JP2005536712A - Heat exchange unit with condensate treatment device - Google Patents

Abstract

The present invention relates to a heat exchange unit including a condensate treatment apparatus for treating condensed water by evaporating condensed water generated in cooling fin portions of the heat exchange unit into air in the heat exchange unit itself. To achieve the above object, the present invention provides a heat sink having a heat sink, a cool sink having a cooling fan, and a heat exchange unit including a heat transfer element disposed between the hot sink and the cool sink. A condensed water evaporation means for absorbing condensed water generated in a cool sink provided in the reverse exchange unit and evaporating the condensed water in the air by the heat of the hot sink is provided. The heat exchange unit according to the present invention can evaporate the condensed water in itself, omitting a separate condensed water receiver and a water distribution hose, thereby reducing manufacturing and installation costs. Further, since the condensed water is evaporated by the heat generated in the hot sink of the heat exchange unit itself, it is a useful invention that does not require additional energy for evaporating the condensed water.

Description

  The present invention relates to a heat exchange unit equipped with a condensate treatment apparatus. In particular, the present invention relates to a heat exchange unit including a condensed water treatment apparatus that treats condensed water by evaporating condensed water generated in cooling fin portions of the heat exchange unit into air in the heat exchange unit itself.

  The present invention also relates to a heat exchange unit including a condensate treatment device integrally formed with a computer power supply device in which a heat exchange unit and a power supply device for supplying current to peripheral devices of the computer are integrally formed.

  In general, computers, communication equipment, and electrical / electronic equipment are electrically connected to each other with various functions having independent unique functions by electric wires or cables, and are organically connected to each other using a printed circuit board as a medium. The equipment can be operated and controlled by the operation of the component elements.

  When the equipment is operated or controlled by the operation of the component elements, if the equipment is used for a long time, a lot of heat is generated in the component elements.

  Therefore, the heat generated in such component elements shortens the life of the component and reduces its function, which affects other adjacent component elements. In extreme cases, malfunctions and data processing are impossible. Because of this, a cooling device is used to cool the component elements.

  As the cooling device for cooling the component elements, a hot sink provided with a heat-dissipating fan that discharges hot air sucked in by having a heat-insulating protrusion protruding in a square shape on the inside is prepared.

  A cool sink having a cooling fan that supplies external air to the inside to generate cold air is prepared.

  A heat transfer element that is stacked on the heat insulating protrusion of the hot sink and transmits cold heat to the cool sink is provided to cool the heat generated in the component elements of various electronic devices.

  For reference, the hot sink is formed by combining a plurality of radiating fins, and the cool sink is also configured by a plurality of cooling fins.

  In such a heat exchange unit, the cooled air passing through the cool sink and discharged to the discharge port side generates condensed water due to a temperature difference with the internal air.

  The process of generating condensed water will be described in more detail as follows. It is used in an environment where the humidity of summer air is higher than 75%.

  In a product such as an air conditioner, the temperature of the cooling fin portion is lower than the dew point of the air, so moisture in the air adheres to the cooling fin portion and condensed water is generated.

  The dehumidifying temperature of air is determined by the air temperature / humidity relationship. The temperature of the cooling fin portion of the cooling device that operates to maintain the internal temperature of 20 ° C is actually lower than 10 ° C.

  Therefore, there is a disadvantage that the condensed water generated by the temperature difference enters the control unit of various electronic devices and causes electric shock and malfunction.

  Therefore, in order to remove the condensed water generated in the cool sink, a water distribution hose for discharging the condensed water to the outside and a condensed water receiver that can receive the condensed water discharged through the water distribution hose are separately provided. In addition, a condensate receiver that can receive the condensate generated in the cool sink must be provided in the interior itself.

  However, if a certain amount of condensate accumulates in the condensate receiver, the condensate overflows and enters the control unit of the electronic device, causing an electric shock or malfunction. As always.

  In addition, since the power supply unit and the heat exchange unit are each installed in the computer, they occupy a lot of space, so that many parts necessary for these installations are included, resulting in economic loss. become.

  Therefore, a separate exhaust port for discharging the heat generated in the power supply apparatus must be provided, and a separate power line for operating the heat exchange unit must be wired. It was.

  The present invention has been devised to solve such a problem, and the condensed water generated in the cool sink is absorbed by the condensed water evaporation means, and the condensed water absorbed is the heat sink fin of the hot sink. The purpose is to treat the condensed water by evaporating it into the external air by the hot hot air generated in the section.

  According to the present invention, a power supply device for supplying power to a computer, communication equipment, and electrical / electronic equipment component elements is formed integrally with a heat exchange unit for cooling the heat of the computer, communication equipment and electrical / electronic equipment component elements. .

  Another object is to exhaust the heat generated in the power supply device to the outside through the heat dissipation fan by connecting the inside of the power supply device and the heat dissipation fan using a communication pipe. There is something.

  The present invention includes a heat sink comprising a hot sink having a heat radiating fan, a cool sink having a cooling fan, and a heat transfer element disposed between the hot sink and the cool sink; The present invention is characterized by comprising condensed water evaporation means for absorbing condensed water generated in the cool sink and evaporating condensed water in the air by the heat of the hot sink.

  The present invention provides a case in which a partition wall is formed in a lateral direction at an inner intermediate portion, and includes a cover that covers an upper portion of the case.

  A power supply device is prepared in the upper part centered on the inner partition wall of the case, a hot sink having a heat radiating fan in the lower part, a cool sink having a cooling fan, and a heat transfer disposed between the hot sink and the cool sink. A heat exchange unit composed of elements is prepared.

  Further, the present invention is characterized by comprising condensed water evaporation means for absorbing condensed water generated in the cool sink and evaporating the condensed water in the air by the heat of the hot sink.

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

  1 is an overall configuration diagram of a heat exchange unit equipped with a condensate treatment apparatus according to the present invention, FIG. 2 is a perspective view of a heat exchange unit equipped with a condensate treatment apparatus according to the present invention, and FIG. 3 is a condensate treatment according to the present invention. 4 is an exploded perspective view of the heat exchange unit equipped with the apparatus, FIG. 4 is a cross-sectional view showing a state where the absorption part of the condensed water evaporation means of the present invention is located in the cooling fin part, and FIG. 5 is an illustration of the condensed water evaporation means of the present invention. It is sectional drawing which showed the state which the evaporation part was located in the radiation fin part.

  As shown in FIGS. 1 to 5, the heat exchange unit 1 according to the present invention includes a heat sink 10 having a heat-dissipating protrusion 16 that protrudes in a rectangular shape on the inner side and a heat radiating fan 14 that discharges internal air to the outside. A cool sink 20 having a cooling fan 24 that is prepared and that supplies external air to the inside is prepared.

  A heat transfer element 26 that is stacked on the heat insulating protrusion 16 of the hot sink 10 and transfers cold heat to the cool sink 20 is seated.

  The hot sink 10 and the cool sink 20 are fixed by a plurality of fixing means, and include a case 2 that houses the cool sink 20 and the hot sink 10 and a cover 3 that covers the upper portion of the case 2.

  The condensed water evaporation means 30 has an absorption part 32 arranged at the lower end of the condensed water aggregation part 28 of the cooling fin part 22 where condensed water is condensed, and the lower end of the hot sink 10 in the direction of the discharge part 18 for releasing hot heat inside. It is formed by the condensed water evaporation part 36 located in this.

  The condensate absorbed by the absorption unit 32 is connected to each other so that the condensed water is transmitted to the evaporation unit 36.

  In addition, a seating portion 40 is provided that prevents the condensed water absorbed at the lower end of the condensed water evaporation means 30 from flowing out to the inner periphery of the heat exchange unit 1.

  On the other hand, as a configuration for detecting the generation of condensed water and promoting the evaporation of the condensed water, the presence or absence of condensed water is detected between the condensed water evaporation means 30 and the seating portion 40, and the condensed water is thereby removed. A configuration for evaporation is provided.

  That is, a condensate sensor 52 for detecting presence / absence of condensate is disposed at the lower end of the absorption part 32 of the condensate evaporation means 30, and the temperature at which the temperature is sensed in order to maintain a constant temperature at the lower end of the evaporator 36. A sensing sensor 50 is arranged.

  In order to prevent the heater 60 from operating on / off by receiving information from the condensate sensor 52 regarding presence / absence of condensate and preventing the temperature sensor 50 from rising above a certain temperature by receiving information from the temperature sensor 50. The control unit 70 is provided.

  If the heat exchange unit according to the present invention is observed closely, if the external air is introduced to the cool sink 20 side by the cooling fan 24, the introduced air becomes cool while passing through the cooling fin portion 22 provided in the cool sink 20.

  The cooled air is supplied to the inside through the air duct 27 and cools heat generated in parts of various electronic devices.

  At this time, condensed air is generated on the surface of the cooling fin portion 22 where the cold air that passes through the cool sink 20 and is supplied to the inside through the air duct 27 meets the internal air due to a temperature difference with the internal air.

  The generated condensed water is absorbed by the absorbing portion 32 of the condensed water evaporating means 30 at the lower end and is passed through the connecting portion 34 to the evaporating portion 36 of the condensed water evaporating means 30 provided at the lower end of the hot sink 10. Moving.

  On the other hand, since the condensed water evaporation means 30 is seated on the seating section 40, the condensed water absorbed by the condensed water evaporation means 30 is prevented from flowing into the heat exchange unit 1.

  At this time, the heat generated while the heat transfer element 26 operates is transferred to the hot sink 10, and the heat of the hot sink 10 evaporates the temperature of the condensed water absorbed by the evaporation section 36 of the condensed water evaporation means 30. Heats to a temperature above ℃.

  The condensed water heated by the evaporation part 36 of the condensed water evaporation means 30 evaporates to the outside through the discharge part 18. At this time, the temperature of the hot sink 10 is about 40 to 50 ° C. or higher, and the temperature of the discharged air is about 35 to 40 ° C.

  Therefore, the condensed water absorbed by the absorption part 32 of the condensed water evaporation means 30 moves to the evaporation part 36 via the connecting part 34, and the condensed water moved to the evaporation part 36 is discharged by the heat of the heat generating fin part 12. Evaporate to the outside through 18.

  Condensed water absorbed by the absorption unit 32 as the condensed water evaporates in the evaporation unit 36 is then supplied to the evaporation unit 36 via the connecting unit 34.

  In addition, the evaporator 36 of the absorption evaporator 30 is provided with a heater 60 for heating the temperature of the condensed water to a predetermined temperature in order to improve the evaporation of the condensed water, thereby quickly evaporating the condensed water.

  At this time, the temperature of the heater 60 is not dangerous to the human body, for example, the temperature is detected by the temperature sensor 50 provided in the evaporation unit 36 of the condensed water evaporation means 30 so as to maintain a temperature of 60 ° C. or less.

  The detected temperature information is transmitted to the control unit 70, and the temperature of the heater 60 is controlled to be maintained below 60 ° C. under the control of the control unit 70.

  The controller 70 detects the presence / absence of condensed water in the absorber 32 via a condensed water sensor 52 provided in the absorber 36 of the condensed water evaporation means 30.

  Information on the presence or absence of the sensed condensed water is transmitted to the control unit 70, and when the control unit 70 determines that there is no condensed water, the power supply 72 is turned off and the heater 60 is turned off. To do.

  On the other hand, it is desirable that the condensed water evaporation means 30 is composed of capillary fibers that improve absorption and evaporation.

  For reference, capillary fibers currently used are ultrafine fibers of 1/100 mm or less, and such finely processed fibers are known to have a capacity of absorbing water three times or more than that of general fibers.

  FIG. 6 is an overall configuration diagram of a heat exchange unit including a condensate treatment apparatus according to another embodiment of the present invention, and FIG. 7 is a condensate water of a heat exchange unit including a condensate treatment apparatus according to another embodiment of the present invention. FIG. 8 is a perspective view of a heat exchange unit equipped with a condensate treatment apparatus according to another embodiment of the present invention, and FIG. 9 is a heat exchange unit equipped with a condensate treatment apparatus according to another embodiment of the present invention. FIG. 10 is a cut-away sectional view of a principal part of a heat exchange unit equipped with a condensate treatment apparatus according to another embodiment of the present invention, and FIG. 11 is a condensate evaporation means according to another embodiment of the present invention. FIG. 12 is a cross-sectional view showing a state in which the evaporating part of the condensed water evaporating means of another embodiment according to the present invention is located in the radiating fin part. is there.

  As shown in FIGS. 6 to 12, the present invention includes a case 101 having a partition wall 107 formed in a lateral direction at an inner intermediate portion, and includes a cover 102 that covers the upper portion of the case 101.

  A power supply device 105 having a power supply connection port 106 for applying power by inserting an external power supply line on the upper side with the inner partition wall 107 as a center is prepared.

  Heat comprising a hot sink 111 having a heat radiating fan 114 below the partition wall, a cool sink 121 having a cooling fan 124, and a heat transfer element 126 disposed between the hot sink 111 and the cool sink 121. An exchange unit 110 is prepared.

  The power supply device 105 plugs an externally supplied power line into the power connection port 106 and applies power to the power supply device 105 to drive the computer equipment and the heat exchange unit.

  At this time, the heat exchange unit 110 is activated by applying power to the power supply unit 172 and the heat transfer element 126 of the heat exchange unit 110.

  A communication pipe 117 is connected to the power supply device 105 and the heat radiating fan 114 of the heat exchange unit 110 to discharge heat generated in the power supply device 105 to the discharge unit 118.

  Between the inner partition wall 107 of the case 101 and the heat exchange unit 110, the outer part of the heat exchange unit 110, that is, between the inner part of the cover 102, the outer surface and the bottom surface of the heat exchange unit 110 and the heat exchange unit 110. Each of the heat insulating members 108, 108a, 108b is provided in the portion to prevent heat loss of the heat exchange unit 110.

  The heat exchange unit 110 is provided with a hot sink 111 having a heat-insulating protrusion 116 protruding in a square shape on the inner side and provided with a heat radiating fan 114 that discharges internal air to the outside.

  A cool sink 121 having a cooling fan 124 that allows the external air to flow in and supply the air to the inside is prepared.

  A heat transfer element 126 that is stacked on the heat insulating protrusion 116 of the hot sink 111 and transmits cold heat to the cool sink 121 is seated.

  The hot sink 111 and the cool sink 121 are fixed by a plurality of bolts 119, and the condensed water evaporating means 130 has an absorbing portion 132 disposed at the lower end of the condensed water condensing portion 128 of the cooling fin portion 122 where the condensed water is condensed.

  A condensed water evaporation unit 136 is disposed at the lower end in the direction of the discharge unit 118 of the hot sink 111 that releases the internal hot heat to the outside.

  A connecting portion 134 is provided that connects the condensed water absorbed by the absorbing portion 132 to the evaporating portion 136 so that the condensed water is transmitted to the evaporating portion 136.

  The bolt 119 is a metal bolt 140 that is a fixing means for fixing the hot sink 111 and the cool sink 121 to each other, and the hot sink 111 and the cool sink 121 are fixed to each other by the bolt 119.

  In addition, the seating unit 140 includes a seating portion 140 that prevents the condensed water absorbed at the lower end of the condensed water evaporation unit 130 from flowing out to the inner periphery of the heat exchange unit 110.

  On the other hand, as a configuration for detecting the generation of condensed water and promoting the evaporation of the condensed water, the presence or absence of condensed water is detected between the condensed water evaporation means 130 and the seating portion 140, and the condensed water is thereby removed. A configuration for evaporation is provided.

  That is, a condensate detection sensor 152 for detecting presence / absence of condensate is disposed at the lower end of the absorption unit 132 of the condensate evaporating unit 130 to detect temperature in order to maintain a constant temperature at the lower end of the evaporation unit 136. A temperature sensor 150 is arranged.

  In order to prevent the temperature of the heater 160 from rising above a certain temperature by receiving the information of the temperature sensor 150 by turning on / off the operation state of the heater 160 based on the information of the condensed water sensor 152 regarding presence or absence of condensed water. A control unit 170 is provided.

  The controller senses the temperature of the computer case and the CPU heat dissipation fan, and determines whether the cooling fan rotation speed of the cool sink and the operation of the heat sink heat sink are active or not based on the information.

  If the heat exchange unit according to the present invention is closely observed, if the external air is introduced to the cool sink 121 side by the cooling fan 124, the introduced air gets cold while passing through the cooling fin portion 122 provided in the cool sink 121.

  The cooled air is supplied to the inside through the air duct 127 and cools the heat generated in parts of various electronic devices.

  At this time, the cold air that passes through the cool sink 121 and is supplied to the inside through the air duct 127 generates condensed water on the surface of the cooling fin portion 122 where the air meets the internal air due to a temperature difference with the internal air.

  The generated condensed water is absorbed by the absorbing portion 132 of the condensed water evaporating means 130 at the lower end and is passed through the connecting portion 134 to the evaporating portion 136 of the condensed water evaporating means 130 provided at the lower end of the hot sink 111. Moving.

  On the other hand, since the condensed water evaporation means 130 is seated on the seating portion 140, the condensed water absorbed by the condensed water evaporation means 130 is prevented from flowing out into the heat exchange unit 110.

  At this time, heat generated while the heat transfer element 126 receiving power from the power supply device is operated is transmitted to the hot sink 111.

  The heat of the hot sink 111 heats the temperature of the condensed water absorbed by the evaporation unit 136 of the condensed water evaporation means 130 to a temperature of about 35 ° C. or more at which evaporation is improved.

  The condensed water heated by the evaporation unit 136 of the condensed water evaporation unit 130 is evaporated to the outside through the discharge unit 118.

  At this time, the temperature of the hot sink 111 is about 40 to 50 ° C. or higher, and the temperature of the discharged air is about 35 to 40 ° C.

  Therefore, the condensed water absorbed by the absorption part 132 of the condensed water evaporation means 130 moves to the evaporation part 136 through the connecting part 134.

  The condensed water moved to the evaporation unit 136 is evaporated to the outside through the discharge unit 118 by the heat of the heat generating fin unit 112.

  Condensed water absorbed by the absorption unit 132 as the condensed water evaporates in the evaporation unit 136 is then supplied to the evaporation unit 136 via the connecting unit 134.

  In addition, in order to improve the evaporation of the condensed water in the evaporation unit 136 of the condensed water evaporation means 130, a heater 160 for heating the temperature of the condensed water to a predetermined temperature is provided to rapidly evaporate the condensed water.

  At this time, the temperature of the heater 160 is not dangerous to the human body, for example, the temperature is detected by the temperature sensor 150 provided in the evaporation unit 136 of the condensed water evaporation means 130 so as to maintain a temperature of 60 ° C. or less.

  The detected temperature information is transmitted to the controller 170, and the temperature of the heater 160 is controlled to be maintained at a temperature of 60 ° C. or less under the control of the controller 170.

  The controller 170 senses the presence or absence of condensed water in the absorber 132 through a condensed water sensor 152 provided in the absorber 136 of the condensed water evaporation means 130.

  Information on the presence or absence of the detected condensed water is transmitted to the control unit 170, and when the control unit 170 determines that there is no condensed water, the power supply unit 172 is turned off and the heater 160 is turned off. .

  On the other hand, it is desirable that the condensed water evaporating means 130 is composed of capillary fibers that improve absorption and evaporation.

  For reference, capillary fibers currently used are ultrafine fibers of 1/100 mm or less, and such finely processed fibers are known to have a capacity of absorbing water three times or more than that of general fibers.

  The heat generated by the operation of the power supply device 105 is absorbed through the communication pipe 117 by the absorption force of the heat radiating fan 114 and discharged to the discharge unit 118.

  A plurality of through holes 103 are formed in the cover 102 covering the upper portion of the case 101, particularly at the position of the power supply device 105.

  When the through hole 103 is formed and heat generated in the power supply device is released to the outside through the discharge unit 118, a part of the heat is released through the through hole 103, thereby The heat generated in the supply device 105 can be released more smoothly.

  FIG. 13 shows another embodiment of the present invention, in which the cooling fin portion of the cool sink is formed in a round bar shape, and the cooling fin portion 122a of the cool sink 121a includes a plurality of cooling fin portions 122a. The condensed water formed in a round bar shape and generated in the condensing part 128 of the cooling fin part 122a smoothly flows down to the absorbing part 132 of the condensed water evaporating means 130.

  FIGS. 14 and 15 show a state in which the wire is fastened to the cooling fin of the cool sink of the cool sink according to the present invention, and the condensation generated in the agglomeration portion 128 of the cooling fin portion 122a of the cool sink 121a. The water falls on the absorption part 132 only by the amount of the condensed water generated, that is, when the condensed water becomes water droplets of a certain size.

  Accordingly, a plurality of wires 180 wound in the vertical direction are provided on the agglomeration part 128 where the condensed water of the round fin shaped cooling fin part 122a is agglomerated.

  Therefore, regardless of the amount of water droplets generated in the cooling fin portion 122a, the round bar-shaped cooling fin is configured so as to be able to immediately flow down to the absorption portion 132 along the wire 180 whenever condensed water is generated. Condensed water is prevented from remaining in the portion 122a.

  FIGS. 16 and 17 show a state in which the partition plate is provided in the round fin-shaped cooling fin portion of the cool sink of the present invention, and a plurality of prepared condensate condensing portions 128a of the cooling fin portion 122a are shown. Each partition plate 182 is provided and the cooling fin portion 122a has the same effect as that provided with the wire 180.

  As is often seen in the above-described embodiment, the present invention does not require a water distribution device that receives and treats separate condensed water, and can prevent electrical shock and malfunction due to condensed water.

  18 and 19 show still another embodiment of the present invention in which a heat insulating spacer is provided, and a heat insulating spacer for preventing heat transfer between the hot sink 211 and the cool sink 221. 240.

  The heat insulating spacer 240 has a screw shaft 242 that is fastened to the hot sink 211, and a screw hole 244 that is fastened to the bolt 230 inserted into the cool sink 221 on the other side. The cool sink 221 includes seating grooves 219 and 229 on which the heat insulating spacer 240 is seated.

  Therefore, the metal bolt 230, which is a fixing means for fixing the hot sink 211 and the cool sink 221 to each other, is not directly fastened and fixed to the hot sink 211, but an insulating spacer 240 having an insulating effect is provided in the middle. The hot sink 211 and the cool sink 221 are fixed to each other so that the heat insulation effect is excellent.

  Further, the heat pumping loss of the heat transfer element 226 in which the heat of the hot sink 211 is transferred to the cool sink 221 side is prevented.

  Further, when the heat insulating spacer 240 is not provided between the hot sink 211 and the cool sink 221, the thermal conductivity of the metallic bolt 230 is 58.9 to 41.8 [w / mk].

  However, the thermal conductivity of the metallic bolt 230 is reduced to 2.09 to 1.57 [w / mk] by providing the heat insulating spacer 240 for preventing the heat transfer.

  As a result, the structure of the bolt 230 that couples the hot sink 211 and the cool sink 221 has a heat insulation effect of up to 29 times.

  Then, a heat insulating protrusion 216 on which the heat transfer element 226 is seated is formed on the inner surface of the hot sink so as to widen the space between the hot sink 211 and the cool sink 221, thereby further increasing the thickness of the heat insulating member 250. This can increase the heat insulation effect.

  At this time, the heat insulating member 250 includes a heat insulating member 250 in the space between the hot sink 211 and the cool sink 221, that is, around the heat insulating protrusion 216, and heat generated in the hot sink 211 is transmitted to the cool sink 221. To prevent.

  FIG. 20 shows another embodiment in which the heat insulating member of the present invention is provided, and the heat insulating member 250 a provided between the hot sink 211 and the cool sink 221 is a heat insulating protrusion 219 of the hot sink 211. Have the same thickness.

  Accordingly, a space portion having a thickness of the heat transfer element 226 is separately formed between the hot sink 211 and the cool sink 221 so that heat generated in the hot sink 211 is transmitted to the cool sink 221 by the heat insulating member 250a. Shut off primarily.

  And the heat | fever is interrupted | blocked secondarily in the said space part, and the double heat insulation effect is provided.

  Although preferred embodiments of the present invention have been described in detail, those skilled in the art to which the present invention pertains may depart from the spirit and scope of the present invention as defined in the appended claims. It will be appreciated that the present invention can be practiced with various modifications or alterations.

  As described above, according to the present invention, the condensed water is evaporated by the heat generated in the hot sink of the heat exchange unit.

  In addition, a heater is provided in the evaporation part of the condensed water evaporation means, and the condensed water is evaporated by the heat generated in the heat radiation fin part, and the condensed water is evaporated by the heat of the heater. The condensed water can be evaporated into the outside air.

  The power supply device that receives and applies power to drive the computer and the heat exchange unit are integrally formed, and the volume when installed inside the computer is small and the occupied space is reduced.

  Further, by providing a heat insulating spacer between the hot sink and the cool sink, the metallic bolt to which the cool sink is fastened is prevented from coming into direct contact with the hot sink, thereby reducing the heat loss.

FIG. 1 is an overall configuration diagram of a heat exchange unit equipped with a condensate treatment apparatus according to the present invention. FIG. 2 is a perspective view of a heat exchange unit equipped with a condensate treatment apparatus according to the present invention. FIG. 3 is an exploded perspective view of a heat exchange unit equipped with a condensate treatment apparatus according to the present invention. FIG. 4 is a cross-sectional view showing a state in which the absorption part of the condensed water evaporation means of the present invention is located in the cooling fin part. FIG. 5 is a cross-sectional view showing a state in which the evaporating part of the condensed water evaporating means of the present invention is located in the radiating fin part. FIG. 6 is an overall configuration diagram of a heat exchange unit including a condensate treatment apparatus according to another embodiment of the present invention. FIG. 7 is a condensed water evaporation system diagram of a heat exchange unit equipped with a condensed water treatment apparatus according to another embodiment of the present invention. FIG. 8 is a perspective view of a heat exchange unit including a condensate treatment apparatus according to another embodiment of the present invention. FIG. 9 is an exploded perspective view of a heat exchange unit including a condensate treatment apparatus according to another embodiment of the present invention. FIG. 10 is a cut-away cross-sectional view of a main part of a combined state of a heat exchange unit including a condensate treatment apparatus according to another embodiment of the present invention. FIG. 11 is a cross-sectional view showing a state in which the absorption part of the condensed water evaporation means according to another embodiment of the present invention is located in the cooling fin part. FIG. 12 is a cross-sectional view showing a state in which the evaporating part of the condensed water evaporating means according to another embodiment of the present invention is located in the heat radiating fin part. FIG. 13 is a perspective view showing a state in which the cooling fin portion of the cool sink is formed of a round bar according to another embodiment of the present invention. FIG. 14 is a perspective view showing another embodiment of the present invention in which a wire is provided on a round fin-shaped cooling fin portion of a cool sink. 15 is a cross-sectional view taken along line AA in FIG. FIG. 16 is a perspective view showing a state in which the partition plate is provided in the round fin-shaped cooling fin portion of the cool sink of the present invention. 17 is a cross-sectional view taken along line BB in FIG. FIG. 18 is an exploded perspective view showing another embodiment of the present invention in which a heat insulating spacer and a heat insulating member are provided. FIG. 19 is a sectional view of the coupled state showing the coupled state of FIG. FIG. 20 is a cross-sectional view showing another embodiment in which the heat insulating member of the present invention is provided.

Explanation of symbols

1,110,210 Heat exchange unit 10,111,211 Hot sink 12,112,212 Radiation fin part 14,114 Radiation fan 16,116,216 Thermal insulation protrusion 18,118 Discharge part 20,20a, 121,121a, 221 Cool sink 22, 22a, 122, 122a Cooling fin part 24, 124 Cooling fan 26, 126, 226 Heat transfer element 27, 127 Air duct 28, 28a, 128, 128a Condensing part 30, 130 Condensate water evaporation means 32, 132 Absorption Unit 34,134 connection unit 36,136 evaporation unit 40,140 seating unit 50,52,150,152 sensing sensor 60,160 heater 70,170 control unit 72,172 power supply unit 105 power supply device 106 power supply connection port 107 Septum 108, 108a, 108b, 50,250a insulating member 180 a wire 182 partition plate 219 and 229 receiving recess 240 insulating spacer 242 screw shaft

Claims (25)

A heat sink having a heat sink, a cool sink having a cooling fan, and a heat exchange unit disposed between the hot sink and the cool sink; and provided in the heat exchange unit A heat exchange unit comprising a condensed water treatment device, comprising condensed water evaporation means for absorbing condensed water generated in a cool sink and evaporating condensed water in the air by the heat of the hot sink. The heat exchange unit of claim 1,
The heat exchange unit provided with a condensed water treatment device, wherein the condensed water evaporation means is a capillary fiber. The heat exchange unit of claim 1,
The condensed water evaporation means includes an absorption part positioned at the lower end of the cooling fin part of the cool sink; an evaporation part positioned at the lower end of the discharge part of the hot sink; and a connecting part that connects the absorption part and the evaporation part A heat exchange unit comprising a condensed water treatment apparatus, characterized in that it is configured. The heat exchange unit of claim 3,
The heat exchange unit having a condensate treatment apparatus, further comprising a seating portion on which the condensate evaporation means is seated. The heat exchange unit of claim 3,
A condensed water sensing sensor disposed in the absorption part of the condensed water evaporating means; a temperature sensing sensor disposed in the evaporation part; a heater disposed in the evaporation part; and the condensed water sensing sensor and temperature sensing sensor. The heat exchange unit provided with the condensed water processing apparatus characterized by further including the control part which drives a heater by the signal of. The heat exchange unit of claim 3,
A heat exchange unit having a condensed water treatment device, wherein the cooling fin portion of the cool sink is formed of a round-bar shaped cooling fin. The heat exchange unit of claim 6,
The round bar-shaped cooling fin is wound up by a wire, and is a heat exchange unit equipped with a condensed water treatment device. The heat exchange unit of claim 6,
The round bar-shaped cooling fin portion includes a plurality of partition plates, and the heat exchange unit includes a condensate treatment apparatus. The heat exchange unit according to claim 1 or 2,
A heat exchange unit comprising a condensed water treatment apparatus, further comprising a case and a cover, wherein the cover is formed with a plurality of through holes.   A case in which a partition wall is formed laterally in an inner intermediate portion; a cover that covers the upper portion of the case; a power supply device disposed in the case inner partition wall; and a heat exchange unit disposed in a lower portion of the case inner partition wall The heat exchange unit includes a hot sink having a heat radiating fan, a cool sink having a cooling fan, and a heat transfer element disposed between the hot sink and the cool sink. Heat exchange unit equipped with a device. The heat exchange unit of claim 10,
A heat exchange unit comprising a condensed water treatment device, further comprising condensed water evaporation means for absorbing condensed water generated in the cool sink and evaporating condensed water in the air by heat of the hot sink. The heat exchange unit of claim 11,
The heat exchange unit provided with a condensed water treatment device, wherein the condensed water evaporation means is a capillary fiber. The heat exchange unit of claim 11,
The condensed water evaporation means includes an absorption part positioned at the lower end of the cooling fin part of the cool sink; an evaporation part positioned at the lower end of the discharge part of the hot sink; and a connecting part that connects the absorption part and the evaporation part A heat exchange unit comprising a condensed water treatment apparatus, characterized in that it is configured. The heat exchange unit of claim 13,
The heat exchange unit having a condensate treatment apparatus, further comprising a seating portion on which the condensate evaporation means is seated. The heat exchange unit of claim 13,
A condensed water sensing sensor disposed in the absorption part of the condensed water evaporating means; a temperature sensing sensor disposed in the evaporation part; a heater disposed in the evaporation part; and the condensed water sensing sensor and temperature sensing sensor. The heat exchange unit provided with the condensed water processing apparatus characterized by further including the control part which drives a heater by the signal of. The heat exchange unit of claim 13,
A heat exchange unit having a condensed water treatment device, wherein the cooling fin portion of the cool sink is formed of a round bar-shaped cooling fin. The heat exchange unit of claim 16,
The round bar-shaped cooling fin is wound up by a wire, and is a heat exchange unit equipped with a condensed water treatment device. The heat exchange unit of claim 16,
The round bar-shaped cooling fin portion includes a plurality of partition plates, and the heat exchange unit includes a condensate treatment apparatus. The heat exchange unit of claim 10,
A heat exchange unit comprising a condensate treatment apparatus, further comprising a heat insulating member at a lower end portion and a side surface portion of the partition wall, wherein a plurality of through holes are formed in the cover. The heat exchange unit of claim 10,
A heat exchange unit comprising a condensate treatment device, further comprising a communication pipe so that the power supply device and the heat dissipating fan communicate with each other. The heat exchange unit of claim 10,
A heat exchange unit comprising a condensate treatment device, wherein the hot sink has a plurality of heat-insulating protrusions on which heat transfer elements are seated. The heat exchange unit of claim 10,
A heat exchange unit comprising a condensate treatment apparatus, wherein a heat insulating spacer is disposed between the hot sink and the cool sink. The heat exchange unit of claim 22,
The heat insulating spacer has a screw shaft that is fastened to a hot sink and a screw hole that is fastened to a bolt inserted into the cool sink on the other side. Replacement unit. The heat exchange unit of claim 22,
A heat exchange unit comprising a condensate treatment apparatus, wherein a seating groove in which the heat insulating spacer is seated is formed on the hot sink and the cool sink. The heat exchange unit of claim 10,
A heat exchange unit comprising a condensate treatment apparatus, wherein a heat insulating member is disposed between the hot sink and the cool sink.

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