WO2018110138A1

WO2018110138A1 - Cold air device

Info

Publication number: WO2018110138A1
Application number: PCT/JP2017/039837
Authority: WO
Inventors: 歩大村; 拓也片岡; 稲田　智洋; 千穂久保
Original assignee: 株式会社デンソー
Priority date: 2016-12-12
Filing date: 2017-11-03
Publication date: 2018-06-21
Also published as: JP2018096595A

Abstract

A cold air device for blowing out cold air, provided with a thermoelectric element (2), a cooling channel (3), a heat radiation channel (4), blowers (5, 6), and a movement unit (7). The thermoelectric element (2) has a heat absorption surface (21) and a heat radiation surface (22). In the cooling channel (3), air is cooled by the heat absorption surface (21) of the thermoelectric element (2). In the heat radiation channel (4), air is heated by the heat radiation surface (22) of the thermoelectric element (2). The blowers (5, 6) blow air to the cooling channel (3) and the heat radiation channel (4), respectively. The movement unit (7) moves condensed water generated from the air cooled in the cooling channel (3) to a location at which the condensed water can evaporate due to the heat from the heat radiation surface (22).

Description

Cold air device

Cross-reference to related applications

This application is based on Japanese Patent Application No. 2016-240552 filed on December 12, 2016, the description of which is incorporated herein by reference.

The present disclosure relates to a cold air device that blows out cold air.

Conventionally, a cold air device capable of cooling and blowing air is known. In the cold air device, the treatment of the condensed water generated when cooling the air becomes a problem.

Patent Document 1 describes an air conditioner mounted on a vehicle. This air conditioner stores the condensed water generated when air is cooled by an evaporator provided in the air conditioning case in the air conditioning case, and the ozone water generated by adding ozone to the condensed water is used to stop the vehicle. It is sprayed into the passenger compartment from the outlet. As a result, the air conditioner deodorizes the passenger compartment with ozone water and treats the condensed water generated in the evaporator.

JP 2014-12432 A

As a result of detailed studies by the inventors, the following problems were found in the air conditioner described in Patent Document 1. In other words, the air conditioner described in Patent Document 1 sprays ozone water containing ozone in condensed water into the vehicle interior without heating, and thus water droplets sprayed into the vehicle interior from the air outlet evaporate. Because it takes a long time to complete, the quick-drying property is low. Therefore, if water droplets sprayed into the passenger compartment adhere to an interior product such as a seat without evaporating, the interior product such as the seat may be deteriorated.

This disclosure is intended to provide a cold air device capable of quickly and reliably evaporating condensed water generated by air cooling.

According to one aspect of the present disclosure, a cold air device that blows out cold air,
A thermoelectric element having an endothermic surface and a heat dissipating surface;
A cooling passage in which air is cooled by the endothermic surface of the thermoelectric element;
A heat dissipation passage in which air is heated by the heat dissipation surface of the thermoelectric element;
A blower for blowing air to the cooling passage and the heat radiation passage,
And a moving unit that moves the condensed water generated from the air cooled in the cooling passage to a place where the condensed water can be evaporated by heat of the heat radiation surface.

According to this, the condensed water generated in the cooling passage absorbs heat generated from the heat radiation surface of the thermoelectric element and evaporates. Therefore, this cold air device can evaporate condensed water quickly and reliably. Therefore, this cold air device can prevent the condensed water from leaking from the cooling passage and can save the trouble of discarding the condensed water.

It is a figure which shows the structure of the cold wind apparatus of 1st Embodiment. It is a figure which shows the structure of the cold air apparatus of 2nd Embodiment. It is a figure which shows the structure of the cold air apparatus of 3rd Embodiment. FIG. 4 is an enlarged view of a portion IV in FIG. 3. FIG. 5 is a sectional view taken along line VV in FIG. 4. It is an enlarged view of the radiation fin with which the cold air apparatus of 4th Embodiment is provided. It is a figure which shows the structure of the cold wind apparatus of 5th Embodiment.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. In the following embodiments, parts that are the same or equivalent to each other will be described with the same reference numerals.

(First embodiment)
A first embodiment will be described with reference to the drawings. The cold air device of the present embodiment is attached to, for example, a backrest of a vehicle seat, and is used to prevent the occupant from falling asleep by blowing cold air toward the occupant seated in the seat. The cold air device is mounted on the vehicle as a product independent of the vehicle air conditioner.

As shown in FIG. 1, the cool air device 1 includes a Peltier element 2, a cooling passage 3, a heat radiating passage 4, a first blower 5, a second blower 6, a moving unit 7, and the like.

The Peltier element 2 is a plate-like thermoelectric element using the Peltier effect. The Peltier device 2 has a heat absorbing surface 21 that absorbs ambient heat when energized, and a heat radiating surface 22 that dissipates heat. One surface in the plate thickness direction of the Peltier element 2 is the heat absorbing surface 21, and the other surface in the plate thickness direction is the heat radiating surface 22.

The heat absorbing surface 21 of the Peltier element 2 is provided in the cooling passage 3. The air in the cooling passage 3 is cooled by being absorbed by the heat absorbing surface 21 of the Peltier element 2. Although not shown, the cooling passage 3 may be provided with a cold storage material for storing cold heat generated from the heat absorbing surface 21 of the Peltier element 2, and a heat radiation fin connected to the cold storage material. When air is cooled in the cooling passage 3, moisture contained in the air may condense and condensed water may be generated. This condensed water is processed by the moving unit 7 described later.

The air cooled in the cooling passage 3 is blown out from the cold air outlet 32.

The heat radiation surface 22 of the Peltier element 2 is provided in the heat radiation passage 4. In the heat radiation passage 4, heat radiation fins 43 connected to the heat radiation surface 22 of the Peltier element 2 are provided. The radiation fins 43 radiate heat generated from the heat radiation surface 22 of the Peltier element 2 to the air flowing through the heat radiation passage 4. Therefore, the air in the heat radiation passage 4 is heated by being radiated from the heat radiation surface 22 of the Peltier element 2.

The air heated in the heat radiation passage 4 is blown out from the hot air outlet 42.

The first blower 5 blows air to the cooling passage 3. The first blower 5 includes a centrifugal fan 51 and a motor (not shown) that rotates the centrifugal fan 51. The first case 52 that houses the centrifugal fan 51 of the first blower 5 and the cooling passage 3 communicate with each other via the first blower passage 53. As indicated by arrows AF1, AF2, and AF3, when the centrifugal fan 51 of the first blower 5 rotates, the air taken into the first case 52 from the rotational axis direction of the centrifugal fan 51 is first blown from the first case 52. It flows through the cooling passage 3 through the passage 53 and is blown out from the cold air outlet 32. Thereby, the air cooled by the heat absorbing surface 21 of the Peltier element 2 in the cooling passage 3 is blown out to the occupant from the cold air outlet 32 together with the air blown from the first blower 5. The first blower 5 is preferably driven after the air in the cooling passage 3 is sufficiently cooled by the heat absorbing surface 21 of the Peltier element 2.

The second blower 6 blows air to the heat radiation passage 4. The second blower 6 also has a centrifugal fan 61 and a motor (not shown) that rotates the centrifugal fan 61. The second case 62 that houses the centrifugal fan 61 of the second blower 6 and the heat dissipation passage 4 communicate with each other via the second blower passage 63. As indicated by arrows AF4, AF5, and AF6, when the centrifugal fan 61 of the second blower 6 rotates, the air taken into the second case 62 from the rotational axis direction of the centrifugal fan 61 is second blown from the second case 62. It flows through the heat dissipation passage 4 through the path 63 and is blown out from the hot air outlet 42. Thereby, the air heated by the heat radiation surface 22 of the Peltier element 2 in the heat radiation passage 4 is blown out from the hot air outlet 42 into the vehicle interior. In order to operate the Peltier element 2 satisfactorily, it is preferable that the second blower 6 is always driven to radiate heat continuously from the heat radiation surface 22 of the Peltier element 2.

The moving part 7 is a tubular drainage channel through which condensed water flows. One end of the moving unit 7 communicates with the first air passage 53 and the other end communicates with the heat dissipation passage 4. Specifically, one end of the moving unit 7 communicates with a portion of the first air passage 53 that is on the lower side in the gravity direction of the cooling passage 3. As described above, when the air is cooled in the cooling passage 3, moisture contained in the air may be condensed and condensed water may be generated. As indicated by an arrow CW 1, the condensed water drops on the lower side in the gravity direction of the cooling passage 3 and flows into the moving unit 7. The moving unit 7 moves the condensed water to the heat radiation passage 4.

A sprayer 72 is provided at the end of the moving part 7 on the side of the heat radiation passage 4. The sprayer 72 is composed of, for example, a piezo element. The sprayer 72 can make the condensed water mist by transmitting the ultrasonic vibration of the piezo element by energization to the condensed water. As indicated by the broken line CW <b> 2, the sprayer 72 sprays the condensed water flowing toward the heat radiation path 4 by the moving unit 7 into the heat radiation path 4. The condensed water sprayed by the sprayer 72 absorbs heat from the hot air flowing through the heat radiation passage 4 and evaporates. Thereby, the condensed water produced in the cooling passage 3 is promptly and reliably processed by the heat transmitted from the heat radiation surface 22 of the Peltier element 2. That is, it can be said that the nebulizer 72 is an example of an evaporation unit for evaporating the condensed water in the heat radiation passage 4.

The cold air device 1 of the first embodiment described above has the following operational effects.

(1) In the first embodiment, the moving unit 7 moves the condensed water generated from the air cooled in the cooling passage 3 to the heat radiation passage 4 where the condensed water can be evaporated by the heat of the heat radiation surface 22. .

According to this, the condensed water generated in the cooling passage 3 absorbs heat generated from the heat radiation surface 22 of the Peltier element 2 in the heat radiation passage 4 and evaporates. Therefore, this cold air device 1 can evaporate condensed water quickly and reliably. Therefore, the cold air device 1 can prevent the condensed water from leaking from the cooling passage 3 or the first air passage 53 and can save the trouble of discarding the condensed water.

(2) In the first embodiment, the moving unit 7 moves the condensed water generated from the air cooled in the cooling passage 3 to the heat radiation passage 4.

According to this, even when the portion where the condensed water generated in the cooling passage 3 flows and the heat radiating passage 4 are separated from each other, the moving portion 7 can move the condensed water to the heat radiating passage 4.

(3) In the first embodiment, the nebulizer 72 is an example of an evaporating unit for evaporating the condensed water moving to the heat radiation passage 4 by the moving unit 7 in the heat radiation passage 4.

According to this, by condensing condensed water with the atomizer 72 and spraying it on the air in the heat radiation passage 4, it is possible to increase the surface area of the condensed water and evaporate the condensed water quickly and reliably.

(Second Embodiment)
A second embodiment will be described. In the second embodiment, the configuration of the evaporation unit is changed with respect to the first embodiment, and the other parts are the same as those in the first embodiment. Therefore, only the parts different from the first embodiment will be described.

As shown in FIG. 2, in the second embodiment, a hygroscopic material 73 is provided at the end of the moving unit 7 on the side of the heat radiation passage 4. The hygroscopic material 73 is provided in a state exposed to the air flowing through the heat dissipation path. The hygroscopic material 73 is made of, for example, a nonwoven fabric or a porous material. The hygroscopic material 73 is an example of a water retention structure capable of retaining the condensed water that has flowed from the moving unit 7 toward the heat radiation passage 4. The condensed water retained in the moisture absorbent 73 absorbs heat from the hot air flowing through the heat radiation passage 4 and evaporates. Thereby, the condensed water produced in the cooling passage 3 absorbs heat transmitted from the heat radiation surface 22 of the Peltier element 2 and is quickly and reliably processed. That is, it can be said that the hygroscopic material 73 is an example of an evaporation part for evaporating the condensed water in the heat radiation passage 4. Therefore, the second embodiment can achieve the same operational effects as the first embodiment.

(Third embodiment)
A third embodiment will be described. The third embodiment is obtained by changing the configuration of the moving unit 7 and the heat radiating fins 43 and the like with respect to the first and second embodiments, and is otherwise the same as the first and second embodiments. Only portions different from the first and second embodiments will be described.

As shown in FIG. 3, in the third embodiment, a drain tank 74 is provided on the lower side of the first air passage 53 in the direction of gravity. As indicated by an arrow CW 3, the condensed water generated in the cooling passage 3 flows downward from the cooling passage 3 in the gravity direction and is stored in the drain tank 74.

The moving unit 7 connects the drain tank 74 and the heat radiation fins 43 provided inside the heat radiation passage 4. Specifically, one end of the moving unit 7 is inserted inside the drain tank 74, passes through a hole 46 provided in the wall of the heat radiation passage 4 in the heat radiation passage 4, and the other end contacts the heat radiation fin 43. .

The moving unit 7 includes a tubular water supply pipe 76 and a capillary member 75 provided inside the water supply pipe 76. The capillary member 75 is made of a nonwoven fabric or a porous material. As indicated by an arrow CW4, the capillary member 75 included in the moving unit 7 can move the condensed water stored in the drain tank 74 to the heat radiating fins 43 by capillary action.

In addition, it may replace with the structure mentioned above and the moving part 7 may be comprised only with the capillary member 75. FIG. In that case, the capillary member 75 can have a tubular shape, a rod shape, a plate shape, or the like.

Furthermore, as shown in FIGS. 4 and 5, in the third embodiment, the radiating fins 43 provided inside the radiating passage 4 have one or a plurality of grooves 44 to which condensed water can adhere. is doing. The groove 44 is capable of adhering condensed water to the surface of the heat radiation fin 43 and spreading the condensed water over the entire surface of the heat radiation fin 43 by capillary action and surface tension of the condensed water. Note that the shape, depth, number, pitch, and the like of the grooves 44 provided in the radiating fins 43 are not limited to those shown in FIGS. 4 and 5 and can be arbitrarily set.

When the condensed water stored in the drain tank 74 moves to the radiating fins 43 by the capillary member 75, the condensed water spreads over the entire surface of the radiating fins 43. The condensed water absorbs heat from the radiation fins 43 and evaporates. Thereby, the condensed water produced in the cooling passage 3 is promptly and reliably processed by the heat transmitted from the heat radiation surface 22 of the Peltier element 2.

Furthermore, according to this structure, since the radiation fins 43 are cooled by the heat of vaporization when the condensed water evaporates, the radiation efficiency of the radiation fins 43 is improved compared to cooling the radiation fins 43 only with air. . Therefore, the Peltier element 2 can increase the cooling capacity of the air by the heat absorbing surface 21.

The cold air device 1 of the third embodiment described above has the following operational effects.

(1) In the third embodiment, the moving unit 7 moves the condensed water generated from the air cooled in the cooling passage 3 to the radiation fins 43.

According to this, it is possible to quickly and surely evaporate condensed water in the heat radiation passage by using heat transmitted from the heat radiation surface 22 of the Peltier element 2 to the heat radiation fins 43.

Moreover, since the heat radiation fins 43 are cooled by the heat of vaporization when the condensed water evaporates, the heat radiation efficiency of the heat radiation fins 43 is improved compared to cooling the heat radiation fins 43 only with air. Therefore, it is possible to maintain the heat transfer capability between the heat radiating surface 22 and the heat absorbing surface 21 when energization to the Peltier element 2 is continued. Therefore, the cold air device 1 can increase the cooling capacity of the air using the heat absorbing surface 21 of the Peltier element 2 in the cooling passage 3.

(2) In the third embodiment, a drain tank 74 that stores condensed water dropped from the cooling passage 3 is provided.

According to this, even when the amount of condensed water generated in the cooling passage 3 increases, the cold air device 1 condenses from the cooling passage 3 or the first air passage 53 by storing the condensed water in the drain tank 74. Water leakage can be prevented.

(3) In the third embodiment, the moving unit 7 has a capillary member 75 that moves the condensed water stored in the drain tank 74 to the heat radiating fins 43 by capillary action.

According to this, even when the heat dissipating fins 43 are located higher in the direction of gravity than the drain tank 74, the moving unit 7 moves the condensed water to the heat dissipating fins 43 using the capillary phenomenon of the capillary member 75. Can do.

(4) In the third embodiment, the radiating fin 43 has a groove 44 capable of spreading condensed water on the surface of the radiating fin 43.

According to this, the contact area between the radiating fins 43 and the condensed water increases, and the amount of heat transferred from the radiating fins 43 to the condensed water increases. Therefore, it is possible to evaporate condensed water quickly and reliably.

Further, by spreading the condensed water on the surface of the radiation fins 43, it is possible to cool the radiation fins 43 in a wide range by the heat of vaporization when the condensed water evaporates.

(Fourth embodiment)
A fourth embodiment will be described. 4th Embodiment changes the structure of the radiation fin 43 with respect to 3rd Embodiment, Since others are the same as that of 3rd Embodiment, only a different part from 3rd Embodiment is demonstrated.

As shown in FIG. 6, in the fourth embodiment, the surface 45 of the heat radiating fin 43 is formed to have a surface roughness capable of spreading condensed water. As a result, when condensed water adheres to the surface 45 of the radiating fin 43, the condensed water spreads over the entire surface 45 of the radiating fin 43. In addition, the shape of the surface 45 of the radiation fin 43, the depth of the unevenness | corrugation of the surface 45, etc. are not restricted to what was shown in FIG. 6, It is possible to set arbitrarily.

The fourth embodiment can also exhibit the same operational effects as the third embodiment.

(Fifth embodiment)
A fifth embodiment will be described. In the fifth embodiment, the configuration of the moving unit 7 is changed with respect to the third embodiment, and the other parts are the same as those in the third embodiment. Therefore, only the parts different from the third embodiment will be described.

As shown in FIG. 7, in the fifth embodiment, the moving unit 7 has one end communicating with the drain tank 74 and the other end communicating with the heat radiation passage 4. Specifically, one end of the moving unit 7 is inserted inside the drain tank 74, passes through a hole (not shown) provided in the wall of the heat radiation path 4 in the heat radiation path 4, and the other end is inside the heat radiation path 4. Has been inserted. The other end of the moving portion 7 is inserted into a portion of the heat radiation passage 4 on the upstream side of the air flowing through the heat radiation passage 4 with respect to the heat radiation fins 43. Note that the other end of the moving unit 7 may be brought into contact with the radiation fins 43. Further, an evaporation unit may be provided at the other end of the moving unit 7.

The moving unit 7 includes a tubular water supply pipe 76 and a capillary member 75 provided inside the water supply pipe 76. The capillary member 75 is made of a nonwoven fabric or a porous material. As indicated by arrows CW5 and CW6, the capillary member 75 included in the moving unit 7 causes the condensed water stored in the drain tank 74 to flow through the heat radiation path 4 with respect to the heat radiation fins 43 in the heat radiation path 4 due to capillary action. It is possible to move to a site upstream of the air. The condensed water that has moved to the heat radiation passage 4 adheres to the heat radiation fins 43 due to gravity or air flow. The condensed water absorbs heat from the radiation fins 43 and evaporates. Thereby, the condensed water produced in the cooling passage 3 is promptly and reliably processed by the heat transmitted from the heat radiation surface 22 of the Peltier element 2.

(Other embodiments)
The present disclosure is not limited to the above-described embodiment, and can be modified as appropriate. Further, the above embodiments are not irrelevant to each other, and can be combined as appropriate unless the combination is clearly impossible. In each of the above-described embodiments, it is needless to say that elements constituting the embodiment are not necessarily essential unless explicitly stated as essential and clearly considered essential in principle. Yes. Further, in each of the above embodiments, when numerical values such as the number, numerical value, quantity, range, etc. of the constituent elements of the embodiment are mentioned, it is clearly limited to a specific number when clearly indicated as essential and in principle. The number is not limited to the specific number except for the case. Further, in each of the above embodiments, when referring to the shape, positional relationship, etc. of the component, etc., the shape, unless otherwise specified and in principle limited to a specific shape, positional relationship, etc. It is not limited to the positional relationship or the like.

(1) In the above-described embodiment, the cold air device 1 that is attached to the backrest of the vehicle seat and used to prevent the passengers from falling asleep has been described. On the other hand, in other embodiment, there is no limitation in the installation place and usage method of the cold wind apparatus 1. FIG. For example, the cold air device 1 can be used for cooling a CPU of a personal computer or a small refrigerator.

(2) In the first and second embodiments described above, the moving section 7 is provided in the first air passage 53. In the third embodiment, the drain tank 74 is provided in the first air passage 53. On the other hand, in other embodiments, the moving unit 7 or the drain tank 74 is not limited to the first air passage 53, and may be provided at a position that is below the cooling passage 3 in the gravity direction. That is, the moving unit 7 or the drain tank 74 may be provided at a position where condensed water drops or flows down from the cooling passage 3. For example, when the cold air device 1 is installed with the surface on the front side of FIG. 1 in the direction of gravity, the moving unit 7 or the drain tank 74 is provided on the front side of the paper surface of FIG.

(3) In the third embodiment described above, the drain tank 74 is provided in the first air passage 53. On the other hand, in another embodiment, the drain tank 74 may be eliminated, and the moving unit 7 may be connected between the first air passage 53 and the heat radiating fins 43.

(4) In the embodiment described above, the cold air device 1 is configured to include the first blower 5 and the second blower 6. On the other hand, in another embodiment, the cool air device 1 may be configured to blow air to the cooling passage 3 and the heat radiation passage 4 by one blower. In that case, a switching door for switching the air flow may be installed in the air passage that communicates from the one air blower to the cooling passage 3 and the heat radiation passage 4.

(5) In the above-described embodiment, the configuration includes two Peltier elements 2. On the other hand, in other embodiments, the number of Peltier elements 2 is not limited, and the number of Peltier elements 2 may be one or three or more. Further, the thermoelectric element is not limited to the Peltier element 2 and may be any element in which a heat absorption surface and a heat dissipation surface are formed by energization.

(6) In the second embodiment described above, the hygroscopic material 73 has been described as an example of the water retention structure. On the other hand, in another embodiment, as another example of a water retention structure for evaporating condensed water in the heat radiating passage 4, a recess for storing condensed water may be provided on the inner wall of the heat radiating passage 4. As described above, the configuration of the evaporation unit is not limited to the above-described sprayer 72 and the hygroscopic material 73.

(7) In the first and second embodiments described above, a tubular drainage channel has been described as an example of the moving unit 7. On the other hand, in other embodiments, a capillary member may be provided inside the tubular drainage channel as the moving unit 7. Moreover, you may form the moving part 7 with a capillary member.

(Summary)
According to the 1st viewpoint shown by one part or all part of the above-mentioned embodiment, a cold wind apparatus is provided with a thermoelectric element, a cooling passage, a thermal radiation passage, an air blower, and a moving part. The thermoelectric element has a heat absorption surface and a heat dissipation surface. In the cooling passage, air is cooled by the heat absorption surface of the thermoelectric element. In the heat dissipation passage, air is heated by the heat dissipation surface of the thermoelectric element. The blower blows air through the cooling passage and the heat radiation passage. The moving unit moves the condensed water generated from the air cooled in the cooling passage to a place where the condensed water can be evaporated by the heat of the heat radiation surface.

According to the second aspect, the place where the moving unit moves the condensed water is the heat dissipation passage.

According to this, the condensed water generated in the cooling passage absorbs heat generated from the heat dissipation surface in the heat dissipation passage and evaporates. Therefore, this cold air device can evaporate condensed water quickly and reliably.

According to the third aspect, the cold air device further includes an evaporation section for evaporating the condensed water that moves to the heat radiation path by the moving section in the heat radiation path.

According to this, the evaporating part evaporates the condensed water in the heat radiation passage, so that the condensed water can be treated promptly and reliably. In addition, as an evaporation part, various things, such as a sprayer or a water retention structure, are illustrated, for example.

According to a fourth aspect, the evaporation unit is a sprayer that sprays the condensed water that is moved to the heat radiation path by the moving unit onto the air that flows through the heat radiation path.

According to this, the surface area of the condensed water can be increased and the condensed water can be quickly and reliably evaporated by spraying the condensed water in the form of a mist with a sprayer and spraying it on the air in the heat radiation passage.

According to a fifth aspect, the evaporating unit is a water retention structure that retains the condensed water that has been moved to the heat radiation path by the moving unit.

According to this, it is possible to evaporate the condensed water in the air flowing through the heat radiation passage by the water retention structure retaining the condensed water in the heat radiation passage.

According to the sixth aspect, the water retention structure is a hygroscopic material.

According to this, it is possible to quickly and surely evaporate the condensed water by allowing the air in the heat radiation passage to flow on the surface of the hygroscopic material.

According to a seventh aspect, the cooling device further includes heat radiation fins provided on the heat radiation surface of the thermoelectric element inside the heat radiation space. The place where the moving part moves the condensed water is a radiation fin.

According to this, it is possible to quickly and reliably evaporate the condensed water using the heat transmitted from the heat radiation surface of the thermoelectric element to the heat radiation fin.

Also, since the heat radiation fin is cooled by the heat of vaporization when the condensed water evaporates, the heat radiation efficiency of the heat radiation fin is improved as compared with cooling the heat radiation fin only with air. Therefore, it is possible to maintain the heat transfer capability between the heat radiating surface and the heat absorbing surface when energization of the thermoelectric element is continued. Therefore, this cold air device can enhance the cooling capacity of air using the heat absorption surface of the thermoelectric element in the cooling passage.

According to the eighth aspect, the cold air device further includes a drain tank for storing condensed water dripped from the cooling space. The moving unit moves the condensed water stored in the drain tank to the radiation fin.

According to this, it is possible to prevent the condensed water from leaking from the cooling passage or the like by storing the condensed water in the drain tank.

According to the ninth aspect, the radiating fin has a groove capable of spreading condensed water on the surface of the radiating fin.

According to this, since the amount of heat transferred from the radiating fins to the condensed water increases, the condensed water can be evaporated quickly and reliably. Moreover, it is possible to cool a radiation fin extensively with the heat of vaporization when condensed water evaporates.

According to the 10th viewpoint, the surface of the radiation fin is formed in the surface roughness which can spread condensed water.

According to this, when condensed water adheres to the surface of the radiation fin and the condensed water spreads on the surface of the radiation fin, the amount of heat transferred from the radiation fin to the condensed water increases, so the condensed water is quickly and reliably evaporated. It is possible. Moreover, it is possible to cool a radiation fin extensively with the heat of vaporization when condensed water evaporates.

According to the eleventh aspect, the moving part has a capillary member that moves the condensed water by capillary action.

According to this, even if there is a position where the portion where the condensed water drops from the cooling passage and the place where the condensed water evaporates are separated, and there is a height difference, the capillary member uses the capillary phenomenon, It can be moved to a place where condensed water is evaporated.

According to the 12th viewpoint, the capillary member is comprised including the nonwoven fabric or the porous material.

According to this, a nonwoven fabric or a porous material is illustrated as a material which comprises a capillary member.

According to the thirteenth aspect, the thermoelectric element is a Peltier element.

According to this, a Peltier device is exemplified as the thermoelectric device.

Claims

A cold air device that blows out cold air,
A thermoelectric element (2) having an endothermic surface (21) and a heat dissipating surface (22);
A cooling passage (3) in which air is cooled by the endothermic surface of the thermoelectric element;
A heat dissipation passage (4) in which air is heated by the heat dissipation surface of the thermoelectric element;
Blowers (5, 6) for blowing air to the cooling passage and the heat dissipation passage,
A cool air device comprising: a moving unit (7) configured to move the condensed water generated from the air cooled in the cooling passage to a place where the condensed water can be evaporated by heat of the heat radiation surface.
The cold air device according to claim 1, wherein the place where the moving unit moves the condensed water is the heat dissipation passage.
The cold air device according to claim 1 or 2, further comprising an evaporating section (72, 73) for evaporating the condensed water moving to the heat radiating path by the moving section in the heat radiating path.
The cold air device according to claim 3, wherein the evaporating unit is a sprayer (72) for spraying the condensed water moving to the heat radiation passage by the moving unit onto the air flowing through the heat radiation passage.
The cold air device according to claim 3, wherein the evaporating unit is a water retaining structure (73) for retaining the condensed water moved to the heat radiation path by the moving unit.
The cold air device according to claim 5, wherein the water retention structure is a hygroscopic material.
A heat dissipating fin (43) provided on the heat dissipating surface of the thermoelectric element;
The cold wind apparatus according to claim 1 or 2, wherein the moving part moves the condensed water in the heat radiating fin.
A drain tank (74) for storing condensed water dripped from the cooling passage;
The cold air device according to claim 7, wherein the moving unit moves the condensed water stored in the drain tank to the heat radiating fins.
The cold air device according to claim 7 or 8, wherein the heat radiation fin has a groove (44) capable of spreading condensed water on a surface of the heat radiation fin.
The cold air device according to any one of claims 7 to 9, wherein the surface (45) of the heat radiating fin is formed to have a surface roughness capable of spreading condensed water.
The cold air device according to any one of claims 1 to 10, wherein the moving unit includes a capillary member (75) that moves the condensed water by a capillary phenomenon.
The cold air device according to claim 11, wherein the capillary member includes a nonwoven fabric or a porous material.
The cold air device according to any one of claims 1 to 12, wherein the thermoelectric element is a Peltier element.