the flow sensor.

According to the present invention, an appropriate amount of water supplied to the ice maker can be maintained irrespective of the water supply pressure of the external water source, so that the ice can be smoothly iced and iced.

1 is a perspective view of a refrigerator according to the present invention;
2 is a front view of a refrigerator according to the present invention;
3 is a perspective view of a flow control valve according to the present invention;
4 is a sectional view of the second discharge pipe;
FIG. 5 is a sectional view showing a state where water of a higher pressure is supplied in FIG. 4; FIG.
6 is a control block diagram of a refrigerator according to the present invention.
7 is a perspective view showing a flow of water in a refrigerator according to the present invention;

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.

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

1 is a perspective view of a refrigerator according to the present invention.

1, a 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 3. As shown in FIG.

The door 5 is rotatably disposed on the main body 1. The door 5 is provided with an ice making chamber 23 for ice making and storing ice and a dispenser 40 for taking out water, Respectively.

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. The water tank 13 is provided at one side thereof with a flow control valve 80 for selectively guiding water in the direction of the dispenser 40 and the ice maker 26.

The flow control valve 80 is composed of a three-way valve and one discharge portion is connected to the dispenser 40 connected to the water tank 13 and the other discharge portion is connected to the direction of the icemaker 26.

The water supply hose 57 is connected to the external water supply source 10 to guide the water to the flow rate control valve 80. The water supply hose 57 is provided with a water supply valve 16 and a filter 19 for filtering water .

The water supply valve (16) can open or close the flow path of the water supply hose (57).

The water supply hose 57 is disposed along one side of the main body 1 and passes through the hinge unit 60 connecting the door 5 and the main body 1, And is connected to the flow control valve 80.

The first connection hose 55 connected to one side discharge portion of the flow control valve 80 is connected to the water tank 33 and the dispenser 40 (see FIG. 2).

The second connection hose 56 connected to the other discharge portion of the flow control valve 80 is disposed so as to be lifted up along one side of the door 5 and is adapted to transport water to the ice tray 27 .

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 .

2 is a front view of a refrigerator according to the present invention.

2, the dispenser 40 is mounted on the front surface of the door 5, and the water tank 13 and the flow control valve 80 are provided on the rear surface of the door 5 do.

As described above, when the user presses the water intake lever 42 of the dispenser 40, the water moving to the dispenser 40 passes through the flow control valve 80 and the water tank 13, Is discharged from the outflow portion of the first connection hose 55 provided on the upper portion of the first connection hose 42 and is accommodated in a container such as a cup.

The second connection hose 56 branched from the flow control valve 80 and directed to the ice maker 26 is disposed along the side wall of the door 5 and the outlet of the second connection hose 56 Is disposed toward the ice-making tray (27) of the ice-maker (26).

The water flowing into the ice-maker 26 falls through the passage control valve 80 into the ice-making tray 27 and is accommodated in the ice-making tray 27.

3 is a perspective view of a flow control valve according to the present invention.

As shown in Fig. 3, the flow control valve 80 includes one inflow portion and two outflow portions. That is, the flow control valve 80 includes an inlet pipe 82 connected to the water supply hose 57, a first outlet pipe 84 connected to the dispenser 40, a second outlet pipe 84 connected to the ice- (86). The first discharge pipe 84 is connected to the first connection hose 55 and the second discharge pipe 86 is connected to the second connection hose 56 to move water.

The flow control valve 80 has a flow control member 90 for controlling the amount of water discharged through the second discharge pipe 86 at a position corresponding to the second discharge pipe 86, Sensor 100 may be provided. At this time, the flow rate sensor 100 is provided at a position where water is supplied from the flow path control valve 80 to the ice maker 26, so that the amount of water supplied to the ice maker 26 can be measured.

That is, water supplied to the dispenser 40 is introduced into the flow control valve 80 through the inlet pipe 82 and discharged through the first outlet pipe 84.

On the other hand, the water supplied to the ice-maker 26 is supplied to the flow control valve 80 through the inlet pipe 82 and discharged to the second outlet pipe 86. At this time, the water discharged to the second discharge pipe (86) can pass through the flow rate control member (90) and the flow rate sensor (100) in the flow control valve (80).

4 is a sectional view of the second discharge pipe.

As shown in FIG. 4, the flow sensor 100 and the flow rate regulating member 90 may be accommodated in the second discharge pipe 86.

The flow sensor 100 includes a body 110 having a space 105 through which water can flow and a plurality of blades 122 rotatably disposed in the space 105, A signal generator 130 provided at an end of one of the plurality of blades 122 and a signal generator 130 provided in a sidewall of the space 105 to generate a signal from the signal generator 130, And a signal sensing unit 140 for sensing a generated signal.

The signal generating unit 130 may be formed of a magnet, and the signal sensing unit 140 may include a Hall sensor for sensing the magnetism of the magnet.

The body part 110 includes an inflow part 111 through which water flows and an outflow part 112 through which water flows. When water flows into the inflow portion 111, the flow of water flows to the outflow portion 112 after rotating the impeller 120. At this time, when the impeller 120 rotates, the signal generating unit mounted on the end of the blade 122 also rotates along the blade 122.

Therefore, when the end of the blade equipped with the signal generator 130 is directed to the signal detector 140, the signal detector 140 detects the presence of the signal generator 130.

Thereafter, when the impeller 120 rotates one time and the end of the blade on which the signal generating unit 130 is mounted is again directed to the signal sensing unit 140, (130).

Thus, the controller (FIG. 6, 200) to which the signal sensing unit 140 is connected recognizes that the impeller 120 makes one revolution.

At this time, the flow rate of the water flowing into the ice maker can be calculated by multiplying the flow rate of the predetermined amount of water causing the rotation of the impeller 1 by the rotation number of the impeller 120.

Therefore, the water supply amount to be supplied to the ice maker can be stopped when the flow rate of the water detected by the flow sensor 100 is compared with the set water supply amount to be supplied to the ice maker and the flow rate reaches the set water supply amount.

The flow rate regulating member 90 includes a body portion 92 whose outer tube is deformed according to the pressure of water to be supplied and a through hole 94 formed at the center of the body portion 92. The body portion 92 may be deformed according to the pressure of water supplied to the flow rate regulating member 90.

The body portion 92 is made of EPDM (Ethylene Prophlene Diene Monomer) material and can be deformed according to the pressure of the applied water. EPDM refers to synthetic rubber consisting of ethylene, prophlene, and None-conjugated Diene.

Meanwhile, the flow rate sensor 100 may be disposed at a rear end of the flow rate regulating member 90. That is, after the water has passed through the flow rate regulating member 90, it is preferable that the amount of water is measured by the flow rate sensor 100 through the flow rate sensor 100. Since the amount of water discharged by the flow rate regulating member 90 can be kept constant, the rotation of the blade 122 of the flow rate sensor 100 can be maintained at a constant speed when water passes. Therefore, the flow rate can be measured more precisely by the flow rate sensor 100.

FIG. 5 is a cross-sectional view showing a state in which water of a higher pressure is supplied in FIG.

The pressure of the water supplied from the external water source 10 may vary. In addition, the pressure of the water supplied by the external water source 10 may vary depending on the location of the refrigerator or the characteristics of the area. Therefore, it is necessary to control the amount of water supplied through the flow rate regulating member 90 to be constant.

As shown in FIG. 5, when the pressure of water supplied through the water supply hose 57 increases, the body portion 92 is deformed. The surface of the trunk portion 92 which is in contact with water is pressed, so that the trunk portion 92 can be compressed in a direction in which water presses the trunk portion 92. At this time, the diameter of the through hole 94 is changed while the body portion 92 is deformed.

Particularly, when the pressure of the supplied water is increased, the diameter and the cross-sectional area of the through hole 94 are reduced, and the amount of water discharged through the through hole 94 can be prevented from increasing with an increase in pressure. Therefore, the amount of water supplied by the flow rate regulating member 90 can be kept constant.

If the flow sensor 100 is arranged to pass through the flow rate regulating member 90 after the flow rate regulating member 90 is in the front end, that is, after the water has passed through the flow rate sensor 100, There may be a large error in the measured value to be measured.

This is because when the pressure of the water supplied by the external water source 10 suddenly increases, the sectional area of the through hole 94 is reduced as shown in FIG. The blade 122 of the flow sensor 100 can be stopped and stopped instantaneously. At this time, although the water is continuously supplied, reverse pressure is generated by the flow rate control member 90, and the rotation of the blade 122 is stopped. An error may occur in the flow rate measured by the flow rate sensor 100 due to the error.

However, in the present invention, since the amount of water is measured after passing through the flow rate control member 90, the amount of water supplied to the ice maker can be more accurately measured.

In addition, if the flow sensor 100 is installed in the water supply valve 16, the blade 122 rotates with respect to all the water passing through the water supply valve 16. Normally, it is not necessary to measure the amount of water supplied to the dispenser 40, and it is necessary to measure only the water supplied to the ice maker 26.

This is because water supplied by the dispenser 40 is sufficient to supply water while the water intake lever 42 is pressed by the user, and it is not necessary to specifically measure the amount of water supplied to the user. On the other hand, since the amount of water supplied to the ice-maker 26 may cause various problems such as insufficient ice-making if an appropriate amount is not supplied, it is necessary to measure the amount of water supplied relatively accurately.

Therefore, even though the amount of water supplied to the dispenser 40 is not measured, the water inevitably passes through the flow sensor 100 and the blade 122 of the flow sensor 100 rotates unnecessarily , There is a problem that the deterioration of the flow sensor 100 can proceed quickly. Therefore, in the present invention, the flow rate sensor 100 is installed in the second discharge pipe 86, which is a part where water is supplied to the ice maker 26.

6 is a control block diagram of a refrigerator according to the present invention.

6, an input port of the control unit 200 is provided with a water intake lever 42 for water intake, an ice extraction input unit 43 for inputting an instruction to extract ice, .

The flow sensor 100 includes the signal generating unit 130 and the signal sensing unit 140 and the signal sensing unit 140 is connected to the control unit 200.

The water supply valve 16, the flow control valve 80 and the ice maker 26 are connected to the output terminal of the controller 200. Therefore, when the intake lever 42 is operated, the water supply valve 16 operates to supply water, and the flow control valve 80 operates to guide the water moving direction toward the dispenser 42, And is taken out to the outside.

On the other hand, when the user inputs the ice extraction input unit 43, the controller 200 causes the ice of the ice storage box (see FIG. 1) to move in the direction of the dispenser 42. If there is no ice in the ice storage box 29, the icemaker 26 is operated to remove the ice, and then the ice is taken out.

When the water is supplied to the ice maker 26 and the user presses the intake lever 42, the controller 200 controls the opening direction of the flow control valve 80 for guiding the water to the water supply device through the dispenser 42 ) Direction.

When the water supply to the dispenser 42 is stopped, the opening direction of the flow control valve 80 is changed to the direction of the ice maker 26 to perform additional water supply.

At this time, the additional water supply is made by a difference amount between a set water supply amount to be supplied to the icemaker (26) and a water supply amount measured by the flow rate sensor (100).

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

In the refrigerator according to the present invention, the water supply is performed in the direction of the icemaker (26) or the dispenser (42), and it is not preferable that the water supply is simultaneously performed in both directions. This is because the amount of water to be supplied is determined, and if the moving direction of the water is made in both directions, the demand of the user who wishes to take water through the dispenser or supply water to the ice maker quickly is hindered.

First, when no water is supplied to the ice maker, or when there is no request signal to the dispenser, the water supply valve 16 is turned off, and water is not allowed to flow through the water supply hose 57.

When the ice maker 26 needs ice making and a water supply request signal is generated in that direction, the water supply valve 16 is turned on and opened, and the flow control valve 80 has a water supply direction which is opposite to that of the ice- ) Direction.

The water passing through the water supply valve 16 passes through the flow control valve 80 along the water supply hose 57 and then flows along the second connection hose 56 to the ice tray 27 of the ice- (A and C directions). At this time, the water passes through the flow rate regulating member 90 and the flow rate sensor 100.

At this time, the flow sensor 100 measures an amount of water supplied into the icemaker 26. When the amount of water reaches a predetermined amount, the controller 200 changes the water supply valve 16 to an off state, Lt; / RTI >

On the other hand, when the water intake signal is inputted from the dispenser 42, the water supply valve 16 is turned on and opened so that the water supply direction becomes the dispenser 42.

The water passing through the water supply valve 16 passes through the flow control valve 80 along the water supply hose 57 and then flows to the dispenser 42 and flows out to the outside. At this time, the water does not pass through the flow rate sensor 100 but moves to the dispenser 42.

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.

13: Water tank 80: Flow control valve
84: first discharge pipe 86: second discharge pipe
90:
100: Flow sensor 110: Body part
120: impeller 122: blade
130: Signal generator 140: Signal generator

Claims (13)

Ice maker;
A dispenser for taking out water; And
And a flow control valve for selectively guiding water in the direction of the ice maker and the dispenser,
Wherein the flow control valve includes a flow sensor for sensing a flow rate of water,
The flow control valve includes:
An inlet pipe connected to the water supply hose; A first discharge pipe connected to the dispenser; And a second discharge pipe connected to the ice maker,
Wherein the flow sensor is provided in the second discharge pipe,
Wherein the flow sensor measures the amount of water supplied only to the ice maker provided on the flow path that is supplied only to the ice maker without being supplied with water from the flow control valve to the dispenser. delete The method according to claim 1,
Wherein the second discharge pipe includes a flow rate regulating member for regulating a supply amount of water to be discharged,
Wherein the flow rate sensor is disposed at a rear end of the flow rate control member. The method of claim 3,
Wherein the flow sensor comprises: a body portion having a predetermined space;
An impeller rotatably installed in the body and having a plurality of blades;
A signal generating unit provided at an end of one of the plurality of blades;
And a signal sensing unit provided in the body to sense a signal generated by the signal generating unit. 5. The method of claim 4,
Wherein the signal generator comprises a magnet,
Wherein the signal sensing unit comprises a hall sensor for sensing the magnetism of the magnet. 6. The method of claim 5,
Wherein the calculation of the flow rate is performed based on the number of revolutions of the impeller and the number of revolutions is calculated by the number of times the signal detection unit detects the signal generated by the signal generation unit as the impeller rotates Refrigerator. The method of claim 3,
Wherein the flow rate regulating member includes a body portion whose outer tube is deformed according to a pressure of water to be supplied,
And a through hole formed in the center of the body portion,
And the diameter of the through hole changes when the body part is deformed. 8. The method of claim 7,
Wherein the diameter of the through hole is reduced when the pressure of water supplied is increased. 9. The method of claim 8,
And the amount of water to be discharged decreases when the diameter of the through-hole is reduced. The method according to claim 1,
Wherein the pressure of water supplied to the flow sensor is maintained at a constant level with respect to the pressure of water supplied from an external water source. The method according to claim 1,
Wherein the flow rate sensor measures the amount of water discharged from the flow path control valve to the ice maker. The method according to claim 1,
And a water supply valve provided between the flow control valve and an external water supply source for guiding water from an external water supply source to the flow control valve. The method according to claim 1,
Wherein the flow sensor and the flow control valve are mounted on the door of the refrigerator.

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