JP6887808B2 - Heat exchange mechanism - Google Patents

Description

The present invention relates to a heat exchange mechanism in a heat exhaust portion of an electronic refrigerator or the like.

Conventionally, those using this type of heat exchange mechanism include a heat source such as a thermo module, an external heat exchange member that heat-transfers contact with the heat source, and a fan motor for blowing air to the external heat exchange member. And an electronic refrigerator having a dust removing filter is known (see, for example, Patent Document 1). In such an electronic refrigerator, dust in the air is removed by the dust removing filter and clean air is sent to the external heat exchange member, so that the external heat exchange member is prevented from becoming dirty and the heat exchange efficiency is improved. Can be prevented from decreasing.

JP-A-2007-163008

However, in such a heat exchange mechanism, there is a possibility that the dust removing filter is clogged and the air blowing efficiency to the external heat exchange member is lowered, so that the heat exchange efficiency is lowered. In addition, some of the dust particles in the air are fine, and such fine dust passes through the dust removal filter and adheres to the external heat exchange member, so it is necessary to clean the external heat exchange member after all. It was.

An object of the present invention is to solve the above problems and to provide a heat exchange mechanism capable of easily cleaning while suppressing a decrease in the efficiency of air blown to a heat exchanger by a blower fan.

The heat exchange mechanism according to claim 1 of the present invention provides a heat source, a heat exchanger that is in heat transfer contact with the heat source, a blower fan for blowing air to the heat exchanger, and air from the blower fan. In a heat exchange mechanism having a blower path provided around the heat exchanger so as to be in contact with the heat exchanger, a wall portion that partitions the blower path has an opening, and the heat is generated from the opening. The end of the exchanger is exposed over the entire direction orthogonal to the direction of the wind, and has an auxiliary cover body that is detachably attached to the opening.

Further, in the heat exchange mechanism according to claim 2 of the present invention, in claim 1, the end portion of the heat exchanger, which is on the upstream side with respect to the wind generated by the blower fan, is exposed from the opening. is there.

Further, in the heat exchange mechanism according to claim 3 of the present invention, in claim 1 or 2, the auxiliary cover body forms a part of the ventilation path.

Further, the heat exchange mechanism according to claim 3 of the present invention has a casing in which a part thereof is formed by the wall portion in claims 1 or 2, and the opening is formed in the casing. , The auxiliary cover body is unevenly fitted to the casing so as to close the opening.

The heat exchange mechanism according to claim 1 of the present invention is configured as described above, whereby the auxiliary cover body is removed, a gap nozzle of a vacuum cleaner is inserted through the opening, and the nozzle is inserted into the heat exchanger. By hitting and sucking, the dust adhering to the heat exchanger can be easily removed.

Since the end of the heat exchanger, which is upstream of the wind generated by the blower fan, is exposed from the opening, it adheres to the end of the heat exchanger, which is the part to which the most dust adheres. The dust can be easily removed.

Further, when the auxiliary cover body forms a part of the blower path, the wind formed by the blower fan flows along the entire heat exchanger, and heat can be exchanged satisfactorily.

Further, it has a casing in which a part thereof is formed by the wall portion, the opening is formed in the casing, and the auxiliary cover body is unevenly fitted to the casing so as to close the opening. By matching, the auxiliary cover body can be easily attached and detached without using a tool or the like, so that the dust adhering to the heat exchanger can be removed more easily.

It is a front view of the electronic refrigerator using the heat exchange mechanism which shows the 1st Embodiment of this invention. The same is the left side view. The same is the rear view. The same is a cross-sectional view taken along the line AA. The same is an enlarged cross-sectional view taken along the line AA. The same is a rear view in the state where the auxiliary cover body is removed. The same is a sectional view taken along line BB with the auxiliary cover body removed. The same is the BB cross-sectional view which enlarged the main part in the state where the auxiliary cover body was removed. The same is a view showing the auxiliary cover body, (a) is a rear view, (b) is a sectional view taken along the line CC, and (c) is a plan view seen from the same direction as (b). FIG. 5 is an enlarged cross-sectional view of a main part of an electronic refrigerator using a heat exchange mechanism showing a second embodiment of the present invention. The same is an enlarged cross-sectional view of a main part in a state where the auxiliary cover body is removed. FIG. 5 is an enlarged cross-sectional view of a main part of an electronic refrigerator using a heat exchange mechanism showing a third embodiment of the present invention. The same is an enlarged cross-sectional view of a main part in a state where the auxiliary cover body is removed.

Hereinafter, the first embodiment of the present invention will be described with reference to FIGS. 1 to 9. Reference numeral 1 denotes an electronic refrigerator using the heat exchange mechanism 46 of the present invention. The electronic refrigerator 1 includes a main body 2, a door body 3, a cooling mechanism 4 which is a part of a heat exchange mechanism 46, and a cover portion 5. The main body 2, the door body 3, and the cooling mechanism 4 have known structures, respectively, but they will be described just in case.

The main body 2 has an outer frame body 6, an inner frame body 7, a front frame body 8, and a heat absorbing plate 9, and is surrounded by the outer frame body 6, the inner frame body 7, the front frame body 8, and the heat absorbing plate 9. The area is filled with the insulating material 10. The endothermic plate 9 is made of a thermally conductive metal such as aluminum. Further, an opening 11 is formed in the front portion of the main body 2. Further, a magnetized member 12 made of a ferromagnetic material such as iron is provided inside the front frame body 8. A tubular portion 13 is formed at the rear portion of the outer frame body 6, and a part of the cooling mechanism 4 is provided inside the tubular portion 13 surrounded by the tubular portion 13. Further, a pair of front leg portions 14 and a pair of rear leg portions 15 are provided in the lower portion of the main body 2. Further, a water receiving portion 16 is detachably attached to the lower portion of the main body 2.

The door body 3 includes an outer shell body 17 and a heat insulating material (not shown) provided in the outer shell body 17. Further, a handle portion 18 is provided on the front surface of the door body 3. Further, a magnet packing 19 is provided on the back surface of the door body 3. Then, when the opening 11 is closed by the door body 3, the magnet packing 19 is magnetically attracted to the magnetized member 12. The door body 3 is provided so as to be movable back and forth by a rail (not shown). In this way, the space surrounded by the door body 3 and the main body 2 that can be moved back and forth is the refrigerating room 20. Then, the basket 21 is detachably attached to the door body 3. That is, as the door body 3 moves back and forth, the basket 21 also moves back and forth.

The cooling mechanism 4 includes a thermo module 22 as a heat source, a heat transfer block 23 provided on the heat absorption side of the thermo module 22, and a heat sink 24 as a heat exchanger provided on the heat exhaust side of the thermo module 22. It is configured to have a blower fan 25. The heat transfer block 23 is formed in a rectangular parallelepiped shape by a metal having good thermal conductivity such as aluminum. Therefore, the heat transfer block 23 has two parallel surfaces. Then, one surface of the heat transfer block 23 is in heat transfer contact with the heat absorbing plate 9. Further, the other surface located on the opposite side of one surface of the heat transfer block 23 is in heat transfer contact with the surface on the heat absorption side of the thermo module 22. Further, the surface of the thermo module 22 on the heat exhaust side comes into heat transfer contact with the front surface of the base 26 of the heat sink 24. A plurality of fins 27 are formed in parallel on the rear surface of the base portion 26. In this example, the fins 27 are each formed in a flat plate shape and horizontally. Further, the heat sink 24 is extruded and formed of a metal having good thermal conductivity such as aluminum. Further, the blower fan 25 is provided behind the fin 27 at a slight interval. The blower fan 25 is arranged so as to send the wind F from the front to the rear. Further, a heat insulating member 28 is provided so as to surround the thermo module 22 and the heat transfer block 23. The heat insulating member 28 closes between the thermo module 22, the heat transfer block 23, and the tubular portion 13. Therefore, when the thermo module 22 and the blower fan 25 are energized, the heat of the refrigerating chamber 20 is transferred from the heat absorbing plate 9 to the thermo module 22 via the heat transfer block 23, and further from the thermo module 22. It moves to the heat sink 24, and is discharged to the outside air by the wind F generated by the blower fan 25 in the heat sink 24.

The cover portion 5 has a plurality of intake ports 30 formed on the side surface portions of the casing 29 constituting the cover portion 5. Further, an exhaust port 31 is formed slightly downward in the center of the back surface of the casing 29. Then, a pair of recesses 32, 32 are formed symmetrically on the back surface of the casing 29 so as to sandwich the exhaust port 31 from the left and right. Then, the blower fan 25 is arranged inside the exhaust port 31 and between the recesses 32 and 32. Further, openings 34 and 34 are formed in the rear walls 33 and 33 as wall portions which are the bottom surfaces of the recesses 32 and 32, respectively. The openings 34 and 34 are formed on the left and right outer sides of the recesses 32 and 32, respectively. That is, the opening 34 is formed on the right side of the recess 32 provided on the right side of the casing 29. Further, the opening 34 is formed on the left side of the recess 32 provided on the left side of the casing 29. The rear walls 33 and 33 are provided close to the rear ends of the fins 27 of the heat sink 24, respectively. Further, an upper wall (not shown) and a lower wall 35 as wall portions are formed inside the casing 29. The upper wall and the lower wall 35 are provided substantially parallel to the fins 27 so as to sandwich the heat sink 24 from above and below. Then, the ventilation path 36 is formed by the rear wall 33, the upper wall (not shown), and the lower wall 35. Therefore, the when actuating the blower fan 25, after air F from the left and right toward the center of the air flow path 36 flows, central configured to flow the wind F rearward from the air feed path 36. Moreover, it said the opening 34, the upstream end 37 of the heat sink 24 is exposed me throughout vertically. Then, engaging recesses 38 and 38 are formed in the recesses 32 and 32, respectively. These engaging recesses 38 and 38 are formed on the left and right outer sides of the recesses 32 and 32, respectively. That is, the engaging recess 38 is formed on the right side of the recess 32 provided on the right side of the casing 29. Further, the engaging recess 38 is formed on the left side of the recess 32 provided on the left side of the casing 29.

An auxiliary cover body 39 is detachably attached to the casing 29 constituting the cover portion 5. In the auxiliary cover body 39, recesses 40, 40 are formed corresponding to the recesses 32, 32 of the casing 29. That is, when the auxiliary cover body 39 is attached to the casing 29, the recesses 40, 40 enter the recesses 32, 32 of the casing 29, and the openings are opened by the front walls 41, 41 of the recesses 40, 40. 34 and 34 are blocked. When the auxiliary cover body 39 is attached to the casing 29, the front walls 41, 41 of the recesses 40, 40 come into contact with the rear walls 33, 33 of the casing 29, or are separated by a very short distance. Close to each other. That is, the front walls 41, 41 of the auxiliary cover body 39 substantially extend the rear walls 33, 33 to form a part of the ventilation path 36. Further, a through hole 42 is formed in the central portion of the auxiliary cover body 39 corresponding to the exhaust port 31 of the casing 29. That is, even if the auxiliary cover body 39 is attached to the casing 29, the exhaust port 31 can be opened by the through hole 42. Further, flexible pieces 43 and 43 are formed at the left and right ends of the auxiliary cover body 39, respectively, and the flexible pieces 43 and 43 correspond to the engaging recesses 38 and 38, respectively. , Engagement claws 44, 44 are formed. Then, by fitting these engaging claws 44, 44 into the engaging recesses 38, 38 in an uneven manner, the auxiliary cover body 39 is attached to the casing 29. Reference numerals 45 and 45 are reinforcing ribs for suppressing the bending of the auxiliary cover body 39. Then, the heat exchange mechanism 46 of the present invention is formed by the cooling mechanism 4, the ventilation path 36, and the auxiliary cover body 39.

Next, the operation of this embodiment will be described. First, the user installs the electronic refrigerator 1 at a predetermined position, and then connects a power plug (not shown) to a power source (not shown). By connecting the power plug to the power supply in this way, a current is supplied to the thermo module 22 and the blower fan 25 by a control circuit (not shown). The current supplied to the thermo module 22 flows so that the heat transfer block 23 side is the endothermic side and the heat sink 24 side is the heat exhaust side. On the other hand, the blower fan 25 operates so as to send the wind F from the heat sink 24 side to the rear by being supplied with an electric current.

As described above, when the thermo module 22 is energized, the heat in the refrigerating chamber 20 is transferred from the heat absorbing plate 9 to the thermo module 22 via the heat transfer block 23. Further, the heat transferred to the thermo module 22 is sent to the heat sink 24. As is well known, the heat sink 24 has a structure in which heat is easily exhausted to the air around the fins 27 because the surface area is increased by having the plurality of fins 27. Then, the blower fan 25 forms the wind F, and the wind F passes around the fins 27 of the heat sink 24 to exhaust heat from the heat sink 24 to the wind F. The wind F formed by the blower fan 25 is sucked into the cover portion 5 from the outside of the electronic refrigerator 1 through the intake port 30, and further passes through the blower path 36 to the heat sink 24. After being sent from the upstream end portion 37 to the central portion, the air is discharged from the exhaust port 31 to the outside of the electronic refrigerator 1 through the blower fan 25.

In the conventional structure, the intake port 30 is provided with a dust removing filter, but in the present embodiment, such a filter is not provided. This is because the filter itself becomes a resistance when forming wind even in a clean state. Therefore, in the present embodiment, the wind F can be efficiently sent to the heat sink 24 by the blow fan 25. On the other hand, since the air intake port 30 is not provided with the dust removing filter as in the conventional case, the dust (particularly cotton dust) contained in the outside air adheres to the heat sink 24. In particular, when the blower fan 25 is provided so as to form a wind F from the left and right to the center of the blower path 36 as in the present embodiment, dust is caught on the upstream end portion 37 of the heat sink 24. Accumulate. However, as described above, by removing the auxiliary cover body 39 from the casing 29, the upstream end portions 37, 37 of the heat sink 24 are exposed from the openings 34, 34, so that the upstream end portions 37 thereof are exposed. , 37 can be easily sucked and removed by a suction type vacuum cleaner equipped with a gap nozzle. Incidentally, the upstream end 37 of the heat sink 24, the entire vertical direction, i.e. by exposing I throughout a direction perpendicular to the direction of the wind F, has adhered to these upstream end 37, 37 All dust can be sucked and removed. That is, the present invention eliminates the conventionally required filter by improving the cleanability of the heat sink 24, thereby reducing the resistance when generating wind F and the heat exchange efficiency of the heat sink 24. Is to improve.

As described above, the front walls 41 and 41 of the auxiliary cover body 39 extend the rear walls 33 and 33 constituting the air passage 36 to substantially form a part of the air passage 36. Therefore, the wind F formed by the blower fan 25 flows to the heat sink 24 in the vicinity of the openings 34 and 34 with almost no disturbance. Therefore, since the wind F formed by the blower fan 25 flows smoothly along the entire heat sink 24, heat exchange between the heat sink 24 and the wind F can be satisfactorily performed.

Further, the flexible pieces 43, 43 are bent inward to release the engagement between the engaging recesses 38, 38 of the casing 29 and the engaging claws 44, 44 of the auxiliary cover body 39, thereby disengaging the engagement claws 44, 44. The auxiliary cover body 39 can be easily removed from the casing 29. On the contrary, by pushing the auxiliary cover body 39 forward so that the recesses 40, 40 of the auxiliary cover body 39 enter the recesses 32, 32 of the casing 29, the flexible pieces 43, 43 are bent and said. Since the engaging claws 44, 44 are unevenly fitted with the engaging recesses 38, 38 of the casing 29, the auxiliary cover body 39 can be easily attached to the casing 29. Therefore, the engaging claws 44, 44 of the auxiliary cover body 39 are unevenly fitted to the engaging recesses 38, 38 of the casing 29, so that the auxiliary cover body 39 can be easily fitted to the casing 29 without using a tool or the like. Since it can be attached to and detached from the heat sink 24, dust adhering to the heat sink 24 can be removed more easily.

As described above, the heat exchange mechanism 46 of the present invention includes a thermo module 22 as a heat source, a heat sink 24 as a heat exchanger that is in heat transfer contact with the thermo module 22, and a blower for blowing air to the heat sink 24. In a heat exchange mechanism 46 having a fan 25 and a blower path 36 provided around the heat sink 24 so that the air from the blower fan 25 comes into contact with the heat sink 24, as a wall portion for partitioning the blower path 36. The rear wall 33 has openings 34, 34, and the upstream end portions 37, 37 of the heat sink 24 are exposed from these openings 34, 34 over the entire direction orthogonal to the direction of the wind F. By having the auxiliary cover body 39 detachably attached to each of the openings 34, 34, the auxiliary cover body 39 is removed, a gap nozzle of the vacuum cleaner is inserted from the respective openings 34, 34, and this nozzle is inserted. Dust adhering to the heat sink 24 can be easily removed by applying the heat sink 24 to the upstream end portions 37, 37 and sucking the heat sink 24.

Further, in the heat exchange mechanism 46 of the present invention, the upstream end portions 37, 37 of the heat sink 24, which is on the upstream side with respect to the wind F generated by the blower fan 25, are exposed from the openings 34, 34. The dust adhering to the upstream end portions 37, 37 of the heat sink 24, which is the portion to which the most dust adheres, can be easily removed.

Further, in the heat exchange mechanism 46 of the present invention, the auxiliary cover body 39 forms a part of the blower path 36, so that the wind F formed by the blower fan 25 flows along the entire heat sink 24. It can exchange heat well.

Further, the heat exchange mechanism 46 of the present invention has a casing 29 in which a part thereof is formed by the rear wall 33, and the openings 34 and 34 are formed in the casing 29, and the auxiliary cover body 39 is formed. By fitting the casing 29 in an uneven manner so as to close the openings 34 and 34, the auxiliary cover body 39 can be easily attached and detached without using a tool or the like, so that dust adhering to the heat sink 24 can be removed. It can be removed more easily.

Next, a second embodiment of the present invention will be described with reference to FIGS. 10 and 11. The parts common to the first embodiment are designated by the same reference numerals and the description thereof will be omitted. Reference numeral 51 denotes an electronic refrigerator using the heat exchange mechanism 69 of the present invention. The electronic refrigerator 51 includes a main body 2, a door body (not shown), a cooling mechanism 52 which is a part of the heat exchange mechanism 69, and a cover portion 53. Since the main body 2 and the door body are the same as those in the first embodiment, the description thereof will be omitted. On the other hand, although the cooling mechanism 52 has a known structure, it will be described just in case.

The cooling mechanism 52 includes a thermo module 22 as a heat source, a heat transfer block 23 provided on the heat absorption side of the thermo module 22, and a heat sink 24 as a heat exchanger provided on the heat exhaust side of the thermo module 22. It is configured to have a blower fan 54. The blower fans 54 are provided at intervals on the sides of the fins 27 of the heat sink 24. The blower fan 54 is arranged so as to send the wind F from the left to the right in FIG. Therefore, when the thermo module 22 and the blower fan 54 are energized, the heat of the refrigerating chamber 20 is transferred from the heat absorbing plate 9 to the thermo module 22 via the heat transfer block 23, and further from the thermo module 22 to the thermo module 22. It moves to the heat sink 24, and is discharged to the outside air by the wind F generated by the blower fan 54 in the heat sink 24.

The cover portion 53 has a plurality of intake ports 56 formed on the side surface of the casing 55 constituting the cover portion 53 on the side where the blower fan 54 is provided. On the other hand, a plurality of exhaust ports 57 are formed on the side surface of the casing 55 opposite to the blower fan 54 with the heat sink 24 interposed therebetween. Further, a recess 58 is formed on the back surface of the casing 55. Further, an opening 60 is formed in the rear wall 59 as the wall portion of the recess 58. The opening 60 is formed on the side of the blower fan 54 of the recess 58. That is, in FIG. 10, it is formed on the left side portion of the recess 58. The bottom wall portion 61 of the rear wall 59 is provided close to the rear end of the fin 27 of the heat sink 24. Further, an upper wall (not shown) and a lower wall 62 as wall portions are formed inside the casing 55. The upper wall and the lower wall 62 are provided substantially parallel to the fins 27 so as to sandwich the heat sink 24 from above and below. Then, the ventilation path 63 is formed by the rear wall 59, the upper wall (not shown), and the lower wall 62. Therefore, when the blower fan 54 is operated, the wind F is configured to flow from the left to the right of the blower path 63 in FIG. Moreover, it said the opening 60, the upstream end 64 of the heat sink 24 is exposed me throughout vertically. Then, an engaging recess 65 is formed in the recess 58. The engaging recess 65 is formed on the left outer side of the recess 58.

An auxiliary cover body 66 is detachably attached to the casing 55 constituting the cover portion 53. Then, the opening 60 is closed by the auxiliary cover body 66. The auxiliary cover body 66 substantially extends the rear wall 59 to form a part of the ventilation path 63. Further, a flexible piece 67 is formed at the end of the auxiliary cover body 66, and an engaging claw 68 is formed in the flexible piece 67 corresponding to the engaging recess 65. Then, the auxiliary cover body 66 is attached to the casing 55 by fitting the engaging claw 68 in the engaging recess 65 in an uneven manner. Then, the heat exchange mechanism 69 of the present invention is formed by the cooling mechanism 52, the ventilation path 63, and the auxiliary cover body 66.

Next, the operation of this embodiment will be described. First, the user installs the electronic refrigerator 51 at a predetermined position, and then connects a power plug (not shown) to a power source (not shown). By connecting the power plug to the power supply in this way, a current is supplied to the thermo module 22 and the blower fan 54 by a control circuit (not shown). The current supplied to the thermo module 22 flows so that the heat transfer block 23 side is the endothermic side and the heat sink 24 side is the heat exhaust side. On the other hand, the blower fan 54 operates so as to send the wind F from the left to the right in FIG. 10 by being supplied with an electric current.

As described above, when the thermo module 22 is energized, the heat in the refrigerating chamber 20 is transferred from the heat absorbing plate 9 to the thermo module 22 via the heat transfer block 23. Further, the heat transferred to the thermo module 22 is sent to the heat sink 24. Then, the blower fan 54 forms the wind F, and the wind F passes around the fins 27 of the heat sink 24 to exhaust heat from the heat sink 24 to the wind F. The wind F formed by the blower fan 54 is sucked into the cover portion 53 from the outside of the electronic refrigerator 51 through the intake port 56, and further passes through the blower path 63 to the heat sink 24. After being sent from the upstream end portion 64 to the other end portion, the exhaust port 57 discharges the electronic refrigerator 51 to the outside.

In the conventional structure, the intake port 56 is provided with a dust removing filter, but in the present embodiment, such a filter is not provided. This is because the filter itself becomes a resistance when forming wind even in a clean state. Therefore, in the present embodiment, the wind F can be efficiently sent to the heat sink 24 by the blow fan 54. On the other hand, since the air intake port 56 is not provided with a dust removing filter as in the conventional case, dust (particularly cotton dust) contained in the outside air adheres to the heat sink 24. In particular, in the case of the so-called side-flow type heat exchange mechanism 69 as in the present embodiment, dust is caught and collected on the upstream end portion 64 of the heat sink 24. However, as described above, by removing the auxiliary cover body 66 from the casing 55, as shown in FIG. 11, the upstream end portion 64 of the heat sink 24 is exposed from the opening 60, and thus the end portion 64 is exposed. Dust adhering to the casing can be easily removed by suction with a suction type vacuum cleaner equipped with a gap nozzle. Incidentally, the upstream end 64 of the heat sink 24, the entire vertical direction, i.e. by exposing I throughout a direction perpendicular to the direction of the wind F, that all aspirate the dust adhering to the end portion 64 Can be done. That is, the present invention eliminates the conventionally required filter by improving the cleanability of the heat sink 24, thereby reducing the resistance when generating wind F and the heat exchange efficiency of the heat sink 24. Is to improve.

As described above, since the auxiliary cover body 66 extends the rear wall 59 constituting the blower path 63 to substantially form a part of the blower path 63, the blower fan 54 is formed. The wind F flows to the heat sink 24 in the vicinity of the opening 60 with almost no disturbance. Therefore, since the wind F formed by the blower fan 54 flows smoothly along the entire heat sink 24, heat exchange between the heat sink 24 and the wind F can be performed satisfactorily.

Further, by bending the flexible piece 67 to disengage the engaging recess 65 of the casing 55 from the engaging claw 68 of the auxiliary cover body 66, the auxiliary cover body 66 is formed by the casing 55. Can be easily removed from. On the contrary, when the auxiliary cover body 66 is attached to the opening 60, the flexible piece 67 bends and the engaging claw 68 is unevenly fitted with the engaging recess 65 of the casing 55. The cover body 66 can be easily attached to the casing 55. Therefore, the engaging claw 68 of the auxiliary cover body 66 is unevenly fitted to the engaging recess 65 of the casing 55, so that the auxiliary cover body 66 can be easily attached to and detached from the casing 55 without using a tool or the like. Therefore, the dust adhering to the heat sink 24 can be removed more easily.

As described above, the heat exchange mechanism 69 of the present invention includes a thermo module 22 as a heat source, a heat sink 24 as a heat exchanger that is in heat transfer contact with the thermo module 22, and a blower for blowing air to the heat sink 24. In a heat exchange mechanism 69 having a fan 54 and a blower path 63 provided surrounding the heat sink 24 so that the air from the blower fan 54 comes into contact with the heat sink 24, as a wall portion for partitioning the blower path 63. The rear wall 59 has an opening 60, and the upstream end portion 64 of the heat sink 24 is exposed from the opening 60 over the entire direction orthogonal to the direction of the wind F, and is attached to and detached from the opening 60. By having the auxiliary cover body 66 that can be attached, the auxiliary cover body 66 is removed, a gap nozzle of the vacuum cleaner is inserted from each of the openings 60, and this nozzle is applied to the upstream end portion 64 of the heat sink 24. By sucking, the dust adhering to the heat sink 24 can be easily removed.

Further, in the heat exchange mechanism 69 of the present invention, the upstream end portion 64 of the heat sink 24, which is upstream of the wind F generated by the blower fan 54, is exposed from the opening 60, so that the amount of dust is the largest. Dust adhering to the upstream end 64 of the heat sink 24, which is a sticking portion, can be easily removed.

Further, in the heat exchange mechanism 69 of the present invention, the auxiliary cover body 66 forms a part of the blower path 63, so that the wind F formed by the blower fan 54 flows along the entire heat sink 24. It can exchange heat well.

Further, the heat exchange mechanism 69 of the present invention has a casing 55 in which a part thereof is formed by the rear wall 59, the opening 60 is formed in the casing 55, and the auxiliary cover body 66 is the same. By fitting the casing 55 in an uneven manner so as to close the opening 60, the auxiliary cover body 66 can be easily attached and detached without using a tool or the like, so that dust adhering to the heat sink 24 can be removed more easily. can do.

Next, a third embodiment of the present invention will be described with reference to FIGS. 12 and 13. The parts common to each of the above embodiments are designated by the same reference numerals and the description thereof will be omitted. Reference numeral 71 denotes an electronic refrigerator using the heat exchange mechanism 89 of the present invention. The electronic refrigerator 71 includes a main body 2, a door body (not shown), a cooling mechanism 72 which is a part of the heat exchange mechanism 89, and a cover portion 73. Since the main body 2 and the door body are the same as those in the first embodiment, the description thereof will be omitted. On the other hand, although the cooling mechanism 72 has a known structure, it will be described just in case.

The cooling mechanism 72 includes a thermo module 22 as a heat source, a heat transfer block 23 provided on the heat absorption side of the thermo module 22, and a heat sink 24 as a heat exchanger provided on the heat exhaust side of the thermo module 22. It is configured to have a blower fan 74. The blower fans 74 are provided at intervals on the sides of the fins 27 of the heat sink 24. The blower fan 74 is arranged so as to send the wind F from the right to the left in FIG. Therefore, when the thermo module 22 and the blower fan 74 are energized, the heat of the refrigerating chamber 20 is transferred from the heat absorbing plate 9 to the thermo module 22 via the heat transfer block 23, and further, the heat sink from the thermo module 22. It moves to 24, and is discharged to the outside air by the wind F generated by the blower fan 74 in the heat sink 24.

A plurality of intake ports 76 are formed in the cover portion 73 on a side surface of the casing 75 constituting the cover portion 73, which is opposite to the blower fan 74 with the heat sink 24 interposed therebetween. On the other hand, a plurality of exhaust ports 77 are formed on the side surface of the casing 75 on the side where the blower fan 74 is provided. Further, a recess 78 is formed on the back surface of the casing 75. Further, an opening 80 is formed in the rear wall 79 as the wall portion of the recess 78. The opening 80 is formed in the recess 78 on the opposite side of the blower fan 74. That is, in FIG. 12, it is formed in the right side portion of the recess 78. The bottom wall portion 81 of the rear wall 79 is provided close to the rear end of the fin 27 of the heat sink 24. Further, an upper wall (not shown) and a lower wall 82 as wall portions are formed inside the casing 75. The upper wall and the lower wall 82 are provided substantially parallel to the fins 27 so as to sandwich the heat sink 24 from above and below. Then, the air passage 83 is formed by the rear wall 79, the upper wall (not shown), and the lower wall 82. Therefore, when the blower fan 74 is operated, the wind F is configured to flow from the right to the left of the blower path 83 in FIG. Moreover, it said the opening 80, the upstream end 84 of the heat sink 24 is exposed me throughout vertically. Then, an engaging recess 85 is formed in the recess 78. The engaging recess 85 is formed on the right outer side of the recess 78.

The auxiliary cover body 86 is detachably attached to the casing 75 constituting the cover portion 73. Then, the opening 80 is closed by the auxiliary cover body 86. The auxiliary cover body 86 substantially extends the rear wall 79 to form a part of the ventilation path 83. Further, a flexible piece 87 is formed at the end of the auxiliary cover body 86, and an engaging claw 88 is formed in the flexible piece 87 corresponding to the engaging recess 85. Then, the auxiliary cover body 86 is attached to the casing 75 by fitting the engaging claw 88 in the engaging recess 85 in an uneven manner. Then, the heat exchange mechanism 89 of the present invention is formed by the cooling mechanism 72, the ventilation path 83, and the auxiliary cover body 86.

Next, the operation of this embodiment will be described. First, the user installs the electronic refrigerator 71 at a predetermined position, and then connects a power plug (not shown) to a power source (not shown). By connecting the power plug to the power supply in this way, a current is supplied to the thermo module 22 and the blower fan 74 by a control circuit (not shown). The current supplied to the thermo module 22 flows so that the heat transfer block 23 side is the endothermic side and the heat sink 24 side is the heat exhaust side. On the other hand, the blower fan 74 operates so as to send the wind F from right to left in FIG. 12 by being supplied with an electric current.

As described above, when the thermo module 22 is energized, the heat in the refrigerating chamber 20 is transferred from the heat absorbing plate 9 to the thermo module 22 via the heat transfer block 23. Further, the heat transferred to the thermo module 22 is sent to the heat sink 24. Then, the blower fan 74 forms the wind F, and the wind F passes around the fins 27 of the heat sink 24 to exhaust heat from the heat sink 24 to the wind F. The wind F formed by the blower fan 74 is sucked into the cover portion 73 from the outside of the electronic refrigerator 71 through the intake port 76, and further passes through the blower path 83 to the heat sink 24. After being sent from the upstream end portion 84 to the other end portion, it is discharged to the outside of the electronic refrigerator 71 from the exhaust port 77.

In the conventional structure, the intake port 76 is provided with a dust removing filter, but in the present embodiment, such a filter is not provided. This is because the filter itself becomes a resistance when forming wind even in a clean state. Therefore, in the present embodiment, the wind F can be efficiently sent to the heat sink 24 by the blow fan 74. On the other hand, since the air intake port 76 is not provided with the dust removing filter as in the conventional case, the dust (particularly cotton dust) contained in the outside air adheres to the heat sink 24. In particular, in the case of the so-called side-flow type heat exchange mechanism 89 as in the present embodiment, dust is caught and collected on the upstream end portion 84 of the heat sink 24. However, as described above, by removing the auxiliary cover body 86 from the casing 75, as shown in FIG. 13, the upstream end portion 84 of the heat sink 24 is exposed from the opening 80, so that the end portion 84 The dust adhering to the dust can be easily removed by suction with a suction type vacuum cleaner equipped with a gap nozzle. Incidentally, the upstream end 84 of the heat sink 24, the entire vertical direction, i.e. by exposing I throughout a direction perpendicular to the direction of the wind F, that all aspirate the dust adhering to the end portion 84 Can be done. That is, the present invention eliminates the conventionally required filter by improving the cleanability of the heat sink 24, thereby reducing the resistance when generating wind F and the heat exchange efficiency of the heat sink 24. Is to improve.

As described above, since the auxiliary cover body 86 extends the rear wall 79 constituting the blower path 83 to substantially form a part of the blower path 83, the blower fan 74 is formed. The wind F flows to the heat sink 24 in the vicinity of the opening 80 with almost no disturbance. Therefore, since the wind F formed by the blower fan 74 flows smoothly along the entire heat sink 24, heat exchange between the heat sink 24 and the wind F can be satisfactorily performed.

Further, by bending the flexible piece 87 to disengage the engaging recess 85 of the casing 75 from the engaging claw 88 of the auxiliary cover body 86, the auxiliary cover body 86 is formed by the casing 75. Can be easily removed from. On the contrary, when the auxiliary cover body 86 is attached to the opening 80, the flexible piece 87 bends and the engaging claw 88 engages with the engaging recess 85 of the casing 75 in an uneven manner. The cover body 86 can be easily attached to the casing 75. Therefore, the engaging claw 88 of the auxiliary cover body 86 is unevenly fitted to the engaging recess 85 of the casing 75, so that the auxiliary cover body 86 can be easily attached to and detached from the casing 75 without using a tool or the like. Therefore, the dust adhering to the heat sink 24 can be removed more easily.

As described above, in the heat exchange mechanism 89 of the present invention, the thermo module 22 as a heat source, the heat sink 24 as a heat exchanger in heat transfer contact with the thermo module 22, and the air blown to blow air to the heat sink 24. In a heat exchange mechanism 89 having a fan 74 and a blower path 83 provided surrounding the heat sink 24 so that the air from the blower fan 74 comes into contact with the heat sink 24, as a wall portion for partitioning the blower path 83. The rear wall 79 has an opening 80, and the upstream end portion 84 of the heat sink 24 is exposed from the opening 80 over the entire direction orthogonal to the direction of the wind F, and is attached to and detached from the opening 80. By having the auxiliary cover body 86 that can be attached, the auxiliary cover body 86 is removed, a gap nozzle of the vacuum cleaner is inserted from each of the openings 80, and this nozzle is applied to the upstream end portion 84 of the heat sink 24. By sucking, the dust adhering to the heat sink 24 can be easily removed.

Further, in the heat exchange mechanism 89 of the present invention, the upstream end portion 84 of the heat sink 24, which is upstream of the wind F generated by the blower fan 74, is exposed from the opening 80, so that the amount of dust is the largest. Dust adhering to the upstream end portion 84 of the heat sink 24, which is a sticking portion, can be easily removed.

Further, in the heat exchange mechanism 89 of the present invention, the auxiliary cover body 86 forms a part of the blower path 83, so that the wind F formed by the blower fan 74 flows along the entire heat sink 24. It can exchange heat well.

Further, the heat exchange mechanism 89 of the present invention has a casing 75 in which a part thereof is formed by the rear wall 79, the opening 80 is formed in the casing 75, and the auxiliary cover body 86 is the same. By fitting the casing 75 in an uneven manner so as to close the opening 80, the auxiliary cover body 86 can be easily attached and detached without using a tool or the like, so that dust adhering to the heat sink 24 can be removed more easily. can do.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the gist of the invention. For example, in the first embodiment, the left and right openings 34, 34 are closed by one auxiliary cover body 39, but they may be closed by individual auxiliary cover bodies. Further, in each of the above embodiments, only the upstream end portions 37, 64, 84 of the heat sink 24 as the heat exchanger are exposed, but the heat sink 24 may be exposed to a wider area near the center portion.

22 Thermo module (heat source)
24 Heat sink (heat exchanger)
25,54,74 Blower fan 29,55,75 Casing 33,59,79 Rear wall (wall part)
34,60,80 Opening 36,63,83 Blower path 37,64,84 Upstream end 38,65,85 Engagement recess 39,66,86 Auxiliary cover 44,68,88 Engagement claw 46,69 , 89 Heat exchange mechanism

Claims (4)

A heat source, a heat exchanger that conducts heat transfer to the heat source, a blower fan for blowing air to the heat exchanger, and the heat exchanger so that the air from the blower fan comes into contact with the heat exchanger. In a heat exchange mechanism having a blower path provided around it,
The wall portion that partitions the ventilation path has an opening, from which the heat exchanger is exposed over the entire direction orthogonal to the direction of the wind, and an auxiliary that is detachably attached to the opening. A heat exchange mechanism characterized by having a cover body. The heat exchange mechanism according to claim 1, wherein an end portion of the heat exchanger, which is on the upstream side with respect to the wind generated by the blower fan, is exposed from the opening. The heat exchange mechanism according to claim 1 or 2, wherein the auxiliary cover body forms a part of the ventilation path. It has a casing whose part is formed by the wall portion, the opening is formed in the casing, and the auxiliary cover body is unevenly fitted to the casing so as to close the opening. The heat exchange mechanism according to claim 1 or 2, wherein the heat exchange mechanism is characterized in that.

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