KR100366498B1 - Water supply structure of the refrigerator equipped with a hydraulic pressure control device - Google Patents

Abstract

The present invention relates to a water supply structure of a refrigerator provided with an ice maker and a dispensing device, wherein a single or double hydraulic pressure shutoff valve 10 is installed between a water supply source 4 and a water filter 20. It is to provide a water supply structure of the refrigerator having a hydraulic pressure blocking device to block the water pressure of the delivered water. Therefore, water that is delivered from an external water supply source 4 and maintains a high water pressure first passes through a single or double water pressure shutoff valve 10 and then is supplied to the water filter 20 for water purification so that low water pressure is applied to the water filter 20. It is possible to maintain the water leakage can be prevented when replacing the filter for water purification.

Description

Water supply structure of the refrigerator equipped with a hydraulic breaker

The present invention relates to a water supply structure of a refrigerator having an ice maker and a dispensing device, and more particularly, by preventing the water pressure of the water delivered to the water purification filter during periodic replacement of the water purification filter, thereby preventing external leakage of water due to the filter replacement. In addition, the present invention relates to a water supply structure of a refrigerator having a water pressure cut-off device for preventing water leakage at a connection portion of a water filter by lowering the water pressure applied to the water filter when the water is delivered to the ice maker and the dispenser.

In general, according to the recent trend of improving living standards and the preference for large and multi-functional refrigerators, refrigerators having a relatively large capacity and having various functions are being shown. In recent years, a refrigerator having a freezer, a refrigerator compartment dispenser and an ice maker has been introduced. As the demand for refrigerators increases, so does its function. Referring to the drawings showing the structure of a conventional complex refrigerator equipped with an ice maker and a dispense device as described above.

Figure 1 is a schematic internal view showing a water supply structure of a conventional refrigerator, Figure 2 is a flow chart showing a water supply process of the composite refrigerator. As shown, the ice maker 2 is installed on the upper one side of the freezing chamber (1). The ice maker 2 has an ice making unit 2a which forms ice, and a storage container unit 2b is installed below the ice maker 2 to store the ice formed in the ice maker 2a.

On the other hand, the dispensing device (3) is installed on the front surface of the freezer door (1a), it is possible to simply take out the water or ice desired by the user without opening the door (1a). That is, the front panel 3a located at the front of the dispensing device 3 is provided with a function button (not shown) for selecting water or ice so that the user can simply receive water or ice from the outside by pressing the function button. Will be.

The ice maker 2 and the dispensing device 3 are connected to a water supply source 4 (eg, a faucet, etc.) outside the refrigerator to receive water. That is, an external pipe 6a connected to the water supply source 4 outside the refrigerator is installed through the rear wall of the refrigerating chamber, and a filter 5 for water purification is installed at one side of the external pipe 6a, through the external pipe 6a. The incoming water is filtered. And, the other side of the filter (5) is connected to the inner pipe (6b), the water supply valve (7) is provided at the end of the inner pipe (6b).

The water supply valve 7 serves to control the water supplied to the ice maker 2 and the dispense device 3. That is, an ice maker pipe 6c connected to the ice maker 2 is installed at one side of the water supply valve 7, and a dispensing pipe 6d connected to the dispense device 4 is installed at the other side. In the middle of the dispensing pipe 6d, a water tank 8 for storing water supplied to the dispensing device 3 is provided.

As configured as described above, the water delivered from the external water supply source 4 is delivered to the ice maker 2 and the dispenser 3 through each pipe 6, the water filter 5, and the water supply valve 7. It becomes possible.

Next, the operation of the water supply valve for controlling the water supply by the ice maker 2 and the dispense device 3 as described above will be described in more detail.

As described above, the water supplied from the outside is connected to the water filter 5 through the external pipe 6a. The water filter 5 may be installed outside the refrigerator or may be installed inside the refrigerator. The water supplied from the outside passes through the water filter 5 to filter foreign matters to supply more clean water.

As shown in FIG. 3, the water filtered by the purified water filter 5 is delivered to the water supply valve 7, which supplies water to the ice maker 2 and the dispenser 3, respectively. It consists of an upper valve 7a and a lower valve 7b inside so that it can supply, and is provided with the double valves 7a and 7b controlled by an electrical signal.

The upper valve 7a and the lower valve 7b are configured to be opened and closed by an electrical signal in connection with the operation of the switches A and B. That is, when the ice maker switch A is turned on, the upper valve 7a is opened, and the water filtered by the purified water filter 5 is supplied to the ice maker 2 through the upper valve 7a. When the dispense switch B is turned on, the lower valve 7b is opened to transfer water to the dispensing device 3.

On the other hand, the ice maker switch (A) is controlled by a microcomputer installed therein. That is, when water supply is required to form ice in the ice maker 2a described above, the ice maker switch A is kept on under the control of the microcomputer. When the ice maker no longer needs to be iced, the ice maker switch A is kept under the control of the microcomputer, so that the upper valve 7a can be opened and closed. It is already input.

However, the dispensing switch B is kept on by the user pressing the water selection button of the front panel 3a. Accordingly, while the user presses the water selection button, the dispensing switch B is turned on, and the lower valve 7b located in the water supply valve 7 is opened in accordance with the electrical signal transmitted thereto. It consists of the structure to be supplied. Therefore, when the user presses the water selection button to drink water, the lower valve 7b inside the water supply valve 7 is opened, and the water passing through the water supply valve 7 is delivered to the water storage tank 8. The water stored in the water storage tank 8 is supplied to the dispensing device 3. In addition, since the water storage tank 8 is located inside the refrigerating compartment, the water stored in the water storage tank 8 may be stored at a low temperature by the refrigerating temperature of the refrigerating compartment, thereby providing cool cold water to the user.

However, the following problems occur in the conventional composite refrigerator by the configuration and operation as described above.

The water filter 5 for filtering water supplied from the outside should be cleaned or replaced from time to time after use for a certain time. At this time, the water delivered through the external pipe (6a) connected to the water filter (5) maintains a constant high water pressure. Therefore, in order to clean the water filter 5 or replace it with a new one, there is a problem that water through the external pipe (6a) is poured out as the water filter (5) is separated. In order to solve the above problems, the external water supply source 4 should be locked every time the replacement and cleaning of the water purification filter 5 is performed, which causes a very inconvenience for the user.

In addition, the high water pressure is always applied to the water filter 5, there is a problem that the fastening force is reduced by long use, so that water leaks, that is, water is transferred directly from the external water supply to the water filter (5). The water pressure delivered from the source is applied to the water filter as it is. Therefore, water leakage occurs through the fastening portion of the water filter 5 by the water pressure when used for a long time. In addition, the water filter 5 may be installed at any position outside the refrigerator or inside the refrigerator, but when installed inside the refrigerator, the leaked water may be introduced into the refrigerator and transferred to the food being stored to alter the food. .

Accordingly, an object of the present invention is to solve the above problems, and the purpose of the present invention is to prevent water from leaking to the outside even during periodic replacement of the water filter by blocking the water pressure of the water delivered to the water filter when the water filter is replaced.

Another object of the present invention is to reduce the water pressure of the water delivered from the external water supply to the water purification filter so that water does not leak through the water purification filter even if the water purification filter is used for a long time.

1 is an internal schematic view showing a water supply structure of a composite refrigerator.

2 is a flow chart showing a water supply process of the conventional water supply structure.

Figure 3 is a simple configuration showing the control of the conventional water supply structure.

4 is a flow chart showing a water supply process of the water supply structure according to an embodiment of the present invention.

5 is a configuration diagram showing the control by the water supply structure of FIG.

6 is a flow chart showing a water supply process of the water supply structure according to another embodiment of the present invention.

7 is a block diagram showing the control by the water supply structure of FIG.

Explanation of symbols on the main parts of the drawings

10: hydraulic pressure shutoff valve 10 ': hydraulic pressure shutoff valve

10a ': Relay 12: Upper valve

14: lower valve 20,20 ': water filter

30,30 ': Water supply valve 32,32': Upper valve

34,34 ': Side valve A, A': Ice maker switch

B, B ': dispense switch

According to a first aspect of the present invention for achieving the above object, the present invention comprises: a water source; A water purification unit for filtering foreign substances of water delivered from the water supply source and combining and separating them for exchange; A water pressure blocking means for transferring water to the water purification unit by opening and closing, and blocking water pressure applied to the water purification unit in a closed state; And it is configured to include a water supply valve for controlling the delivery of purified water from the water purification unit to the ice maker and the dispense device.

The hydraulic pressure blocking means is constituted by a valve provided between the water supply source and the purified water part.

The hydraulic pressure blocking means is constituted by a double hydraulic pressure shutoff valve which is linked with the water supply valve to open and close.

The hydraulic pressure blocking means is composed of a single hydraulic pressure shutoff valve driven by a relay in accordance with the operation of the water supply valve.

As shown in the above configuration, in order to block the water pressure of the water delivered to the filter for water purification, the water delivered from an external water supply source to maintain a high water pressure is first blocked by a hydraulic pressure blocking means consisting of a single or double valve. To make it happen. Therefore, when water is supplied, water that maintains the high water pressure is first blocked by the water supply valve, and water is supplied to the water filter only when necessary, so that excessive water pressure is prevented on the water filter side even when used for a long time so that water leaks. Also, since water is not supplied at the time of exchange of writing, the water pressure of the water delivered to the filter by the water supply valve is cut off, so that the exchange is easily performed.

Next, with reference to the drawings of Figures 4 and 5 showing an embodiment of the water supply structure of the refrigerator having a hydraulic pressure blocking device according to the present invention having the characteristics as described above will be described in more detail. In the following description, the same components as in the prior art will be described using the same reference numerals as used in FIGS. 1 to 3.

As shown, in the present embodiment, a double hydraulic shutoff valve 10 consisting of a double valve is used to block the water pressure of the water transferred from the external water supply source 4 to the purified water filter 20. That is, the double hydraulic shut-off valve 10 is composed of a plurality of valves 12 and 14 which are provided between the water supply source 4 and the water filter 5 and are opened and closed by an electrical signal. In addition, the water supply valve 30 for supplying the water transferred from the water filter 20 to the ice maker 2 or the dispensing device 3 is also composed of double valves 32 and 34 as in the prior art.

On the other hand, as shown in Figure 5, the double hydraulic shutoff valve 10 is operated in conjunction with the water supply valve (30). That is, the upper valve 12 of the double hydraulic shutoff valve 10 and the upper valve 32 of the water supply valve 30 are electrically connected to each other to open and close together, and the lower valve 14 of the hydraulic shutoff valve 10 is closed. ) And the lower valve 34 of the water supply valve 30 is also to be operated together. In addition, the control of each of the double hydraulic shutoff valve 10 and the water supply valve 30 has a structure that is opened and closed by an electrical signal in connection with the operation of the switches (A, B). That is, when the ice maker switch A is turned on, the upper valve 32 of the water supply valve 30 and the upper valve 12 of the double hydraulic shutoff valve 10 are opened by the electrical signal according to the ice maker switch A. do. When the dispense switch B is turned on, the lower valve 34 of the water supply valve 30 and the lower valve 14 of the double hydraulic shutoff valve 10 are opened.

The ice maker switch A is controlled by a microcomputer installed therein. That is, when water supply is required to form ice in the ice making unit 2a described above, the ice maker switch A is kept on under the control of the microcomputer, and even when the ice maker no longer needs to be iced. Under the control of the ice maker switch (A) is kept off (off) control is made automatically.

However, the dispensing switch B is kept on by the user pressing the water selection button. Accordingly, while the user presses the water selection button, the dispensing switch B is turned on, and each lower side of the water supply valve 30 and the double hydraulic shutoff valve 10 is located in accordance with the electrical signal transmitted thereto. The valves 34 and 14 are opened to form a water supply structure.

On the other hand, the operation of the ice maker switch (A) and the dispensing switch (B) is made alternatively. That is, the dispense switch B maintains the off state while the ice maker switch A remains on, and the ice maker switch A maintains the off state while the dispense switch B maintains the on state. It is supposed to. Therefore, the water supply is always configured to be made only in one direction of the ice maker 2 or the dispense device (3). The control as described above is of course made by a microcomputer built in the refrigerator, and such an alternative control is also applied to the conventional refrigerator, and thus a detailed description thereof will be omitted.

Then, when water is supplied, the water delivered from the external water supply source 4 is first delivered to the double hydraulic shutoff valve 10 first, and the double hydraulic shutoff from the double hydraulic shutoff valve 10 to the filter 20 for water purification. Only part of the water delivered from the water source 4 is delivered through the upper valve 12 or the lower valve 14 of the valve 10. Therefore, when water supply is not made, the water pressure is kept blocked in the water filter 20. Therefore, since excessive water pressure is prevented from being applied to the water filter 20 at all times, a drop in fastening force does not occur, and water leakage may be prevented.

On the other hand, when the water supply is not made, the high water pressure transmitted from the water supply source 4 reaches only the double hydraulic shutoff valve 10, the upper valve 12 and the lower valve 14 of the double hydraulic shutoff valve 10. The state in which the water is not delivered to the water filter 20 is maintained in a closed state. Therefore, since no water pressure is applied to the water filter 20 and there is no water to be delivered, water leakage may be prevented when the water filter 20 is replaced. Therefore, the replacement operation of the water filter 20 can be made smoothly. In addition, since the configuration for water transfer from the water supply valve 30 to the ice maker 2 and the dispensing apparatus 3 thereafter is the same configuration as in the prior art, a detailed description thereof will be omitted.

Next will be described briefly as a whole the operation of the water supply structure of the refrigerator of the present invention configured as described above. The ice maker 2 is operated under the control of the microcomputer installed in the refrigerator. That is, when ice needs to be formed, the ice maker switch A is turned on under the control of the microcomputer, and thus an electrical signal is transmitted to the water supply valve 30 and the double hydraulic shutoff valve 10. According to the transmitted signal, the upper valve 32 and the upper valve 12 of the double hydraulic shutoff valve 10 in the water supply valve 30 are opened. Accordingly, the water supplied from the water supply source 4 sequentially passes through the upper valve 12 of the double hydraulic shutoff valve 10, the filter for water purification 20, and the upper valve 32 of the water supply valve 30, and an ice maker 2. Is delivered. Of course, in the above case, since the lower valve 14 in the double hydraulic shutoff valve 10 is kept closed, only a part of the water delivered from the external water supply source 4 may open the upper valve 12 of the double hydraulic shutoff valve 10. Through the water filter 20 to be passed through.

On the other hand, as described above, the dispensing switch (B) is kept on only while the user presses the water-suntec button (3a) located on the front of the refrigerator door. Therefore, while the user presses the water selection button, the dispense switch (B) is turned on, and according to the electrical signal, the lower valve 34 of the water supply valve 30 and the lower valve (10) of the double hydraulic shutoff valve (10). 14) is opened. Accordingly, the water delivered from the water supply source 4 is dispensed through the lower valve 14 of the double hydraulic shutoff valve 10, the water filter 20, and the lower valve 34 of the water supply valve 30. ) Can be delivered.

In summary, the water pressure is not always applied to the water filter 20 side, but the double hydraulic pressure shutoff valve 10 is opened to supply water only when water is supplied. Therefore, in the related art, excessive water pressure is always applied to the water purification filter 20 so that water leakage occurs due to a decrease in the fastening force. However, in the present invention, water leakage due to a decrease in the fastening force is prevented because excessive water pressure is prevented from being applied to the water purification filter 20. There is no fear of occurrence.

In addition, in the case of periodic replacement of the water purification filter 20, conventionally, the external water supply source 4 and the water purification filter 20 are directly connected to each other so that the water pressure by the water supplied from the water supply source 4 is reduced. 20) as it is going crazy as well as hard work, there was a problem that water is poured. However, as described above, when water is not supplied to the ice maker and the dispensing device, the double hydraulic shutoff valve 10 is kept in a closed state so that no water is supplied to the water filter 20. As a result, the water pressure is maintained on the filter 20 side. Therefore, the water purification filter 20 can be easily replaced, and water can be prevented from spilling to the outside.

Next, another embodiment of the refrigerator water supply structure with the hydraulic pressure blocking means according to the present invention will be described with reference to FIGS. 6 and 7.

As shown, in this embodiment, a single hydraulic pressure shutoff valve 10 'to cut off the water pressure between the water supply 4 and the water filter 20 in order to block the water pressure of the water delivered from the water supply 4. ) Structured. Using the single hydraulic pressure shutoff valve 10 'as described above can reduce the cost than using the double hydraulic pressure shutoff valve 10 consisting of a double valve used in the above-described embodiment, and the volume of the double hydraulic pressure Less than the shut-off valve 10 can reduce the noise inside the machine room. In addition, the operation of the single hydraulic shutoff valve 10 'is operated in conjunction with the water supply valve 30 to be described later by the relay (10a').

In addition, the water filter 20 is connected to the single water pressure shutoff valve 10 ′, and a water supply valve 30 is connected to the water filter 20. The water supply valve 30 adjusts the direction of water delivered to the ice maker 2 and the dispensing device 3. That is, two valves are installed inside the water supply valve 30 so that water through the upper valve 32 is delivered to the ice maker 2 side, and water through the lower valve 34 is delivered to the dispensing device 3 side. do. In addition, the water supply valve 30 is opened and closed by an electrical signal according to the operation of the switches (A, B), and is linked with the operation of the water supply valve 30 by the relay 10a 'the single water pressure. As the shutoff valve 10 'is adjusted, water is supplied.

Referring to the circuit configuration for the operation of the water supply valve 30 and the single water pressure blocking valve 10 ', as shown in Figure 7, when the ice maker switch (A) is turned on (on) under the control of the microcomputer, The upper valve 32 inside the water supply valve 30 is opened by an electrical signal transmitted. At the same time, the electrical signal is transmitted to the relay 10a ', and the electrical current is configured to generate an electrical flow at the contact b of the relay 10a' by the transmitted current. Therefore, a current is applied to the single hydraulic shutoff valve 10 'through the contact b of the relay 10a' so that the single hydraulic shutoff valve 10 'is also opened.

In addition, when the dispense switch (B) is turned on (on), the electrical signal is applied to the lower valve 34 is configured to open. At the same time, the electrical signal transmitted is transmitted to the relay 10a ', and the relay coil c is operated by the transmitted signal. By the operation of the relay coil (c), the relay element is moved to the contact a to generate a current flow through the contact a. Therefore, even in this case, the current is applied to the single hydraulic shutoff valve 10 'by the operation of the relay 10a', and the single hydraulic shutoff valve 10 'is also configured to open. Therefore, when the ice maker switch (A) or the dispense switch (B) is operated, the current flows to the single hydraulic shutoff valve (10 ') through the contact point a or b by the operation of the relay (10a'). Opening of the single hydraulic shutoff valve 10 'is enabled.

Next will be described the operation process according to the configuration of the water supply structure configured as described above.

First, the supply of water delivered to the ice maker 2 side is controlled by a microcomputer located inside as in the prior art. Therefore, when water is required to supply ice to the ice maker 2 side, ice maker switch A is operated under the control of the microcomputer, thereby opening the upper valve 32 of the water supply valve 30. In addition, the relay 10a 'is operated by a signal transmitted according to the operation of the ice maker switch a' to open the valve of the single hydraulic shutoff valve 10 '. Therefore, in this case, the water delivered through the single water pressure shutoff valve 10 'is passed through the water filter 20 to the ice maker 2 through the upper valve 32 inside the water supply valve 30. In this case, since the lower valve 34 is closed, the water is not delivered to the dispensing 3.

On the other hand, the water supplied to the dispense device (3) is configured to operate only while pressing the water selection button located on the front of the refrigerator door as described above. Therefore, the dispensing switch (B) is kept on while the user presses the water selection button to drink water. The lower valve 34 of the water supply valve 30 is opened by the electrical signal transmitted by the dispense switch B. At the same time as the operation of the lower valve 34, a signal according to the operation of the dispensing switch B is transmitted to the relay 10a 'so that the single hydraulic pressure shutoff valve 10' is also opened. Therefore, the supplied water is delivered to the water storage tank 8 through the single hydraulic shutoff valve 10 ', the water filter 20 and the lower valve 34 of the water supply valve 30. In addition, the low temperature water refrigerated in the water storage tank 8 is delivered to the dispensing device 3 and supplied to the user, and the insufficient water can be supplied to the water storage tank 8 through the above process.

In addition, the operation of the upper valve 32 and the lower valve 34 respectively positioned on the upper and lower sides of the water supply valve 30 is operated separately. That is, as described above, the operation of the ice maker switch (A) and the dispensing switch (B) is configured to be made mutually alternative, this alternative operation is the same as the conventional description will be omitted.

Meanwhile, in the conventional structure shown in FIGS. 1 to 3, the water supplied from the external water supply source 4 is directly connected to the water filter 5 and is blocked by the water supply valve 7. In (5), the state of high water pressure is always maintained. Therefore, water leakage occurs when used for a long time due to excessive water pressure. In addition, the external faucet, etc. for the replacement of the water purification filter 5 to prevent water from being delivered to the water purification filter 5 side, there was an inconvenience to replace the water purification filter (5).

However, in the present invention, the water supplied from the outside is delivered to the water filter 20 through the single hydraulic shutoff valve 10 '. When the ice maker switch A or the dispense switch B is not operated, the single water pressure shutoff valve 10 'is kept locked so that no water pressure is applied to the water filter 20. Therefore, unlike the conventional water filter 20 is prevented from being subjected to excessive water pressure can be prevented from leaking water even when used for a long time.

In addition, as described above, in this embodiment, since water supplied from an external water supply source is preferentially connected to the water filter 20 through a single hydraulic shutoff valve 10 ', the ice maker 2 or the dispensing device 3 ) Is not operated, the water is not delivered to the water filter 20 by the single hydraulic shutoff valve 10 '. Therefore, it provides a convenient point that can perform the replacement operation of the water filter 20 even when the external faucet is not locked.

According to the water supply structure of the refrigerator having the hydraulic pressure cutoff device according to the present invention described above, since water supplied from the outside is transferred to the water filter through the hydraulic shutoff valve, water of low water pressure is transferred to the water filter. Since the water pressure is blocked in the water purification filter in a state where water is not supplied, there is an effect of preventing water leakage through the water purification filter even when used for a long time.

In addition, since the water supplied from the outside during the replacement of the water purification filter maintains a state in which water is not transferred to the water purification filter by the hydraulic shutoff valve, the water does not leak to the outside during the replacement operation of the water purification filter as well as in the prior art. The replacement of the water filter can be performed immediately in the unlocked state of the external faucet.

Claims (4)

Water supply source; A water purification unit for filtering foreign substances of water delivered from the water supply source and being separated for exchange; A water pressure blocking means for transferring water to the water purification unit by opening and closing, and blocking water pressure applied to the water purification unit in a closed state; And A water supply structure of the refrigerator having a water pressure cut-off device, characterized in that it comprises a water supply valve for controlling the transfer of water purified by the water purification unit to the ice maker and the dispenser. The method of claim 1, The water pressure blocking means is a water supply structure of a refrigerator having a water pressure blocking device, characterized in that the valve is installed between the water supply source and the water purification unit. The method according to claim 1 or 2, The water pressure blocking means is a water supply structure of a refrigerator having a water pressure shutoff device, characterized in that it is composed of a double water pressure shutoff valve which is opened and closed operation in conjunction with the water supply valve. The method according to claim 1 or 2, The water pressure blocking means is a water supply structure of a refrigerator having a water pressure shutoff device, characterized in that configured as a single water pressure shutoff valve driven by a relay in accordance with the operation of the water supply valve.