KR20120129484A - water purifier using thermoelectric element - Google Patents

Abstract

PURPOSE: A water purifier using a thermoelectric element is provided to prevent the generation of operational noises by cooling a cooling pad using electric currents applied to a thermoelectric semiconductor. CONSTITUTION: A water purifier includes a filtering module(50), a cool and warming module(60), a circulating module(70), and a discharging pipe(80). The cooling and warming module cools a part of purified water from the filtering module based on thermoelectric phenomenon and heats remaining purified water based on the thermoelectric phenomenon. The circulating module circulates the purified water through the filtering module and the cooling and warming module. The cooling and warming module includes a plurality of thermoelectric semiconductors, a cooling pad, and a heating pad. The thermoelectric semiconductors are composed of thermoelectric elements. Cooling effect is generated from one side of a thermoelectric element, and heating effect is generated from another side of the thermoelectric element. [Reference numerals] (76) Temperature controller

Description

Water purifier using thermoelectric element

The present invention relates to a water purifier using a thermoelectric element, and more particularly, to a water purifier using a thermoelectric element that performs cooling and heating of purified water using a thermoelectric element.

In general, the water purifier was developed for the purpose of purifying water used for drinking water, and according to its shape, it is a faucet attachment type used by directly connecting to a faucet and a table type that receives water from a plastic bucket and purifies it during natural dropping process. Tubular), and depending on the water purification method, it is divided into water direct connection type, natural filtration type, ion exchange resin type, distillation type, and reverse osmosis type.

Among them, the reverse osmotic pressure water purifier, which is commonly used, will be described in detail below.

1 is a view illustrating a cooling system of a conventional reverse osmosis water purifier. As is well known, a water purification method using reverse osmosis is supplied with raw water through tap water, and a plurality of raw water is applied by applying pressure to raw water containing various impurities. Impurities are filtered through two filters, and the filtered water contains only pure water, dissolved oxygen and trace minerals.

The semi-permeable membrane used in the reverse osmosis water purifier using the water purification method includes a precipitation filter 2, a pretreatment carbon filter 3, a reverse osmosis filter 4, and a post treatment carbon filter 5.

In a conventional reverse osmosis water purifier, a cooling system and a heating system are installed to selectively supply cold water and hot water. A cooling system for supplying cold water is a refrigerant circuit cooling method using a compressor illustrated in FIG. 1. And, although not shown in the drawing, a method of cooling water by inserting a predetermined thermoelectric element having a function such as a cooling coil in a cold water tank is mainly used.

Looking at the configuration of the cooling system in a conventional water purifier, as shown in Figure 1, the raw water supplied from the water supply (1) sediment filter (2), pre-treatment carbon filter (3), reverse osmosis filter (4) and after-treatment carbon Filtered by a filter (5), having a separate cold water tank (6) in which the filtered purified water is accommodated, one side of the cold water tank (6) is connected to the discharge cock (7) for the extraction of cold water.

The cold water tank 6 is provided with a cooling coil 8 through which a coolant flows, and both ends of the cooling coil 8 are connected to a coolant pipe 9 which is a circulation passage of the coolant. In the refrigerant pipe (9), the compressor (10) is installed in the outlet direction of the cooling coil (8), the condenser (11) is installed in the inlet direction of the cooling coil (8), and condensed in the condenser (11) The refrigerant is expanded in a fine liquid state in the evaporator 13 formed of a capillary tube and then evaporated in the cooling coil 8 to cool the cold water tank 6.

By the way, the water purifier for cooling by using a refrigerant as in the prior art is essentially provided with a compressor 10, there is a problem that noise is generated due to the drive of the compressor (10).

In addition, the water purifier according to the prior art should be provided with the cold water tank (6) to store the filtered purified water, and because the purified water is kept in a stagnant state inside the cooling tank (6) inside the cooling tank (6) There is a problem that water moss and the like is generated to contaminate the purified water.

It is an object of the present invention to provide a water purifier using a thermoelectric element in which operating noise does not occur due to cooling and heating of purified water using a thermoelectric element.

One side of the present invention is a water purifier using a thermoelectric element, the filter module for filtering water to generate purified water; A cold / hot module 60 for cooling a part of the purified water purified by the filter module 50 by a thermoelectric phenomenon and simultaneously heating the rest of the purified water by a thermoelectric phenomenon; A circulation module 70 for circulating the purified water to the filter module 50 and the cold / hot module 60; It includes a discharge pipe 80 for discharging the purified water of the circulation module 70 to the discharge cock 100, the cold module 60 is a cooling effect is generated on one side by the applied current and on the other side A plurality of thermoelectric semiconductors 62 composed of thermoelectric elements having a heating effect; A cooling pad 64 disposed in close contact between the thermoelectric semiconductors 62 and cooling the purified water purified by the filter module 50; A water purifier using a thermoelectric element is disposed in close contact with each outer surface of the thermoelectric semiconductor 62 and includes a heating pad 66 for heating purified water purified by the filter module 50.

Here, the circulation module 70 is connected to the cooling pad 64, the cooling circulation module 78 for circulating the cooled purified water; Connected to the heating pad 66 may include a heating circulation module 79 for circulating the heated purified water.

In addition, the circulation module 70, the supply pipe 71 for supplying purified water purified by the filter module 50 to the cold and hot module 60; A circulation pipe (73) connecting the supply pipe (71) and the cold / hot module (60) to circulate purified water cooled or cooled in the cold / hot module (60); A three-way valve (74) installed in the supply pipe (71) and connected to the circulation pipe (73) to change the flow path of the purified water into any one of the cold / hot module (60) and the circulation pipe (73); It may be installed in the circulation pipe 73 may include a circulation pump 72 for circulating the purified water in one direction in the circulation pipe 73.

In addition, the cooling pad 64 is a pad body (65a) for providing a flow path of the purified water; An inlet (65b) into which the purified water from the filter module (50) flows into the pad body (65a); It may include an outlet (65c) for discharging the purified water of the pad body (65a).

In the water purifier using a thermoelectric device according to another aspect of the present invention, the filter module for filtering water to generate purified water; A cold / hot module 60 for cooling a part of the purified water purified by the filter module 50 by a thermoelectric phenomenon and simultaneously heating the rest of the purified water by a thermoelectric phenomenon; A circulation module 70 for circulating the purified water to the filter module 50 and the cold / hot module 60; It includes a discharge pipe 80 for discharging the purified water of the cold module 60 to the discharge cock 100, the cold module 60 is a cooling effect is generated on one side by the applied current and on the other side A plurality of thermoelectric semiconductors 62 composed of thermoelectric elements having a heating effect; A cooling pad 64 disposed in close contact between the thermoelectric semiconductors 62 and cooling the purified water purified by the filter module 50; A water purifier using a thermoelectric element is disposed in close contact with each outer surface of the thermoelectric semiconductor 62 and includes a heating pad 66 for heating purified water purified by the filter module 50.

Wherein the circulation module 70 is a supply pipe 71 for supplying purified water purified by the filter module 50 to the cold and hot module 60; A circulation pipe (73) connecting the supply pipe (71) and the cold / hot module (60) to circulate purified water cooled or cooled in the cold / hot module (60); A three-way valve (74) installed in the supply pipe (71) and connected to the circulation pipe (73) to change the flow path of the purified water into any one of the cold / hot module (60) and the circulation pipe (73); A circulation pump 72 installed in the circulation pipe 73 to circulate the purified water in one direction in the circulation pipe 73; The cold and hot module 60, the discharge pipe 80 and the circulation pipe 73 is connected, and the temperature controlled constant of the cold and hot module 60 when opening the discharge cock 100, the discharge cock 100 It may include a three-way valve 77 to move directly to).

Since the water purifier using the thermoelectric device according to the present invention is temperature controlled by the cooling pad 64 and the heating pad 66 at the same time, it is possible to minimize the energy loss generated during the operation of the thermoelectric semiconductor 62. In addition, since the cooling pad 64 is cooled by the current applied to the thermoelectric semiconductor 62, there is an effect that operation noise is not generated.

In addition, the water purifier using the thermoelectric device according to the present invention is because the thermoelectric semiconductor 62, the cooling pad 64, and the heating pad 66 are manufactured integrally with the cold / hot module 60, thereby improving the energy efficiency of the thermoelectric semiconductor 62. Not only can maximize, but also easy to install and disassemble due to the integrated cold and hot module 60.

In addition, the water purifier using the thermoelectric element according to the present invention has the effect of suppressing the generation of water moss because the purified purified water is circulated by the circulation module 70.

1 is a block diagram of a water purifier according to the prior art
2 is a block diagram of a water purifier according to an embodiment of the present invention.
Figure 3 is a schematic front view of the cold and hot module shown in Figure 2
4 is a cross-sectional view of the pad body shown in FIG.
5 is a block diagram of a water purifier according to another embodiment of the present invention.

2 is a configuration diagram of a water purifier according to an embodiment of the present invention, FIG. 3 is a schematic front view of the cold / hot module shown in FIG. 2, and FIG. 4 is a cross-sectional view of the pad body shown in FIG. 3.

As shown, the water purifier according to the present embodiment filters the water to generate purified water, and cools some of the purified water purified by the filter module 50 by a thermoelectric phenomenon and at the same time among the purified water. The cold and hot module 60 for heating the rest by the thermoelectric phenomenon, the circulation module 70 for circulating the purified water to the filter module 50 and the cold and hot module 60, and the purified water of the circulation module 70 A discharge pipe 80 for discharging to the discharge cock 100 is included.

The filter module 50 may be used in combination with a variety of filters, in this embodiment includes a precipitating filter 52, a pre-treatment carbon filter 53, a reverse osmosis filter 54 and a post-treatment carbon filter 55 .

Here, the technical configuration and operation of the precipitation filter 52, the pretreatment carbon filter 53, the reverse osmosis filter 54, and the post treatment carbon filter 55 constituting the filter module 50 are generally true to those skilled in the art. Omit the description.

The cold / hot module 60 has a cooling effect on one side and a heating effect on the other side due to the applied current, and between the plurality of thermoconductors 62 composed of thermoelectric elements and the thermoconductor 62. Cooling pads 64 disposed in close contact with each other to cool purified water purified by the filter module 50 and purified water from the filter module 50 may be disposed in close contact with each outer surface of the thermoelectric semiconductor 62. And a heating pad 66 for heating.

The thermoelectric semiconductor 62 is composed of a thermoelectric element operated by using the Peltier effect, and the thermoelectric element is electrically connected in parallel with n and p type thermo couples in series. It is composed of one module type, and when DC current flows, a temperature difference occurs on both sides of the module by thermoelectric effect, one side is cooled and the other side is heated. The thermoelectric semiconductor is an environmentally friendly cooling method that replaces the existing cooling method that operates a compressor to circulate a refrigerant. The thermoelectric semiconductor can simultaneously cool and heat an object at room temperature to -30 ° C to + 180 ° C by an applied current. It is suitable for the water purifier which uses hot water and cold water simultaneously. Herein, the structure and operation of the thermoelectric semiconductor 62 are general techniques to those skilled in the art, and thus a detailed description thereof will be omitted.

In this case, two thermoelectric semiconductors 62 are used, and cooling is performed between the plurality of thermoelectric semiconductors 62. Here, in the present embodiment, two thermoelectric semiconductors 62 are used, but may be extended to four or six, depending on the amount of purified water, and the cooling pad 64 and the heating pad 66 may also be used. It can be changed according to the amount of purified water.

The cooling pads 64 are disposed in close contact between the thermoelectric semiconductors 62 and are cooled by the thermoelectric semiconductors 62 disposed on both sides.

In addition, the heating pad 66 is disposed on the opposite side of the cooling pad 64 with respect to the thermoelectric semiconductor 62 and is heated through one thermoelectric semiconductor 62.

Thus, when a current is applied to the thermoconductor 62, the cooling pad 64 is cooled by cooling on one side of the thermoconductor 62, and the heating pad 66 is heated by heating on the other side. The two heating pads 66, one cooling pad 64, and two thermoelectric semiconductors 62 are integrally modularized.

Since the heating pad 66 and the cooling pad 64 have the same structure, the cooling pad 64 will be described as an example in this embodiment.

The cooling pad 64 may include a pad body 65a which provides a flow path of the purified water, an inlet 65b through which the purified water purified by the filter module 50 flows into the pad body 65a, and the pad. And an outlet 65c for discharging the purified water of the body 65a.

The inlet 65b and the outlet 65c are formed in the pad body 65a, a plurality of partitions 65d are formed therein, and a flow path through which the purified water moves is formed by the partitions 65d. Here, the pad body 65a is formed of an aluminum material in this embodiment, and unlike the present embodiment, another metal material having high thermal conductivity may be used.

The circulation module 70 is for circulating the purified water inside the water purifier while the purified water cooled or heated by the cold / heat module 60 is not used, and the purified water module purified by the filter module 50 may be purified. A supply pipe 71 to be supplied to the 60, a circulation pipe 73 connecting the supply pipe 71 and the pad body 65a to circulate purified water cooled or cooled in the pad body 65a; A three-way valve (74) installed in the supply pipe (71) and connected to the circulation pipe (73), the pad body (65a) and one of the circulation pipes (73) to change the flow path of the purified water; Is installed in the circulation pipe 73 includes a circulation pump 72 for circulating the purified water in one direction in the circulation pipe (73).

The three-way valve 74 branches the supply pipe 71 and connects the circulation pipe 73. In this case, when there is no discharge of purified water from the discharge cock 100, the three-way valve 74 opens a flow path toward the circulation pipe 73 so that the purified water is circulated, and the purified water is discharged from the discharge cock 100. In this case, the purified water is supplied by opening a flow path toward the cold / hot module 60.

The circulation pump 72 may flow the purified water in the forward and reverse directions, and in this embodiment, after the purified water flows through the circulation pipe 73 to the cold / hot module 60, the three-way valve 74 is opened. Flowing the purified water to circulate through it.

On the other hand, in the present embodiment, the temperature sensor 75 installed in the circulation pipe 73 and the temperature controller 76 for receiving data from the temperature sensor 75 to control the temperature of the cold module 60 is further. Include.

In addition, the discharge pipe 80 connects the discharge cock 100 and the circulation pipe 73, and when the discharge cock 100 is opened, the temperature inside the circulation pipe 73 in which the temperature is adjusted is the The discharge cock 100 is moved to the discharge cock 100 through the discharge pipe 80.

On the other hand, the circulation module 70 is connected to the cooling pad 64, the cooling circulation module 78 for circulating the cooled purified water, and the heating circulation module connected to the heating pad 66 for circulating the heated purified water It consists of 79.

In addition, the cooling circulation module 78 of the circulation module 70 is insulated using a heat insulating material such as urethane foam, and the heating circulation module 79 is not insulated for stabilizing connection elements of the thermoelectric semiconductor 62. By not doing so, it is possible to extend the life of the thermoconductor 62 and to improve stability in operation.

Hereinafter, the operation of the water purifier using the thermoelectric device according to the present embodiment will be described in more detail with reference to the accompanying drawings.

First, the purified water purified by the filter module 50 is supplied to the cold / hot module 60 through the supply pipe 71 and the three-way valve 74, the purified water (cooling pad of the cold module 60) ( 64) or the heating pad 66.

Here, the purified water is supplied only to the cooling circulation module 78 or the heating circulation module 79 which is lacking in purified water.

Thereafter, the controller (not shown) of the water purifier applies power to the thermoelectric semiconductor 62 to cool or heat the cooling pad 64 or the heating pad 66, and the cooled cooling pad 64 or the The heating pad 66 cools or heats the purified water flowing inside by the heat conduction.

Here, since the thermoelectric semiconductor 62 is cooled and heated at both sides, even if fresh water is supplied only to the cooling pad 64, heat generated from the opposite side heats the heating pad 66 to generate waste heat. Minimize. That is, even if a new purified water is supplied to only one of the cooling circulation module 78 and the heating circulation module 79 so that the thermoelectric conductor 62 is operated, an arrangement structure of the cooling pad 64 or the heating pad 66 is provided. By the other circulation module 70 is also temperature control, by this structure can reduce the energy used for temperature control of the purified water circulated in the circulation module 70.

Thereafter, the purified water temperature controlled in the cold / hot module 60 is circulated through the cooling circulation module 78 or the heating circulation module 79, and when the discharge cock 100 is opened, the cooling circulation module 78 In one of the heating circulation module 79 or the temperature-controlled purified water is discharged.

In this case, when the discharge cock 100 is opened, the control unit stops the operation of the circulation pump 72 and the three-way valve to supply purified water from the supply pipe 71 to the cold / hot module 60. When the flow path of the 74 is adjusted, and the discharge cock 100 is closed, the flow path of the three-way valve 74 is switched to the cooling circulation module 78 or the heating circulation module 79 and the circulation pump 72. ) Is activated.

On the other hand, in the present embodiment has been described by taking the water direct type as an example, it can also be configured as a non-pipe type, such as a tabletop type.

5 is a block diagram of a water purifier according to another embodiment of the present invention.

As shown, unlike the water purifier according to the present embodiment, a three-way valve 77 is disposed between the cold / hot module 60 and the discharge pipe 80, and the three-way valve 77 is disposed. It is configured to be connected with the circulation pipe 73 through.

As such, when the cooling circulation module 78 and the heating circulation module 79 are configured, when the discharge cock 100 is opened, the purified water temperature controlled by the cold / hot module 60 may control the three-way valve 77. Directly discharged to the discharge coke 100, through which the heat loss of the temperature-controlled purified water is minimized.

That is, when the discharge cock 100 is opened, the three-way valve 77 disposed below the cold / hot module 60 opens the flow path toward the discharge cock 100 to open the cooling pad 64 or the heating pad. Cold water or hot water temperature controlled at 66 is flowed directly to the discharge cock (100).

After the discharge cock 100 is closed, the flow path of each of the three-way valve 74, 77 in the direction in which the cooling circulation module 78 or the heating circulation module 79 is circulated.

Since the rest of the configuration is similar to the above embodiment, a detailed description thereof will be omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, This is possible.

50: filter module 52: sedimentation filter
53: pretreated carbon filter 54: reverse osmosis filter
55: post-treatment carbon filter 60: cold temperature module
62: thermoelectric semiconductor 64: cooling pad
65a: pad body 65b: inlet
65c: outlet 65d: bulkhead
66: heating pad 70: circulation module
71: supply piping 72: circulation pump
73: circulation piping 74: three-way valve
76: temperature controller 77: 3-way valve
78: cooling circulation module 79: heating circulation module
80: discharge piping

Claims (6)

In a water purifier using a thermoelectric element,
A filter module 50 for filtering water to generate purified water; A cold / hot module 60 for cooling a part of the purified water purified by the filter module 50 by a thermoelectric phenomenon and simultaneously heating the rest of the purified water by a thermoelectric phenomenon; A circulation module 70 for circulating the purified water to the filter module 50 and the cold / hot module 60; It includes a discharge pipe 80 for discharging the purified water of the circulation module 70 to the discharge cock 100,
The cold module 60 is
A plurality of thermoelectric semiconductors 62 each including a thermoelectric element having a cooling effect on one side and a heating effect on the other side by an applied current;
A cooling pad 64 disposed in close contact between the thermoelectric semiconductors 62 and cooling the purified water purified by the filter module 50;
The water purifier using a thermoelectric element is disposed in close contact with each outer surface of the thermoelectric semiconductor (62) and comprises a heating pad (66) for heating the purified water purified by the filter module (50).
The method according to claim 1,
The circulation module 70
A cooling circulation module 78 connected to the cooling pad 64 to circulate the cooled purified water;
A water purifier using a thermoelectric element including a heating circulation module (79) connected to the heating pad (66) to circulate the heated purified water.
The method according to claim 1,
The circulation module 70
A supply pipe (71) for supplying purified water purified by the filter module (50) to the cold / hot module (60);
A circulation pipe (73) connecting the supply pipe (71) and the cold / hot module (60) to circulate purified water cooled or cooled in the cold / hot module (60);
A three-way valve (74) installed in the supply pipe (71) and connected to the circulation pipe (73) to change the flow path of the purified water into any one of the cold / hot module (60) and the circulation pipe (73);
The water purifier using the thermoelectric element is installed in the circulation pipe (73) including a circulation pump (72) for circulating the purified water in the circulation pipe 73 in one direction.
The method according to claim 1,
The cooling pad 64 is
A pad body (65a) for providing the purified water path;
An inlet (65b) into which the purified water from the filter module (50) flows into the pad body (65a);
Water purifier using a thermoelectric element comprising an outlet (65c) for discharging the purified water of the pad body (65a).
In a water purifier using a thermoelectric element,
A filter module 50 for filtering water to generate purified water; A cold / hot module 60 for cooling a part of the purified water purified by the filter module 50 by a thermoelectric phenomenon and simultaneously heating the rest of the purified water by a thermoelectric phenomenon; A circulation module 70 for circulating the purified water to the filter module 50 and the cold / hot module 60; It includes a discharge pipe 80 for discharging the purified water of the cold module 60 to the discharge cock 100,
The cold module 60 is
A plurality of thermoelectric semiconductors 62 each including a thermoelectric element having a cooling effect on one side and a heating effect on the other side by an applied current;
A cooling pad 64 disposed in close contact between the thermoelectric semiconductors 62 and cooling the purified water purified by the filter module 50;
The water purifier using a thermoelectric element is disposed in close contact with each outer surface of the thermoelectric semiconductor (62) and comprises a heating pad (66) for heating the purified water purified by the filter module (50).
The method according to claim 5,
The circulation module 70
A supply pipe (71) for supplying purified water purified by the filter module (50) to the cold / hot module (60);
A circulation pipe (73) connecting the supply pipe (71) and the cold / hot module (60) to circulate purified water cooled or cooled in the cold / hot module (60);
A three-way valve (74) installed in the supply pipe (71) and connected to the circulation pipe (73) to change the flow path of the purified water into any one of the cold / hot module (60) and the circulation pipe (73);
A circulation pump 72 installed in the circulation pipe 73 to circulate the purified water in one direction in the circulation pipe 73;
The cold / hot module 60, the discharge pipe 80, and the circulation pipe 73 are connected to each other. Water purifier using a thermoelectric element including a three-way valve (77) to move directly to).

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