KR20130035544A - Water treatment apparatus - Google Patents

Abstract

PURPOSE: A water treatment apparatus is provided to be compactly manufactured by arranging a filter, a refrigerator and et cetera inside of a cooling container. CONSTITUTION: A water treatment apparatus(100) includes a cooling container(110), a refrigerator(120) and a filter(130). Source water is flowed into the cooling container. The refrigerator cools the source water flowed inside of the cooling container by being arranged inside of the cooling container. The filter filters and discharges the cooled water by being arranged inside of the cooling container. The refrigerator is an evaporator in which a refrigerant flows. The evaporator is made in a coil type. The filter is spaced apart from the evaporator inside of the evaporator. The refrigerator is a thermoelectric device module. The filter is a carbon block filter. A sterilizer is further included in the cooling container. The sterilizer is a UV lamp or a UV LED.

Description

[0001] WATER TREATMENT APPARATUS [0002]

The present invention relates to a water treatment apparatus that can be manufactured in a compact size.

In general, a water treatment apparatus is a device for filtering purified water to produce purified water. The water treatment device includes various devices such as a water purifier, a water heater, a cold water heater, and an ionizer.

The water treatment apparatus may include a filter unit for filtering raw water and a cooling tank for cooling the purified water filtered by the filter unit. An evaporator may be disposed in the cooling chill.

Korean Patent Publication No. 2007-003308 (published Jan. 5, 2007) discloses a cold water heater. The cold ionizer includes a filter unit including a plurality of filters, and a storage tank unit in which purified water filtered by the filter unit is accommodated. The storage tank unit includes a normal temperature tank, a cold water tank and a hot water tank.

Since the cold ion water heater is provided with various filters and tanks separately, the size of the cold water ionizer can be increased.

The present invention provides a water treatment apparatus which can be manufactured compactly.

According to an aspect of the present invention, a cooling vessel into which raw water is introduced; A cooler disposed inside the cooling vessel to cool the raw water introduced into the cooling vessel; And a filter disposed inside the cooling vessel to filter and discharge cold water.

The cooler may be an evaporator through which a refrigerant flows.

The evaporator may be formed in the form of a coil.

The filter may be spaced apart from the evaporator inside the evaporator.

The cooler may be a thermoelectric module.

The filter may be a carbon block filter.

A cold water flow path may be formed at the center of the filter, and a cold water discharge pipe may be connected to the cold water flow path.

The cooling vessel may further include a sterilizer.

The sterilizer may be a UV lamp or an ultraviolet LED.

According to the present invention, since a filter, a cooler, and the like are arranged inside the cooling vessel, there is an effect that the size of the water treatment device can be significantly reduced.

1 is a view showing a first embodiment of a water treatment apparatus according to the present invention.
2 is a view showing the water treatment apparatus of FIG.
3 is a view showing a second embodiment of the water treatment apparatus according to the present invention.

Hereinafter, specific embodiments of the water treatment apparatus according to the present invention will be described with reference to the drawings.

1 is a view showing a first embodiment of a water treatment apparatus according to the present invention, Figure 2 is a view showing a water treatment apparatus.

1 and 2, the water treatment device 100 may include a cooling vessel 110, a cooler 120, and a filter 130.

The cooling container 110 may be formed in a cylindrical or polygonal shape to accommodate the raw water. In this case, the cooling container 110 may be surrounded by a heat insulating member (not shown) to minimize the heat exchange with the outside air.

The cooling vessel 110 may be connected to the raw water inlet pipe 111. The raw water inlet pipe 111 may be connected to the raw water tank or water pipe. When the raw water inlet pipe 111 is directly connected to the water pipe can reduce the size of the water treatment device 100 significantly. This raw water inlet pipe 111 supplies a constant raw water to the cooling vessel (110). At this time, the inside of the cooling vessel 110 may be maintained a constant pressure by the supply pressure of the raw water.

The cooler 120 is disposed inside the cooling vessel 110 to cool the raw water introduced into the cooling vessel 110. The cooler 120 may be an evaporator 127 that cools raw water by flowing a refrigerant. The evaporator 127 may be formed in a coil shape and disposed along a circumference of the cooling vessel 110. Since the evaporator 127 is formed in the form of a coil, it is possible to increase the thermal contact time and the thermal contact area with the raw water of the cooling vessel 110.

The evaporator 127 may form a closed circuit with the compressor 121, the condenser 123, and the expansion valve 125. The refrigerant compressed in the compressor 121 is condensed in the condenser 123, and the refrigerant condensed in the condenser 123 is expanded in the expansion valve 125 and then flows into the evaporator 127. The refrigerant of the evaporator 127 may cool the evaporator 127 to cool the raw water. The refrigerant in the evaporator 127 repeats the closed circulation flowing into the compressor 121.

The evaporator 127 may be installed to be spaced apart from the inner surface of the cooling vessel 110. Therefore, the cold air of the evaporator 127 may be made to be in maximum contact with the raw water without directly cooling the cooling vessel 110.

The filter 130 may be disposed inside the cooling container 110 to filter and discharge cold water. The filter 130 may be disposed inside the evaporator 127 in the form of a coil. In this case, the outer surface of the filter 130 may be spaced apart from the evaporator 127 to allow the cold water to smoothly flow into the filter 130. That is, the evaporator 127 may not be in contact with the filter 130 to prevent the path of the cold water from being partially blocked by the filter 130.

The filter 130 may be a carbon block filter 130. The carbon block having a particle size of about 1-100 μm may be accommodated in the carbon block filter 130.

When a constant water pressure is formed in the cooling vessel 110, the cold water of the cooling vessel 110 is filtered while being introduced into the carbon block filter 130. In addition, the carbon block filter 130 has a characteristic of stably filtering water at a temperature of 3-50 ℃. Therefore, the carbon block filter 130 may sufficiently filter the cold water when water pressure is formed inside the cooling vessel 110.

The filter 130 may be applied in addition to the carbon block filter 130 as long as it can filter the water by forming a pressure inside the cooling vessel 110.

The cold water passage 135 may be formed inside the filter 130. The cold water discharge pipe 113 may be connected to the cold water passage 135. The cold water discharge pipe 113 may pass through the upper side of the cooling vessel 110 may be connected to the cold water extraction coke.

The filter 130 is filtered while the cold water is introduced through the bottom surface or the outer surface. Cold water filtered while passing through the filter 130 may be introduced into the cold water flow path 135. Cold water of the cold water passage 135 may be discharged to the cold water extraction coke through the cold water discharge pipe 113.

The filter 130 may be formed in a cylindrical shape. Since the filter 130 is formed in a cylindrical shape, the cold water may be filtered while permeating through the outer side surfaces. Thus, the filtration efficiency of cold water can be increased.

The cooling vessel 110 may further include a sterilizer 140 to sterilize microorganisms contained in raw or cold water. As the sterilizer 140, a UV lamp or an ultraviolet LED may be applied. In this case, the UV lamp or ultraviolet LED may be installed in contact with or without contact with raw or cold water. Such UV lamps or ultraviolet LEDs may be indirectly cooled by cold air generated in the cooler 120.

The operation of the water treatment device according to the present invention configured as described above will be described.

Raw water is supplied to the cooling vessel 110 by the raw water inlet pipe 111. In this case, a constant water pressure may be formed in the cooling vessel 110.

The cooler 120 cools the raw water contained in the cooling container 110 by the low-temperature refrigerant flow. At this time, the sterilizer 140 sterilizes microorganisms contained in the cold water by irradiating the cold water with light. Therefore, the preparation of cold water and the sterilization of microorganisms can be performed at the same time.

Cold water of the cooling vessel 110 is introduced into the filter 130 through the outer surface of the filter 130, filtered through the filter 130, and then flows into the cold water flow path 135. Cold water of the cold water passage 135 may be discharged to the cold water coke through the cold water discharge pipe 113.

Since the filter 130 and the cooler 120 are both accommodated in the cooling vessel 110, the water treatment device 100 may allow the cooling vessel 110 to simultaneously generate and filter the cold water.

In addition, since the filter 130 and the cooler 120 are embedded in the cooling container 110, a space in which the filter 130 and the cooler 120 are installed in the water treatment device may be unnecessary. Therefore, the micro water treatment apparatus 100 can be manufactured. In addition, an ultra low cost water treatment apparatus can be manufactured.

In addition, since the sterilizer 140 is installed in the cooling vessel 110, the water treatment device 100 may sterilize cold water while generating cold water, thereby suppressing the growth of microorganisms.

Next, a second embodiment of the water treatment apparatus according to the present invention will be described. Since the second embodiment is substantially the same as the first embodiment except for the cooler as compared to the first embodiment, the same reference numerals are given to the same components and the description thereof will be omitted.

3 is a view showing a second embodiment of the water treatment apparatus according to the present invention.

Referring to FIG. 3, the cooler 120 of the water treatment device may be a thermoelectric module 220. The thermoelectric module 220 includes a Peltier device using the Peltier effect. In the Peltier element, one terminal absorbs heat and the other terminal generates heat according to the current direction. The Peltier device can switch between endothermic and exothermic according to the current direction, and the endothermic and exothermic amount can be adjusted according to the amount of current.

The thermoelectric module 220 may include a cooling unit 221 disposed inside the cooling container 110 and a heat generating unit 225 disposed outside the cooling container 110. The cooling unit 221 may be provided with a cooling fin 223 to improve the heat exchange efficiency with the raw water. The cooling fins 223 may be formed of aluminum in various forms. The heat generating unit 225 may be provided with a heat generating fin 227 to exchange heat with the outside air. The heating fin 227 may be formed of an aluminum material.

When the thermoelectric module 220 supplies power, the cooling unit 221 may be cooled, and heat may be generated in the heat generating unit 225. Accordingly, since the compressor 121, the condenser 123, the expansion valve 125, and the like do not need to be installed as in the first embodiment, the size of the water treatment device can be reduced than in the first embodiment.

100: water treatment device 110: cooling vessel
111: raw water inlet pipe 113: cold water discharge pipe
120: cooler 121: compressor
123: condenser 125: expansion valve
127: evaporator 130: filter
135: cold water flow path 140: sterilizer
220: thermoelectric module 221: cooling unit
223: cooling fin 225: heat generating portion
227: heating fin

Claims (9)

A cooling vessel into which raw water flows;
A cooler disposed inside the cooling vessel to cool the raw water introduced into the cooling vessel; And
And a filter disposed in the cooling vessel to filter and discharge cold water.
The method of claim 1,
The cooler is a water treatment device, characterized in that the evaporator through which the refrigerant flows.
The method of claim 2,
The evaporator is a water treatment apparatus, characterized in that formed in the form of a coil.
The method of claim 3, wherein
The filter is a water treatment device, characterized in that spaced apart from the evaporator inside the evaporator.
The method of claim 1,
The cooler is a water treatment device, characterized in that the thermoelectric module.
The method according to any one of claims 1 to 5,
And said filter is a carbon block filter.
The method according to claim 6,
Cold water flow path is formed in the center of the filter,
The cold water flow path is characterized in that the cold water discharge pipe is connected.
6. The method according to any one of claims 1 to 5,
The cooling vessel further comprises a sterilizer.
The method of claim 8,
The sterilizer is a water treatment device, characterized in that the UV lamp or ultraviolet LED.

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