KR200401756Y1 - Heat exchange unit - Google Patents

Abstract

A heat exchange unit is provided. The provided heat exchange unit is provided with a partition wall formed in a horizontal direction at an inner middle portion, the case having first and second installation portions, a power supply unit installed at the first installation portion of the case, and a second installation portion of the case. At one end having an intake fan at the front end, a hot sink at the other end, and at least one thermoelectric element disposed between the hot sink and the cool sink and the hot sink are installed to absorb the condensed water formed in the cool sink. Condensate evaporation means for evaporating the condensed water into the air by the heat of the hot sink, wherein the cool sink and the hot sink is arranged up and down around the thermoelectric element.

Description

Heat exchanger unit {HEAT EXCHANGE UNIT}

The present invention relates to a heat exchange unit for industrial equipment, and more particularly to a heat exchange unit having a power supply unit integrally.

Generally, various industrial equipments such as electronic devices, semiconductor devices, communication equipments, computers, and computer peripherals are electrically connected with wires or cables by various parts having independent functions to operate or control the equipment. In addition to being connected to each other, the circuit board is organically connected to each other through a medium. At this time, the parts embedded in the various industrial equipment generates a lot of heat when the equipment is used for a long time, the heat generated in the component element, such as shortens the life of the component and also decreases its function, affecting other adjacent components Severe cases, of course, can cause malfunctions or inability to process data. Accordingly, the existing various industrial equipment is provided with a heat exchange unit for cooling the component elements.

Existing heat exchange unit is a heat sink having a heat sink for discharging the hot air sucked, a cool sink having a cooling fan to supply the outside air to generate cool air, and the cool sink is stacked on the hot sink It consists of a thermoelectric element that transfers cold heat to it. According to this configuration, the heat sink fan of the hot sink discharges the air inside the equipment, the temperature rises by the heat generated from the various components, the outside of the equipment to the outside, the cooling fan of the cool sink generates cold air to the equipment It supplies the inside to prevent overheating of various parts.

At this time, the conventional heat exchange unit is a condensed water is generated because the cooled air discharged through the cool sink toward the outlet has a temperature difference with the air inside the equipment. As such, the condensed water generated by the temperature difference flows into various components, causing electric shock and malfunction. Accordingly, the existing heat exchange unit is provided with a drain hose for discharging the condensate to the outside and a condensate receiver for receiving the condensate discharged through the drain hose in order to remove the condensate from the cool sink, or formed in the cool sink. The condensate tray which can receive condensate is provided in the inside itself.

However, the existing heat exchange unit still has a problem such that when a certain amount of condensate accumulates in the condensate receiver, the condensate overflows and enters the controller of the electronic device, causing electric shock and malfunction. In particular, a computer with a small size of the equipment itself occupies a lot of space because the power supply unit and the heat exchange unit are mounted inside each, and a separate exhaust port for dissipating heat generated from the power supply unit must be provided. In addition, there is a problem in that a separate power line must be wired to operate the heat exchange unit.

Thus, in Utility Model Application No. 2003-0021476, filed by the present applicant in order to solve the above problems, a case in which a partition wall is formed in a transverse direction is provided at an inner middle portion, and a cover covering an upper portion of the case is provided. A heat exchange unit including a hot sink having a heat dissipation fan at a lower portion, a heat sink having a cooling fan, and a thermoelectric element disposed between the hot sink and the cool sink, the power supply device being provided at an upper portion of the case inner partition wall; Is disclosed. This preliminary design makes it possible to evaporate the condensed water in the cool sink by heat generated from the hot sink through the condensate evaporation means, thus eliminating the need to install a separate condensate tray, etc. Of course, since the heat exchange unit can receive power directly from the power supply, there is no need for a separate power line wiring.

However, the above-described application design has a structure in which the cool sink and the hot sink are arranged on the left and right sides of the thermoelectric element. For this reason, the design of the prior application has a problem that the condensed water formed in the cooling fin portion of the cool sink is not easily introduced into the condensate evaporation means, so that the evaporation efficiency of the condensate is reduced.

Thus, the present invention was devised to solve the general problems of the above-described application,

The technical problem to be achieved by the present invention is to improve the arrangement of the cooling sink and the hot sink to maximize the evaporation efficiency of the condensate by allowing the condensed water formed in the cooling fins of the cooling sink to flow down by gravity and easily flow into the condensate evaporation means. To provide a heat exchange unit.

Another technical problem to be achieved by the present invention is to provide a heat exchange unit that can maximize the evaporation efficiency of the condensate by improving the structure of the cool sink to facilitate the flow of condensate flowing from the cooling fins into the condensate evaporation means.

As a specific means of the present invention for solving the above technical problem;

A case in which a partition wall is formed in a horizontal direction in an inner middle portion and provided with first and second installation portions;

A power supply unit installed in the first installation unit of the case;

At least one thermoelectric element installed at a second installation portion of the case and having a hot sink at one end having an intake fan at a front end, a cool sink at the other end, and between the hot sink and the cool sink; And

Condensate evaporation means installed to enclose the hot sink and absorb condensed water formed in the cool sink to evaporate condensed water into the air by the heat of the hot sink; Including,

The cool sink and the hot sink have a heat exchange unit, which is arranged up and down about the thermoelectric element.

In a preferred embodiment, the cool sink has a structure in which a plurality of cooling fins protrude from an upper surface of the base plate, and a gradient portion may be provided in the base plate.

More preferably, the gradient portion may be configured in the form of a raised center of the base plate.

In a preferred embodiment, the second installation portion may be provided with an insulating space in the space between the hot sink, the thermoelectric element and the cool sink, the heat insulating material may be installed in this insulating space.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram for explaining a heat exchange unit according to the present invention, Figure 2 is a side configuration diagram for explaining a second installation unit in the heat exchange unit according to the present invention.

Referring to FIG. 1, the heat exchange unit 1 of the present invention includes a power supply device 3, a hot sink 4, and a cool sink 5 in a case 2 having first and second installation portions 21 and 22. ), The thermoelectric element 6 and the condensate evaporation means (7) is provided.

The case 2 has a partition wall formed in a horizontal direction at an inner middle portion thereof to provide first and second installation parts 21 and 22. The power supply device 3 is installed in the first installation part 21 of the case 2, and the power supply device 3 is a power connector (socket or jack type) to which a power supply line supplied from the outside is connected. ).

The second sink 22 of the case 2 is provided with a hot sink 4, a thermoelectric element 6, and a cool sink 5. In the present invention, the cool sink 5 and the hot sink 4 are arranged up and down around the thermoelectric element 6. According to this configuration, the condensed water generated in the cool sink 5 can be more smoothly introduced into the hot sink 4 by gravity, it is possible to maximize the evaporation efficiency of the condensate.

At this time, the hot sink 4 is provided with an intake fan 41 at the front end thereof, and is installed in such a manner as to encapsulate the condensate evaporation means 7, that is, a microfiber etc., on the upper portion of the hot sink 4. The cool sink 5 is arranged. In addition, at least one thermoelectric element 6 disposed between the hot sink 4 and the cool sink 5 is installed, and the thermoelectric element 6 is electrically supplied from the power supply device. (The power supply supplies the driving power for each fan described before and after.)

In addition, the second installation part 22 is provided with a space between the hot sink 4 and the thermoelectric element 6 and the cool sink 5 is provided with a heat insulating space 221, for example, a insulation space filled with a heat insulating material hot sink 4 ) And the heat sink between the cooling sink (5).

3 is a perspective view and a side view for explaining the cool / hot sink in the heat exchange unit according to the present invention.

Referring to FIG. 3, the cool sink 5 has a structure in which a plurality of cooling fins 52 protrude from an upper surface of the base plate 51. Such a plurality of cooling fins 52 have a predetermined interval. It is preferable to form an air flow path between the respective cooling fins 52 by protruding in a spaced form. In addition, the base plate 51 is preferably provided with a gradient portion 53, the gradient portion 53, the condensate evaporation means (7) of the hot sink 4 to facilitate the condensate flowed down from the cooling fin (52) The center of the base plate 51 is formed in a raised form to guide to).

Referring back to FIG. 2, the heat exchange unit 1 includes a hot sink 4 at one end and a cool sink 5 at the other end, an intake fan 41 installed at the front end of the sink, and a hot duct 31 at the other end of the sink. The cool duct 32 is composed of.

At this time, the cool duct 32 at the rear end of the cool sink 5 faces an arc in order to smooth the flow of the fluid and is directed downward so that cold air flows into the computer from the end and the hot sink 32 at the front end. ) Is a structure that is blocked at the front and open at both sides to disperse air.

Thus, the working state of the heat exchange unit according to the present invention having the configuration as described above will be described.

Figure 4 is a block diagram for explaining the operating state of the heat exchange unit according to the present invention.

Referring to FIG. 4, when the intake fan 41 introduces external air into the cool sink 5, the introduced air is cooled by the cool sink 5 cooled by the thermoelectric element 6 and then the cool duct 32. It is supplied to the heating part of the equipment through) to perform cooling. In addition, when the intake fan 41 flows the air present in the equipment into the hot sink 4, the introduced air is heat-exchanged with the heated hot sink 4 for heat dissipation of the thermoelectric element 6 to heat the hot sink 4 After cooling, it is discharged to the outside of the equipment through the hot duct (31).

At this time, the condensate generated in the cool sink 5 flows smoothly into the base plate 51 by the cooling fins 52 by gravity, and is smoothly guided by the gradient part 53 provided in the base plate 51. It is absorbed by the condensed water evaporation means 7 installed in the hot sink 4, and since it is evaporated by the heat of the hot sink 4 can maximize the evaporation efficiency.

As described above, in the heat exchange unit according to the present invention, by condensing the cool sink and the hot sink up and down, the condensed water formed in the cooling fins of the cool sink flows down by gravity and can be easily introduced into the condensate evaporation means. Can be maximized. In addition, by providing a gradient in the base plate of the cool sink to easily flow the condensate flowing from the cooling fins into the condensate evaporation means has the effect of maximizing the evaporation efficiency of the condensate.

1 is a configuration diagram for explaining a heat exchange unit according to the present invention.

2 is a side configuration diagram for explaining a second installation unit in the heat exchange unit according to the present invention.

3 is a perspective view and a side view for explaining the cool / hot sink in the heat exchange unit according to the present invention.

Figure 4 is a block diagram for explaining the operating state of the heat exchange unit according to the present invention.

<Explanation of symbols for major parts of drawing>

1: heat exchange unit 2: case

3: power supply 4: hot sink

5: cool sink 6: thermoelectric element

7: condensate evaporation means

Claims (5)

A case in which a partition wall is formed in a horizontal direction in an inner middle portion and provided with first and second installation portions; A power supply unit installed in the first installation unit of the case; At least one thermoelectric element installed at a second installation portion of the case and disposed between a hot sink, a cool sink, an intake fan installed at a front end of the hot sink and a cool sink, and between the hot sink and the cool sink; And Condensate evaporation means installed to enclose the hot sink and absorb condensed water formed in the cool sink to evaporate condensed water into the air by the heat of the hot sink; Including, And said cool sink and said hot sink are arranged up and down with respect to said thermoelectric element, respectively. The method of claim 1, The cool sink has a structure in which a plurality of cooling fins protruding from the upper surface of the base plate, wherein the base plate is provided with a gradient portion. The method of claim 2, The gradient unit heat exchange unit, characterized in that the center of the base plate is formed in the form of raised. The method of claim 1, The second installation unit is provided with a heat insulating space in the space between the hot sink and the thermoelectric element and the cool sink, the heat insulating unit, characterized in that the heat insulating material is installed. The method of claim 1, And a cool duct for introducing cold air into the rear end of the cool sink, and a hot duct in the form of a branch pipe at the rear end of the hot sink.