KR20090019615A - A water purifier and method for preventing flowing backward thereof - Google Patents

Abstract

A water purifier is provided to reduce power consumption by transferring heat generated in the thermoelectric element to a radiating plate when a thermoelectric element is operated, and insulating the thermoelectric element from the radiating plate when the thermoelectric element is not operated, thereby preventing heat remained in the radiating plate from flowing backward to the thermoelectric element and a cold water tank, and a method for preventing heat from flowing backward in the water purifier is provided. A water purifier comprises: a cold water tank(110) storing water to be cooled by receiving water from a water supply source; a thermoelectric element(120) which is installed to face the cold water tank, and which cools the water stored in the cold water tank; a radiating plate(130) which is installed to face a direction opposite to the facing direction of the cold water tank of the thermoelectric element, and which radiates heat generated from the thermoelectric element; a heat backflow preventing unit which is installed between the thermoelectric element and radiating plate, which transfers heat generated in the thermoelectric element to the radiating plate when the thermoelectric element is operated, and which insulates the thermoelectric element from the radiating plate when the thermoelectric element is not operated.

Description

A water purifier and method for preventing flowing backward

The present invention relates to a water purifier, and more particularly, to a water purifier and a method for preventing backflow of a water purifier to which the thermoelectric element is a cooling means.

Various methods are used for the cooling device used in the water purifier, but in consideration of design miniaturization, vibration and noise, and a design aspect, a cooling device using a thermoelectric element has recently been introduced. Thermo Electric Module is a type of heat pump that cools one side and generates heat on the other side when power is supplied. The thermoelectric module is simple and small in configuration, as opposed to the bulky, heavy, heavy vibration and noise of the compressor method. It has the advantage of no noise and vibration.

1 illustrates an example of a water purifier to which such a thermoelectric element is applied.

Referring to FIG. 1, a cold water tank 10 is installed at one side of the thermoelectric element 15 with a cooling member 12 interposed therebetween, so that the water stored in the cold water tank 10 is cooled by the thermoelectric element 15. do. The heat sink 13 is installed on the other side of the thermoelectric element 15 to dissipate heat generated from the thermoelectric element 15. And, the cooling fan 14 absorbs the heat radiated by the heat sink 13 and sends it to the outside.

On the other hand, the thermoelectric element 15 does not always operate, but the operation is stopped when the water in the cold water tank 10 reaches the appropriate temperature. At this time, the heat from the heat dissipation plate 13 flows back to the cold water tank 10 via the thermoelectric element 15, that is, a thermal backflow phenomenon occurs. The water in the cold water tank 10 is not brought to an appropriate temperature by the thermal backflow, so that the power consumption is increased by operating the thermoelectric element 15 again, and a user may not be able to drink cold water at an appropriate temperature. Can be.

The present invention has been made in view of the above, the present invention provides a water purifier and a method for preventing the backflow of the water purifier and the water purifier to prevent the heat from the heat sink back to the cold water tank when the thermoelectric element as a cooling means does not operate. Its purpose is to.

Water purifier according to the present invention for achieving the above object, the cold water tank in which the water to be supplied to the water supply is stored cold water; A thermoelectric element installed to face the cold water tank and cooling the water stored in the cold water tank; A heat dissipation plate installed to face in a direction opposite to a direction facing the cold water tank of the thermoelectric element, and dissipating heat generated from the thermoelectric element; And installed between the thermoelectric element and the heat sink to transfer heat generated from the thermoelectric element to the heat sink when the thermoelectric element is operated, and to insulate the thermoelectric element from the heat sink when the thermoelectric element is not operated. It is characterized in that it comprises a; heat reverse flow prevention unit that operates to.

The thermal backflow prevention unit may include: a liquid jacket installed to face between the thermoelectric element and the heat dissipation plate, and having a space in which liquid is contained; First and second connecting pipes connected to one end and the other end of the liquid jacket to supply and discharge liquid to the liquid jacket and having first and second valves respectively installed in a path; And sensing the operation of the thermoelectric element so that the liquid is contained in the liquid jacket when the thermoelectric element is operated, and discharges the liquid in the liquid jacket and fills the air when the thermoelectric element is not operated. And a controller for controlling the first and second valves to operate.

In addition, the liquid jacket has a hexahedral shape, the surface facing the thermoelectric element and the heat sink is formed of aluminum or stainless steel, and the other surface is formed of acrylic or synthetic water.

On the other hand, the method for preventing the heat backflow of the water purifier according to the present invention for achieving the above object, the method of preventing heat backflow of the disclosed water purifier, a) detecting the operation of the thermoelectric element; b) transferring heat generated by the thermoelectric element to the heat sink when the thermoelectric element is operated; And c) insulating the thermoelectric element from the heat sink when the thermoelectric element is not operated.

On the other hand, step b), filling the liquid inside the liquid jacket to transfer the heat generated in the thermoelectric element through the liquid to the heat sink, step c), the liquid inside the liquid jacket By discharging the air insulating step between the thermoelectric element and the heat sink.

According to the present invention, when the thermoelectric element is operated, the heat generated from the thermoelectric element is transferred to the heat sink, and when the thermoelectric element is not operated, the heat remaining on the heat sink is insulated between the thermoelectric element and the heat sink to flow back to the thermoelectric element and the cold water tank. Will not be. Therefore, the additional power consumption is not generated, thereby reducing the cost and providing the cold water at a suitable temperature desired by the user, thereby increasing the user satisfaction.

The above objects, features and other advantages of the present invention will become more apparent by describing the preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the water purifier according to an embodiment of the present invention.

2 and 3, the water purifier according to the embodiment of the present invention includes a cold water tank 110, a thermoelectric element 120, a heat sink 130, and a thermal backflow prevention unit 150.

Cooling member 112 is disposed on one side of the cold water tank 110, the thermoelectric element 120 is a cooling means for cooling the cold water tank 110 through the cooling member 112 on one side of the cooling member (112) Is placed. In addition, the heat dissipation side of the thermoelectric element 120 absorbs heat radiated from the thermoelectric element 120 and the cooling fan 140 sucks heat dissipated by the heat dissipation plate 130 and discharges it to the outside of the water purifier. ) Is placed.

The cold water tank 110 receives water from a water supply source not shown and stores water to be cold water. Although not shown, various filters are installed in the water purifier to filter the water from the water supply source, and the filtered water is introduced into the cold water tank 110 through the inlet 113. In addition, when the user presses a cock or a discharge button not shown installed outside the water purifier to drink cold water, the cold water cooled in the cold water tank 110 is discharged through the discharge port 114.

One surface of the cold water tank 110 is installed to face the thermoelectric element 120 with the cooling member 112 therebetween. The cooling member 112 is preferably formed of an aluminum material so that heat exchange between the thermoelectric element 120 and the cold water tank 110 can be made well. On the other hand, in the present invention, the cooling member 112 is sufficient if the heat exchange between the thermoelectric element and the cold water tank is well performed, the shape, the number of shapes and the like is not limited to a specific one.

When the thermoelectric element 120 is supplied with power, one side is cooled and the other side is heated according to the Peltier Effect. Specific principles and operations of the thermoelectric element 120 correspond to techniques well known to those skilled in the art, so a detailed description thereof will be omitted. A plurality of thermoelectric elements 120 may be installed as necessary.

On the other hand, the thermal backflow prevention unit 150 is installed between the thermoelectric element 120 and the heat sink 130. The thermal backflow prevention unit 150 transfers the heat generated from the thermoelectric element 120 to the heat sink 130 when the thermoelectric element 120 operates, and the thermoelectric element 120 when the thermoelectric element 120 does not operate. Operate to insulate between heat sinks 130. The thermal backflow prevention unit 150 includes a liquid jacket 152, a first connector 154, a second connector 156, and a controller 158.

The liquid jacket 152 is installed to face between the thermoelectric element 120 and the heat dissipation plate 130, and a space in which the liquid is contained is formed. According to this embodiment, the liquid jacket has a substantially hexahedral box shape having a rectangular cross section, but the scope of the present invention is not limited thereto. The liquid jacket 152 is preferably a surface facing the thermoelectric element 120 and the heat sink 130, that is, the left and right sides in the drawing is formed of aluminum or stainless steel (SUS) material, which operates the thermoelectric element 120 This is to transfer heat generated from the thermoelectric element 120 to the heat sink well. In addition, the upper and lower surfaces of the remaining surface of the liquid jacket 152, in particular, the first and second connection pipes 154 and 156, may be formed of acrylic or synthetic water for thermal insulation.

The first connecting pipe 154 is connected to the upper end of the liquid jacket 152 and the first valve 155 is installed on the path. First connector 154 is connected to a liquid source, not shown. The liquid source may be a raw water source, may be an unfiltered reservoir or the cold water tank 110, and is not limited to any of the present invention, it is sufficient to supply water. The second connecting pipe 156 is connected to the lower end of the liquid jacket 152 and the second valve 157 is installed on the path. The first and second connection pipes 154 and 156 are flow paths through which the liquid moves, and the liquid is supplied to and discharged from the liquid jacket 152 by the first and second valves 155 and 157 installed on the path. Let's do it. The first and second valves 155, 157 operate by the control signal of the controller 158.

The controller 158 controls to operate various components of the water purifier. On the other hand, the cold water tank 110 is provided with a temperature sensor 114, the controller 158 by using the temperature information sent from the temperature sensor 114, the cold water in the cold water tank 110, the predetermined temperature If the condition is not satisfied, the thermoelectric element 120 is controlled to operate.

On the other hand, the controller 158 detects the operation of the thermoelectric element 120 and transmits a control signal so that the liquid is contained in the liquid jacket 152 when the thermoelectric element 120 operates. That is, when the thermoelectric element 120 is on, the second valve 157 is closed, the first valve 155 is opened to fill the liquid in the liquid jacket 152, and the first valve 155 is closed. Since the heat continues to be generated when the thermoelectric element 120 operates, the liquid jacket 152 filled with liquid conducts the heat of the thermoelectric element 120 to the heat sink 130.

In addition, the controller 158 transmits a control signal to discharge the liquid filled in the liquid jacket 152 when the thermoelectric element 120 is not operated (off). That is, the first valve 155 is kept closed, and only the second valve 157 is opened to discharge the liquid in the liquid jacket 152. As the liquid is discharged, the inside of the liquid jacket 152 is filled with air so that the thermoelectric element 120 and the heat sink 130 are insulated by air. Of course, air does not completely block heat transfer, but as is well known, it has superior thermal insulation compared to liquids. Therefore, the heat inherent by the heat sink 130 is blocked by the liquid-filled jacket 152 filled with air to prevent the heat element 120 and the cold water tank 110 from going toward the heat, and the heat flow back from the heat sink 130 is conventionally generated. It prevents the phenomenon.

Hereinafter, an operation of the water purifier having the above configuration and a method for preventing heat backflow of the water purifier according to the embodiment of the present invention will be described with reference to FIG. 4.

First, in the initial operation of the water purifier, the controller 158 sends a control command to fill the liquid in the liquid jacket 152 (S210). That is, the second valve 157 is closed, the first valve 155 is opened to fill the liquid in the liquid jacket 152, and the first valve 155 is closed.

Then, the controller 158 detects the operation of the thermoelectric element 120 (S220).

When the thermoelectric element 120 is operated, the controller 158 repeats the "S220" step.

On the other hand, when the thermoelectric element 120 is not operating (off) (S230), the controller 158 sends a control signal to discharge the liquid filled in the liquid jacket 152 (S240). That is, the first valve 155 is kept closed, and only the second valve 157 is opened to discharge the liquid in the liquid jacket 152. As the liquid is discharged, the inside of the liquid jacket 152 is filled with air so that the thermoelectric element 120 and the heat sink 130 are insulated by air. Of course, air does not completely block heat transfer, but as is well known, it has superior thermal insulation compared to liquids. Therefore, the heat inherent by the heat sink 130 is blocked by the liquid-filled jacket 152 filled with air to prevent the heat element 120 and the cold water tank 110 from going toward the heat, and the heat flow back from the heat sink 130 is conventionally generated. It prevents the phenomenon.

After that, the controller 158 detects the operation of the thermoelectric element 120 again (S250).

When the temperature of the cold water tank 110 is lowered and the thermoelectric element is turned on again, the controller 158 detects this and the liquid inside the liquid jacket 152 inside the liquid jacket 152. The control signal is sent to be contained again (S260). That is, when the thermoelectric element 120 is on, the second valve 157 is closed, the first valve 155 is opened to fill the liquid in the liquid jacket 152, and the first valve 155 is closed. Since the heat continues to be generated when the thermoelectric element 120 operates, the liquid jacket 152 filled with liquid conducts the heat of the thermoelectric element 120 to the heat sink 130.

When the thermoelectric element is not turned on, the controller 158 repeats the "S250" step.

1 is a schematic configuration diagram of a water purifier according to the prior art,

2 is a schematic configuration diagram of a water purifier according to an embodiment of the present invention;

3 is a block diagram illustrating main parts of a water purifier according to an embodiment of the present invention;

4 is a flowchart illustrating a method for preventing thermal backflow of a water purifier according to an embodiment of the present invention.

<Description of Major Symbols in Drawing>

110. Cold water tank 112. Cooling member

120. Thermoelectric element 130. Heat sink

150. Heat Backflow Prevention Unit 152. Liquid Jacket

154. First connector 155. First valve

156. Second connector 157. Second valve

158.Controller

Claims (5)

Cold water tank to store the water to be supplied cold water to the water supply source; A thermoelectric element installed to face the cold water tank and cooling the water stored in the cold water tank; A heat dissipation plate installed to face in a direction opposite to a direction facing the cold water tank of the thermoelectric element, and dissipating heat generated from the thermoelectric element; And, Installed between the thermoelectric element and the heat sink, the thermoelectric element transfers heat generated from the thermoelectric element to the heat sink when the operation, and to insulate between the thermoelectric element and the heat sink when the thermoelectric element is not in operation Water purifier comprising; a water purifier. According to claim 1, wherein the heat backflow prevention unit, A liquid jacket installed to face the thermoelectric element and the heat sink, and having a space in which liquid is contained; First and second connecting pipes connected to one end and the other end of the liquid jacket to supply and discharge liquid to the liquid jacket and having first and second valves respectively installed in a path; Detecting the operation of the thermoelectric element, so that the liquid is contained in the liquid jacket when the thermoelectric element is operated, and discharge the liquid inside the liquid jacket and the air is filled when the thermoelectric element is not operating, the first And a controller for controlling the second valve to operate. The method of claim 2, The liquid jacket has a hexahedron shape, and the surface facing the thermoelectric element and the heat sink is formed of aluminum or stainless steel, and the other surface is formed of acrylic or synthetic water. In the method for preventing heat backflow of a water purifier according to any one of claims 1 to 3, a) detecting the operation of the thermoelectric element; b) transferring heat generated by the thermoelectric element to the heat sink when the thermoelectric element is operated; And, c) insulating heat between the thermoelectric element and the heat sink when the thermoelectric element is not in operation. The method of claim 4, wherein The step b) includes filling a liquid in the liquid jacket to transfer heat generated from the thermoelectric element to the heat sink through the liquid, The c) step, the step of discharging the liquid in the liquid jacket to insulate the air backflow between the thermoelectric element and the heat sink characterized in that it comprises a step of preventing the water backflow.

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