KR20220128854A - Cooling device for water purifier - Google Patents

Abstract

The present invention relates to a cooling device for supplying cold water to a water purifier and, more specifically, to a cooling device for a water purifier without water storage, capable of eliminating the need for water storage to remedy weaknesses caused by water storage, reducing a heat loss for the cooling of water, and making convenient the manufacture of a cooling device to improve productivity. To achieve the purpose, in accordance with the present invention, the cooling device includes: a thermoelectric element (100) absorbing and emitting heat, and enabling a cooling operation using the heat absorption side; a heat exchange unit (200) provided in contact with the heat absorption side of the thermoelectric element (100), and cooled by the heat absorption action; and a water coil unit (300) in which a pipe body (310), in which water flows, is provided in contact with the heat exchange unit (200), wherein the water in the pipe body (310) is instantly cooled by cold air delivered from the heat exchange unit (200), and which provides the cooled cold water to the water purifier.

Description

Cooling device for water purifier that does not store water

The present invention is a cooling device for supplying cold water to a water purifier, to prevent water from being stored, to compensate for the disadvantages of water being stored, to reduce heat loss for cooling water, and to simplify the manufacture of a cooling device. It relates to a cooling device for a water purifier that does not store water to improve productivity.

In general, a water purifier is a device that supplies water by removing impurities by hanging water by physical and chemical methods. There are water purifiers, etc.

Such a water purifier can supply cold water and hot water, respectively, as needed. In the case of cold water, there are a compression cooling method that forcibly circulates a refrigerant through a compressor to cool it, an electronic cooling method using a thermoelectric semiconductor, and the like, of which the thermoelectric element supplies power. Due to the Sipeltier effect, one side absorbs heat and the other side generates heat, and a fluid cooling device for a water purifier having a thermoelectric device is being developed.

For example, looking at the prior Korean Patent Publication No. 10-2013-0033934, it includes a water tank made of a thermally conductive material and storing water and at least one cooling unit for cooling the water stored in the water tank, , The cooling unit is a thermoelectric element that absorbs heat on one side and heats the other side when power is supplied, and is made of a thermally conductive material, and one surface is bonded to the surface of the heat absorbing side of the thermoelectric element via the first solder layer. At the same time, the other side is bonded to the outer surface of the water tank via a second solder layer to transfer the cold air from the thermoelectric element to the water tank, and a heat transfer spacer, and the thermoelectric element from the heat generating side of the thermoelectric element and a heat sink for dissipating heat, wherein the water tank is made of any one of a stainless steel-based metal and a polypropylene-based synthetic resin, the heat transfer spacer is made of a copper-based metal, and the first and A water purifier having a cooling unit is proposed, wherein the second solder is made of a material containing tin, and the water tank has a protrusion for expanding the heat transfer area on the inner surface of the portion to which the heat transfer spacer is joined. .

However, conventionally, a cooling device using a thermoelectric element is a method of storing and using water, and a water tank for storing water is essential. There is a cumbersome need to clean the water tank, the size of the water purifier is limited due to the area occupied by the water tank as a basis, and the water purifier cannot be manufactured in a small size, and there is a problem that productivity is significantly reduced due to the cumbersome manufacture of the water purifier.

In addition, in the prior art, in order to transfer the cold air of the thermoelectric element to the water stored in the water tank, a heat pipe connected to the thermoelectric element is in contact with the outer surface of the water tank or in contact with water inside the water tank. There was a problem in that the cooling efficiency was significantly reduced and energy was wasted due to a large amount of heat loss during cooling by cooling the whole.

Korean Patent Publication No. 10-2013-0033934 is presented.

The present invention is to solve the problems of the prior art, by contacting a water coil in which water flows to a heat exchange unit that transmits cold air of a thermoelectric element to instantly cool the water, so that the water is cooled without a separate storage space and cold water is provided immediately. Accordingly, the purpose is to compensate for the disadvantages of using a water tank because there is no water tank, to make the water purifier small, and to improve the productivity by simplifying the manufacture of the water purifier.

In addition, according to the present invention, the water coil through which water flows is wound around the peripheral surface of the side wall of the heat exchange unit in a spiral form so that each tube of the water coil is in contact with the heat exchange unit, so that the required capacity for easy use of cold water is supplied. The purpose of this is to improve cooling efficiency while minimizing heat loss during water cooling as the secured water can be cooled as a whole.

The present invention in order to solve the above object;

a thermoelectric element that absorbs heat and generates heat, and performs cooling using the side that absorbs heat;

a heat exchange unit provided in contact with a heat absorbing side of the thermoelectric element and cooled by the heat absorbing action;

A tubular body through which water flows is provided in contact with the heat exchange part, and cold air is transferred from the heat exchange part to instantly cool the water in the tubular body, and a water coil part for providing the cooled cold water to a water purifier. Provided is a cooling device for a water purifier that does not store water.

According to the present invention, since there is no water tank in the water purifier to which the cooling device is applied, the disadvantages caused by the use of the water tank can be supplemented, the water purifier can be manufactured in a compact size, and the production of the water purifier is simple, thereby improving productivity.

In addition, the cooling device to which the water coil is applied minimizes heat loss while cooling water and improves cooling efficiency.

1 to 2 are block diagrams of a cooling device for a water purifier in which water is not stored according to an embodiment of the present invention.

The features of the cooling device for a water purifier in which water is not stored according to the present invention will be understood by the embodiments described in detail below with reference to the accompanying drawings.

On the other hand, in describing the embodiments, detailed descriptions of components widely known and used in the technical field to which the present invention belongs or do not belong will be omitted, and unnecessary descriptions will be omitted and the present invention according to this will be omitted. This is to convey the point more clearly.

Hereinafter, as a basic configuration of the present invention, the configuration of each part of the cooling device for a water purifier in which water is not stored according to an embodiment will be described in detail with reference to FIG. 1 . 1 is a side sectional view of the cooling device, and FIG. 2 is a plan view of the cooling device.

A schematic view of the cooling device 1 according to this will include a thermoelectric element 100 that absorbs heat and generates heat; a heat exchange unit 200 for cooling the endothermic action of the thermoelectric element 100; and a water coil unit 300 that provides cold water cooled through the heat exchange unit 200 to the water purifier.

A detailed configuration of the cooling device 1 for a water purifier in which water is not stored having such a configuration will be described in detail with reference to the accompanying drawings.

First, the thermoelectric element 100 is;

It absorbs heat and heats up, and cooling is performed using the side that absorbs heat.

For example, the thermoelectric element 100 is an element using a thermoelectric effect that appears as a result of the interaction of heat and electricity, and the thermoelectric element 100 absorbs or generates heat due to the Peltier effect, and a heat exchange unit ( 200) is in contact with the thermoelectric element 100 so as to cool the heat exchange unit 200 through an endothermic action of the thermoelectric element 100 .

At this time, thermal paste is used between the contact surface of the thermoelectric element 100 and the heat exchange unit 200 to improve bonding properties and thermal conductivity.

In addition, the thermoelectric element 100, the heat dissipation unit 110 is provided on the heat generating side to perform heat dissipation; further includes.

The heat dissipation unit 110 is a heat sink provided in surface contact with the radiating side of the thermoelectric element 100, and uses a plurality of heat dissipation fins provided in the heat dissipation unit 110 to radiate heat of the thermoelectric element 100. It functions, and between the contact surface of the heat dissipation unit 110 and the thermoelectric element 100, thermal paste is also used to improve bonding properties and thermal conductivity.

In addition, the heat dissipation unit 110, a blower fan 120 for forcibly cooling the radiated heat; further includes.

The blower fan 120 is provided on the outside of the heat dissipation unit 110 to forcibly blow the heat radiated from the heat dissipation unit 110 to the outside.

And, the heat exchange unit 200;

It is provided in contact with the heat absorbing side of the thermoelectric element 100, is cooled by the heat absorbing action, and is for cooling water by transferring cold air to the water coil unit 300 through the cooling.

For example, the heat exchange unit 200 may include a base 210 in contact with a heat absorbing side; and

It is formed to protrude from the base 210, and the protruding portion of the water coil unit 300, the tubular body 310 to be in contact with the support 220; further includes.

The base 210 is provided in contact with the heat absorbing side of the thermoelectric element 100 as a plate, and thermal paste is also used between the base 210 and the contact surface of the thermoelectric element 100 to improve bonding properties and thermal conductivity.

The support 220 is integrally formed to protrude from the base 210 so as to provide a space in which the water coil unit 300 is in contact with the opposite surface where the base 210 is in contact with the thermoelectric element 100 , preferably The support 220 is provided in a cylindrical shape around the base 210 .

At this time, the base 210 and the support 220 are cooled through the heat absorbing action of the thermoelectric element 100, and the base 210 and the support 220 are cooled while being provided in contact with the support 220 Cool air is transmitted to the water coil unit 300 .

And, the water coil unit 300;

A tube body 310 through which water flows is provided in contact with the heat exchange unit 200 , cold air is transferred from the heat exchange unit 200 , and the water in the tube body 310 is instantly cooled, and the cooled cold water is treated with a water purifier. is intended to provide

For example, the water coil unit 300 includes a pipe body 310 having inlets and outlets 311 through which water is introduced and discharged, respectively, provided at both ends, and through which water flows through the outlets 311 ; .

The tube body 310 is coupled to the heat exchange unit 200 to be in surface contact, and the tube body 310 is a tube through which water flows. The water inlet side of 310 is connected to the water purifier so that water filtered through the filter of the water purifier is supplied, and the water outlet side of the tube body 310 is connected to supply water to the cold water outlet of the water purifier.

At this time, the tube body 310 can instantaneously cool the water supplied through the filter of the water purifier through the cooling action of the heat exchange unit 200, and the cooled water in the cold water supply situation of the water purifier is applied to the tube body 310. Through this, it is provided directly to the cold water outlet of the water purifier so that it can be used as a direct water purifier.

On the other hand, the tube body 310 is supported by being spirally wound around the support body 220 of the heat exchange unit 200, in proportion to the number of times the tube body 310 is spirally wound around the support body 220. The capacity for maximally discharging cold water cooled to an appropriate level is determined, and through this, the water purifier can store an appropriate level of water to use the cold water more than once.

Here, the tube body 310 includes, when the support body 220 of the heat exchange unit 200 is formed in a cylindrical shape, a first spiral part 312 spirally wound around the outer periphery of the support body 220 of the cylindrical body; and

It further includes; while extending from the first spiral portion 312, a second spiral portion 313 spirally wound around the inner periphery of the cylindrical support 220.

The first spiral portion 312 is a portion in which the tube body 310 is spirally wound around the cylindrical outer periphery of the support body 220 , and the first spiral portion 312 is a straight tube body having an entrance 311 . The portion 310 is formed to be spirally wound to the upper portion of the support 220 from the point where it extends to the bottom of the support 220, and the first spiral portion 312 is wound to the upper end of the support 220. It extends to the second spiral portion 313 to connect them.

The second spiral portion 313 is a portion extending from the first spiral portion 312 and spirally wound around the inner periphery of the cylinder of the support 220 , and the second spiral portion 313 is the support 220 . ) is formed to be supported by being spirally wound from the upper portion to the lower portion of the support 220 , and the portion where the second spiral portion 313 is wound to the lower portion of the support 220 is a straight tube body 310 of the support 220 . It is formed to have an entrance 311 while extending upward.

At this time, water is supplied from the water purifier to the entrance 311 on the first spiral part 312 side and the entrance 311 on the second spiral part 313 side. to flow in, preferably water is introduced into the inlet 311 on the side of the second helix 313, and water is discharged through the inlet 311 on the side of the first helix 312 to perform fluid circulation. can

Here, the first spiral portion 312 and the second spiral portion 313 may be elastically supported in the form of interference fit to the support 220 by elastic force due to a spiral structure.

In the process of coupling the tubular body 310 to the support 220 , the first spiral part 312 and the second spiral part 313 are expanded, and the second spiral part 313 is ) is wound in the form of a spring to be contracted to generate stress due to elastic force. The first spiral portion 312 and the second spiral portion 313 wound in a spiral form when the support 220 is sandwiched between the first spiral portion 312 and the second spiral portion 313. ), the first spiral part 312 is closely supported by the outer peripheral side of the support 220 by the force to keep the shape while removing the stress of the support 220 , and the second spiral part 313 is the inner peripheral side of the support 220 . The water coil unit 300 is fixed to the heat exchange unit 200 in the form of an interference fit while being closely supported.

Characteristically, the present invention cools the water instantaneously while the water coil unit 300 through which water flows is in contact with the heat exchange unit 200 that transmits the cold air of the thermoelectric element 100, so that the water is cooled without a separate storage space, and cold water is supplied. It can be provided immediately, and thus a water tank is not required, so the disadvantages of using a water tank can be supplemented, and the water purifier can be manufactured in a compact size, and productivity can be improved while manufacturing the water purifier easily.

In addition, the present invention is provided by winding the water coil unit 300 through which water flows in a spiral shape around the side wall of the heat exchange unit 200 as a whole. It is possible to cool the secured water as a whole while securing it, minimizing heat loss during water cooling and improving cooling efficiency.

As described above. Although the present invention has been expressed with descriptions and drawings illustrating specific preferred embodiments, the terms used here are for the purpose of easily explaining the present invention, limiting the meaning of these terms, or limiting the scope of the claims not to do it,

The present invention is capable of various changes, alterations, modifications, etc. by those of ordinary skill in the art to which the invention pertains within the scope that does not depart from the spirit and scope of the invention indicated by the claims according to the above embodiments. Anyone can easily see that it is possible.

One; cooling device 100; thermoelectric element
110; heat dissipation unit 120; blower fan
200; heat exchange unit 210; Base
220; support 300; water coil part
310; tube body

Claims (5)

a thermoelectric element 100 that absorbs heat and generates heat, and performs cooling using the side that absorbs heat;
a heat exchange unit 200 provided in contact with a heat absorbing side of the thermoelectric element 100 and cooled by the heat absorbing action;
A tube body 310 through which water flows is provided in contact with the heat exchange unit 200 , cold air is transferred from the heat exchange unit 200 , and the water in the tube body 310 is instantly cooled, and the cooled cold water is treated with a water purifier. A cooling device for a water purifier that does not store water, characterized in that it includes; a water coil unit 300 provided to. According to claim 1,
The thermoelectric element 100 includes a heat dissipation unit 110 provided on the heat generating side to perform heat dissipation; and a blower fan 120 for forcibly cooling the heat radiated from the heat dissipation unit 110; a cooling device for water purifier that does not store water further including. According to claim 1,
The heat exchange unit 200 includes a base 210 in contact with a heat absorbing side; and
A cooling device for a water purifier that does not store water further including; a support 220 protruding from the base 210 and allowing the tube body 310 of the water coil unit 300 to come into contact with the protruding portion. According to claim 1,
The water coil unit 300 is a water purifier that does not store water further including; a pipe body 310 through which water inlet and outlet 311 are provided at both ends, and water flows through the inlet 311 . for cooling device. According to claim 1,
The pipe body 310 is a cooling device for a water purifier that does not store water further including being spirally wound around the support body 220 of the heat exchange unit 200 .

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