KR101094804B1 - Water purifier - Google Patents

Abstract

The present invention relates to a water purifier, and more particularly, to a water purifier capable of preventing contamination and recontamination of water. Water purifier according to the present invention, the heat storage tank accommodates the heat storage material therein; A heat storage heater for heating the heat storage material of the heat storage tank; A water supply unit installed to pass through the heat storage tank, selectively supplying water, and allowing water passing through the heat storage tank to exchange heat with the heat storage material; And a cooling device for cooling the heat storage material of the heat storage tank. According to the present invention, water contamination and recontamination can be prevented.

Water heater, heat storage tank

Description

Water Purifier {WATER PURIFIER}

The present invention relates to a water purifier.

In general, water purifier is a device to filter the heavy metals or foreign substances contained in the water to drink clean water.

The water purifier is provided with a water purification tank for storing the water filtered by the filter, the cold water tank and hot water tank is connected to the purified water tank by a pipe or a hose. The cold water tank is provided with a cooling device for cooling the filtered water. A heating device for heating the filtered water is disposed inside the hot water tank. Cold water and hot water are stored in the cold water tank and the hot water tank.

However, in the conventional water purifier, when the purified hot water is stored in the hot water tank and the purified water tank for a long time, contamination of the hot water of the hot water tank and the cold water of the cold water tank is caused by air contact.

In addition, the hot water tank and the cold water tank is difficult to clean the inside due to the sealed structure, when the cold water tank other than the hot water tank is used for a long time as the water is stuck in the hot water and the hot water accumulated in the hot water tank, Could be contaminated.

In order to solve the above problems, it is an object of the present invention to provide a water purifier that can prevent contamination and recontamination of hot or cold water.

Water purifier according to the present invention for achieving the above object, the heat storage tank accommodating a heat storage material therein; A heat storage heater for heating the heat storage material of the heat storage tank; A water supply unit installed to pass through the heat storage tank, selectively supplying water, and allowing water passing through the heat storage tank to exchange heat with the heat storage material; And a cooling device for cooling the heat storage material of the heat storage tank.

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The cooling device, the compressor for compressing the refrigerant; A condenser into which the refrigerant discharged from the compressor is introduced; An expansion unit to expand the refrigerant discharged from the condenser; And an evaporator for allowing the refrigerant expanded in the expansion unit to flow to cool the heat storage material of the heat storage tank.

The evaporator may be installed to be spaced apart from the water supply.

It may further include a heating heater coupled to the heat storage tank discharge side of the water supply unit for heating the water discharged from the heat storage tank.

The heating heater may be installed to be in contact with the portion via the heat storage tank of the water supply unit.

The heating heater may have a larger heat generation capacity than the heat storage heater.

The heat storage material may be water, antifreeze, brine, sand, concrete or magnesium material.

The water supply unit, the tube through which water flows; And it may include a valve for opening and closing the flow path of the tube.

The portion passing through the heat storage tank of the tube may be formed in a spiral or zigzag bent shape.

According to the present invention, it is possible to prevent contamination or re-contamination of hot and cold water, to drink hygienic hot water, and to reduce power consumption.

It will be described with respect to specific embodiments of the water purifier according to the present invention for achieving the above object.

1 is a schematic view showing a first embodiment of a water purifier according to the present invention.

Referring to FIG. 1, the water purifier includes a filter 10 for filtering heavy metals and foreign substances contained in supplied water. The filter 10 is connected to the water supply unit 20. Instead of the filter, a purified water tank may be disposed in which filtered water is stored.

The water supply unit 20 includes a tube 21 through which water flows, and a valve 25 that opens and closes a flow path of the tube 21. The tube 21 of the water supply unit 20 is installed to pass through the heat storage tank 30, and a cock (not shown) is connected to an end of the tube 21.

At this time, the portion 23 via the heat storage tank of the tube 21 may be formed spirally so as to increase the heat exchange area with the heat storage tank 30. Of course, the heat storage tank diesel portion 23 of the tube 21 may be formed to be bent in a zigzag. In FIG. 1, the tube 21 is helically bent. Here, the length of the bent portion of the tube 21 may be appropriately changed according to the heat exchange performance with the heat storage material 31 and the target temperature of the water heat exchanged with the heat storage material 31.

The heat storage material 31 is accommodated in the heat storage tank 30. As the heat storage material 31, a solution such as water, an antifreezing liquid, and brine, and a solid material such as sand, concrete, and magnesium may be applied. The antifreeze includes calcium chloride solution, magnesium chloride solution, ethylene glycol solution, ethyl alcohol and the like.

The heat storage material 31 is a material having an excellent ability to store heat because it has a high specific heat. This heat storage material 31 may be appropriately selected according to the temperature of the water heat exchanged due to the heat storage.

The heat storage heater 40 for heating the heat storage material 31 to a preset heat storage temperature is disposed in the heat storage tank 30. As the heat storage heater 40, a sheath heater having a form in which a resistance coil is accommodated in a pipe having excellent thermal conductivity may be applied. The sheath heater may be prevented from shorting by the heat storage material.

Since the heat storage heater 40 is stopped after the heat storage material 31 is heated to a predetermined temperature in the controller 60, the heat storage material 31 is maintained at a substantially heat storage temperature. In addition, the heat storage heater 40 may increase the amount of heat generated when hot water is discharged to the outside of the heat storage tank 30 through the water supply unit 20. Here, the calorific value and length of the heat storage heater 40 may be appropriately designed according to the preset temperature of the hot water.

The heat storage tank 30 may further include a temperature sensor 37 to measure the temperature of the heat storage material 31.

The valve 25 and the heat storage heater 40 are electrically connected to the power supply unit 50, and the power supply unit 50 is electrically connected to the control unit 60. According to the command of the controller 60, the power supply unit 50 supplies power to the configuration. In addition, the temperature sensor 37 is electrically connected to the controller 60.

An operation and a control method of the first embodiment of the water purifier according to the present invention configured as described above will be described.

The controller 60 closes the valve 25 to block water from flowing through the tube 21.

When the controller 60 controls to supply power to the heat storage heater 40, the heat storage material 31 is heated as the heat storage heater 40 is operated. At this time, the temperature sensor 37 senses the temperature of the heat storage material 31, and transmits the information about the detected temperature to the controller 60.

The controller 60 determines whether the heat storage material 31 has reached a preset temperature based on the information in the temperature sensor 37.

If it is determined that the heat storage material 31 has not reached the preset temperature, the heat storage heater 40 is continuously operated. At this time, the valve 25 is still in the closed state.

In addition, when it is determined that the heat storage material 31 has reached a predetermined temperature, the heat storage heater 40 is turned off and stopped. At this time, the valve 25 is still closed.

As the heat storage heater 40 is turned on / off as described above, the heat storage material 31 maintains a constant temperature range.

When the user selects hot water through an operation unit (not shown), the control unit 60 opens the valve 25 to allow the water to flow in the tube 21. The water of the tube 21 is discharged from the heat storage tank 30 after heat exchange with the heat storage material (31).

At this time, since the heat storage tank diesel portion 23 of the tube 21 is bent in a spiral or zigzag form, the time and heat exchange area of the water heat exchange with the heat storage material 31 is increased. Thus, the water is sufficiently heat exchanged with the heat storage material 31 to reach a target temperature (eg, approximately 60 to 95 ° C.). In this case, the target temperature may be appropriately changed according to the length of the portion 23 via the heat storage tank 30 of the tube 21 and the heat generation capacity of the heat storage heater 40. In addition, the hot water discharged from the heat storage tank 40 is discharged to the cock (not shown).

When the user releases the pressure of the cock, the controller 60 determines that hot water selection is released and controls the valve 25 to be closed.

As described above, only when the hot water is selected in a state in which the heat storage material 31 is preheated in the heat storage tank 30, water is flowed into the tube 21, so that a separate hot water tank is used to store the hot water. No need to install

Therefore, since the hot water is heated only when necessary, it is possible to prevent the hot water from being stored for a long time or contaminated as the hot water comes into contact with the air. In addition, since the hot water tank is not installed, hot water can be prevented from being recontaminated. In addition, since only the required amount of hot water needs to be instantaneously heated without heating all the water contained in the hot water tank, power consumption may be significantly reduced.

Next, a second embodiment of the water purifier according to the present invention will be described.

The second embodiment of the water purifier has a technical feature in that a cooling device 70 for cooling the heat storage material is further included as compared with the first embodiment. Therefore, in the following, the same components as those in the first embodiment will be given the same reference number and the description thereof will be omitted.

2 is a schematic view showing a second embodiment of the water purifier according to the present invention.

Referring to FIG. 2, the heat storage tank of the water purifier may further include a cooling device 70 for cooling the heat storage material. The cooling device 70 cools the heat storage material by circulating a refrigerant.

The cooling device 70 is composed of a compressor 71, a condenser 72, an expansion unit 73 and the evaporator 74 is sequentially connected by a refrigerant pipe. The compressor 71 compresses the refrigerant to high temperature and high pressure, and the condenser 72 condenses the compressed high temperature refrigerant. The expansion unit 73 expands the condensed refrigerant to low temperature and low pressure. The evaporator 74 allows the expanded low temperature low pressure refrigerant to exchange heat with the heat storage material 31.

The compressor 71 may be driven at a constant speed so that a constant speed compressor having a constant cooling capacity or an inverter compressor for varying the cooling capacity as the driving frequency is changed may be applied.

In addition, the expansion unit 73 may be a capillary tube (capillary tube) for expanding the refrigerant by a capillary phenomenon, or a solenoid valve (solenoid valve) that can change the expansion capacity by adjusting the opening degree may be applied. .

In this case, the evaporator 74 may be formed of a refrigerant pipe spirally wound or zigzag to improve heat exchange capacity with the heat storage material. In addition, a heat exchange fin (not shown) may be coupled or integrally formed on the outer surface of the refrigerant pipe of the evaporator 74 to increase the heat exchange area with the heat storage material 31. In addition, the refrigerant pipe of the evaporator 74 may be installed to surround the heat storage tank 30 or may be accommodated in the heat storage tank 30.

There may be a case where the evaporator 74 is abnormally operated and abnormally operated at a temperature below zero. At this time, when the evaporator 74 is in contact with the tube portion 23 via the heat storage tank of the tube, water flowing through the tube portion 23 may freeze, thereby blocking the flow path of the tube. As such, the evaporator 74 may be installed to be spaced apart from the tube part 23 via the heat storage tank so as to prevent freezing of the water in the tube part 23.

The heat storage heater 40 may be disposed in contact with the tube portion 23 via the heat storage tank. This is to allow the ice of the portion 23 via the heat storage tank to be quickly melted when water is frozen in the tube portion 23 via the heat storage tank.

In addition, the heat storage heater 40 may be installed to be spaced apart from the tube portion 23 via the heat storage tank.

An operation and a control method of the second embodiment of the present invention configured as described above will be described.

The user can extract the hot water or cold water instantaneously according to the season or free choice. The cooling device 70 does not operate when the hot water is selected, and the heat storage heater 40 does not operate when the cold water is selected.

When the user selects hot water through an operation unit (not shown), the operation of discharging hot water from the hot water heater is the same as in the first embodiment, and thus the description of the hot water discharge process will be omitted.

When the user selects the cold water through the operation unit, the refrigerant compressed by the compressor 71 is circulated along the condenser 72, the expansion unit 73 and the evaporator 74. At this time, the cold air of the evaporator 74 cools the heat storage material 31. At this time, the temperature sensor 37 senses the temperature of the heat storage material 31, and transmits the information about the detected temperature to the controller 60.

The controller 60 determines whether the heat storage material 31 has reached a preset temperature based on the information in the temperature sensor 37.

If it is determined that the heat storage material 31 has not reached the preset temperature, the cooling device 70 is continuously operated. At this time, the valve 25 is still in the closed state.

In addition, when it is determined that the heat storage material 31 has reached a preset temperature, the cooling device 70 is cut off and stopped. At this time, the valve 25 is still closed.

As the cooling device 70 is turned on / off in this manner, the heat storage material 31 is maintained at a constant temperature range.

When the user presses the cock, the controller 60 opens the valve 25 to allow water to flow in the tube 21. The water in the tube 21 is cooled while being heat-exchanged with the heat storage material 31 and then discharged from the heat storage tank 30.

At this time, since the heat storage tank diesel portion 23 of the tube 21 is bent in a spiral or zigzag form, the time and heat exchange area of the water heat exchange with the heat storage material 31 is increased. Thus, the water is sufficiently heat exchanged with the heat storage material 31 to reach a target temperature (eg, approximately 3-15 ° C.). In this case, the target temperature may be appropriately changed according to the length of the portion 23 via the heat storage tank 30 of the tube 21 and the cooling capacity of the evaporator 74. In addition, the hot water discharged from the heat storage tank 40 is discharged to the cock (not shown).

When the user releases pressurization of the cock, the controller 60 determines that the cold water selection is released and controls the valve 25 to be closed.

Since only the cold water is selected in the state in which the heat storage material 31 is pre-cooled in the heat storage tank 30 as described above, water may be flowed into the tube 21 so that a separate cold water tank may be installed to store cold water. no need.

Therefore, since the cold water is heated only when necessary, the cold water can be prevented from being contaminated as the cold water is stored for a long time or the cold water comes into contact with the air. In addition, since the cold water tank is not installed, cold water can be prevented from being recontaminated. In addition, since only the required amount of cold water needs to be instantaneously heated without heating all the water contained in the cold water tank, power consumption may be significantly reduced.

The above-mentioned prevention of contamination and re-contamination of cold water is the same when selecting hot water, and thus description thereof will be omitted.

On the other hand, as the evaporator 74 is abnormally operated, the heat storage material 31 may be cooled to a temperature near minus zero. At this time, water may freeze in the portion 23 passing through the heat storage tank of the tube.

When the controller 60 determines that the water in the tube part 23 freezes so that the water is not discharged through the cock, the controller supplies power to the heat storage heater 40 for a predetermined time, thereby providing the evaporator 74. ) Can be heated. Thus, the ice in the tube portion 23 quickly melts.

Next, a third embodiment of the water purifier according to the present invention will be described.

The third embodiment of the water purifier has a technical feature in that it further includes a heating heater 80 for heating the water discharged from the heat storage tank compared to the second embodiment. Therefore, in the following, the same components as those in the second embodiment will be given the same reference number and the description thereof will be omitted.

3 is a schematic view showing a third embodiment of the water purifier according to the present invention.

Referring to FIG. 3, a heating heater 80 may be further included in the discharge side of the heat storage tank 30 of the water supply unit 20. In this case, the heating heater 80 may be disposed inside the tube 21 of the water supply unit 20 or may be installed to surround the outer surface of the tube 21.

An operation and a control method of the third embodiment according to the present invention configured as described above will be described.

First, when the cold water is selected by the user and the cooling device 70 is operated, the heating heater 80 may not operate together with the heat storage heater 40.

As the heat storage heater 40 is turned on / off, the heat storage material 31 maintains a constant temperature range.

When the user presses the cock to select hot water, the controller 60 opens the valve 25 to allow water to flow in the tube 21. The water of the tube 21 is discharged from the heat storage tank 30 after heat exchange with the heat storage material (31). At this time, since the heat storage tank diesel portion 23 of the tube 21 is bent in a spiral or zigzag form, the time and heat exchange area of the water heat exchange with the heat storage material 31 is increased. Therefore, the water is sufficiently heat exchanged with the heat storage material 31 to reach a target temperature (for example, about 60 to 65 ℃).

In addition, the heating heater 80 is operated to heat the water discharged from the heat storage tank 30 to a predetermined temperature. In this case, the temperature discharged from the heating heater 80 may reach a predetermined temperature (for example, approximately 85 ~ 95 ℃). Hot water discharged from the heater 80 is discharged to the cock (not shown).

When the user releases pressurization of the cock, the controller 60 determines that hot water selection is released. In addition, the controller 60 controls the valve 25 to be closed and the heating heater 80 is stopped.

As described above, since the water is heated by the heat storage tank 30 and the heating heater 80 over a second time, it is not necessary to install a separate hot water tank to store hot water. Therefore, since the hot water is heated only when necessary, it is possible to prevent the hot water from being stored for a long time or contaminated as the hot water comes into contact with the air. In addition, since the hot water tank is not installed, hot water can be prevented from being recontaminated. In addition, since only the required amount of hot water needs to be instantaneously heated, power consumption can be significantly reduced.

In addition, since the water is heated by the heat storage tank 30 to a predetermined temperature, a heating heater 80 having a relatively low amount of heat can be applied.

Since the present invention can prevent contamination or re-contamination of hot and cold water, there is a marked applicability in industry.

1 is a schematic view showing a first embodiment of a water purifier according to the present invention.

2 is a schematic view showing a second embodiment of the water purifier according to the present invention.

3 is a schematic view showing a third embodiment of the water purifier according to the present invention.

Explanation of symbols on the main parts of the drawings

10: filter 20: water supply

21: Tube 23: via the heat storage tank of the tube

25: valve 30: heat storage tank

31: heat storage material 40: heat storage heater

40: heating heater 50: power supply

60: control unit 70: cooling unit

71: compressor 72: condenser

74: evaporator 80: heating heater

Claims (10)

A heat storage tank accommodating heat storage material therein; A heat storage heater for heating the heat storage material of the heat storage tank; A water supply unit installed to pass through the heat storage tank, selectively supplying water, and allowing water passing through the heat storage tank to exchange heat with the heat storage material; And And a cooling device for cooling the heat storage material of the heat storage tank. delete The method of claim 1, The cooling device is: A compressor for compressing the refrigerant; A condenser into which the refrigerant discharged from the compressor is introduced; An expansion unit to expand the refrigerant discharged from the condenser; And And an evaporator configured to cool the heat storage material of the heat storage tank by the introduction of the refrigerant expanded in the expansion unit. The method of claim 3, wherein The evaporator is a water purifier, characterized in that spaced apart from the water supply. The method of claim 1, And a heating heater coupled to the heat storage tank discharge side of the water supply unit to heat the water discharged from the heat storage tank. The method of claim 5, The heater is characterized in that the water heater is installed in contact with the portion via the heat storage tank. The method of claim 5, The heater is a water purifier, characterized in that the heat generation capacity is relatively larger than the heat storage heater. The method of claim 1, The heat storage material is water, antifreeze, brine, sand, concrete or magnesium purifier, characterized in that the material. The method of claim 1, The water supply unit: A tube through which water flows; And And a valve for opening and closing the flow path of the tube. The method of claim 9, Water purifier portion of the tube via the heat storage tank is formed in a spiral or zigzag bent form.

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