JPH07180948A - Water drop vaporising device for cold storage case - Google Patents

Abstract

PURPOSE:To vaporize water drops in a heat insulating space at the outside of the heat insulating space by a method wherein rail members which are fixed to a heat insulating door and retaining a receiving case so as to be capable of carrying it in and out of the heat insulating space is provided with a passage for receiving discharged water drops while the absorbing material of the water drops is arranged at the end of the passage. CONSTITUTION:The front opening of a box-type heat insulating wall 11 is opened and closed by a heat insulating door 12 and a heat insulating space 13 is formed therein. Ducts 18, 19, whose both ends are communicated with outdoor air, are formed around the box-type heat insulating wall 11. Further, thermoelectric converting element 14 is arranged between the heat insulating space 13 and the ducts 18, 19. On the other hand, a receiving case 15, fixed to the heat insulating door 12, is retained by rail members 16 (16a, 16b) in the heat insulating space 13 so as to be capable of being carried into and out of the heat insulating space 13. Water drops, generated in the heat insulating space 13, are discharged out of the heat insulating space 13 through a drainage means. In this case, a moving side rail member 16a is provided with a passage 28 for receiving the discharged water while the absorbing material 30 of the water drops are provided at the ends of the passage 28 to arrange it in the duct 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water drop evaporation device in a cold storage, and is used for a cabinet arranged adjacent to a vanity or the like.

[0002]

2. Description of the Related Art As a conventional technique of this type of water drop evaporation device for a cold storage, there is known one disclosed in Japanese Utility Model Laid-Open No. 57-16777. This is because the cooling part of the thermoelectric conversion element is brought into thermal contact with the heat insulating space formed by the box-shaped heat insulating wall with the front surface as the opening and the heat insulating wall that opens and closes the opening, and the heat radiating part of the thermoelectric conversion element is exposed to the atmosphere. It is a cool box that is in thermal contact with.

In this cool box, water drops generated in the heat insulating space are drained to a water storage tank through a drain hole provided in the lower part of the heat insulating space.

[0004]

In the above-mentioned conventional technique, the drained water drops are stored in the drawer-shaped water storage tank, but the drainage stored in this water storage tank must be discarded outside the cold storage.

If this is neglected and the capacity of the water storage tank exceeds the capacity, if it is left as it is, the drainage water leaks from the water storage tank and the outside of the cold storage is moistened by the drainage.

An object of the present invention is to evaporate water droplets generated inside the heat insulating space outside the heat insulating space.

[0007]

Means for Solving the Problems The measures taken in the present invention to solve the above-mentioned problems are a box-shaped heat insulating wall having an opening at the front, a heat insulating door for opening and closing the opening, and a box-shaped heat insulating wall. A heat insulating space formed by the heat insulating door and a duct formed around the box-shaped heat insulating wall and having both ends communicating with the outside air,
A thermoelectric conversion element in which the cooling part is in thermal contact with the heat insulating space and the heat radiating part is in thermal contact with the duct, the storage case fixed to the heat insulating door, and the storage case are held so that they can be taken in and out of the heat insulating space. In a water drop evaporation device of a cold storage having a rail member and a drainage means for draining water drops generated in the heat insulating space to the outside of the heat insulating space, a passage provided in the rail member and a drain provided in an end portion of the passage And an absorbent material that absorbs water droplets, and the absorbent material is disposed in the duct.

The means taken in the invention of claim 2 is that the drain port formed below the heat insulating space is used as the drain means.

The means taken in the third aspect of the invention is that, in the heat insulating door which is in contact with the box-shaped heat insulating wall, the water discharging means drains water droplets when the heat insulating door is open.

[0010]

According to the above-mentioned means of claim 1, the water droplets drained to the passage outside the heat insulating space spontaneously evaporate on the passage or are absorbed by the absorber so that the heat radiated from the heat radiating portion is released. Can be evaporated. As a result, the water droplets generated in the heat insulating space are drained to the outside of the heat insulating space and evaporated, so that there is no need to waste the waste water. or,
By evaporating the water droplets using the heat radiated from the heat radiating portion, the heat can be effectively used and the evaporation can be further promoted.

According to the second aspect of the present invention, the water drops generated in the cold storage are smoothly drained by draining the water from the drain port provided in the heat insulating space.

According to the third aspect of the present invention, when the heat insulating door is opened, the water drops generated in the heat insulating space are drained to the outside of the heat insulating space, so that the water drops can be drained with a simple structure. You can

[0013]

Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 shows a cool box 10 housed in a cabinet arranged adjacent to a vanity or the like. The cool box 10 has a box-shaped heat insulating wall 11 having an opening at the front.
An adiabatic door 12 that opens and closes an opening; an adiabatic space 13 formed by the box-shaped adiabatic wall 11 and an adiabatic door 12; an adiabatic space 13 and a cooling part are in thermal contact with each other; Thermoelectric conversion element 14 in thermal contact with the heat insulating door 12
And a rail member 16 that supports the inside of the heat insulating space 13 so as to be able to be taken in and out.

The heat insulating door 12 includes a heat insulating material 12a and a frame 12b.
It consists of and. A moving side rail member 16a of the rail member 16 is fixed below the frame 12b.

The moving side rail member 16a is provided in the heat insulating space 13.
It is held by a fixed side rail member 16b arranged outside and can roll in the front-rear direction. A storage case 15 is fixed to the heat insulating material 12 a and is stored in the heat insulating space 13.

The box-shaped heat insulating wall 11 is provided with a heat insulating material 11a inside and a frame 11b outside the heat insulating material 11a. The heat insulating door 12 described above is the box-shaped heat insulating wall 11
The opening can be opened and closed. A packing 17 is provided on the contact surface between the heat insulating door 12 and the box-shaped heat insulating wall 11 to ensure airtightness.

On the rear side of the cool box 10, ducts 18 and 19 extending from the lower side of the cool box 10 toward the rear are formed. The lower end of the duct 19 is opened as an intake port 20 on the lower front surface of the cool box 10. The upper end of the duct 18 is opened as an exhaust port 21 on the upper front surface of the cool box 10, and the lower end is opened as an exhaust port 22 on the lower front surface of the cool box 10.

One end surface of the heat transfer block 23 is in contact with the cooling surface of the thermoelectric conversion element 14, and a heat insulating material 24 is arranged around it. Further, the heat radiation surface of the thermoelectric conversion element 14 is in contact with a radiation fin 25 that radiates heat.
A blower fan 26 that blows cooling air to the heat radiation fins 25 is disposed inside the duct 19 on the opposite surface of the heat radiation fins 25. Further, the duct 19 communicates with the duct 18 via the radiation fin 25. The heat absorbing plate 27 is used as the heat insulating material 11.
It is disposed on the inner surface of a and is in thermal contact with the other end of the heat transfer block 23.

Next, the features of the present invention will be described. The drain hole 29 is formed in the passage 28 formed in the moving-side rail member 16a.
Water drops drained from the stream. An absorber 31 is arranged above the drainage port 29. In addition, the moving side rail member 16
Absorbing material 30 is arranged at the end of a, and absorbing material 3
The lower surface of 0 is reticulated. Also, the moving side rail member 1
The passage formed in 6a is higher on the side of the heat insulating door 12 than on the side where the absorber 30 on the rear side is arranged, so that the drained water droplets are easily absorbed by the absorber 30.

Next, the operation of the first embodiment will be described.

The cool box 10 is operated by an operation switch (not shown).
When the switch for instructing the start of cooling is turned on, the thermoelectric conversion element 14 is energized and at the same time the motor is energized.

When the thermoelectric conversion element 14 is energized, the cooling surface starts cooling, and the heat absorbing plate 27 is passed through the heat transfer block 23.
Since the heat is exchanged with the heat absorbing plate 27, the heat absorbing plate 27 is cooled. Since the heat absorbing plate 27 further exchanges heat with the air in the heat insulating space 13, the air in the heat insulating space 13 is cooled. At this time, the air in contact with the vertical portion 27a and the ceiling portion 27b of the heat absorbing plate 27 is cooled and moves downward. In this way, the cool box 10
The whole is cooled down.

Further, the heat generated by the heat radiation surface exchanges heat with the heat radiation fins 25, and the heat radiation fins 25 exchange heat with the air in the duct 18. In the duct 19, the blower fan 26 is rotated by the drive of the motor, air is sucked from the intake port 20, passes through the duct 18 through the duct 19, and is blown to the radiating fins 25, and then the exhaust ports 21 and 22. Is being discharged more. Therefore, the heat radiation fins 25 efficiently exchange heat by this air flow.

Further, when the heat insulating door 12 is opened and closed, moisture in the atmosphere enters the heat insulating space 13, so that the heat insulating space 1
Within 3, water droplets are generated. The water droplets are drained from the exhaust port 29 formed below the box-shaped heat insulating wall 11, flow through the passage 28, and are absorbed by the absorber 30. The absorbed waste water is naturally evaporated on the passage 28, or is evaporated by the hot air that is absorbed by the absorbent 30 and is radiated from the radiating fins 25.

Next, the second embodiment will be described.

As shown in FIG. 3, the cool box 10 of the first embodiment is not provided with the drain port 29, and the other structure is the same as that of the first embodiment, and the description thereof will be omitted. In the cool box 10 of the second embodiment, when the heat insulating door 12 that is in contact with the box-shaped heat insulating wall 11 is opened instead of draining from the drain port 29, a passage is formed from the opening of the box-shaped heat insulating wall 11. A water drop is made to flow to 28.

The operation of the second embodiment will be described.

The cool box 10 is operated by an operation switch (not shown).
When the switch for instructing the start of cooling is turned on, the thermoelectric conversion element 14 is energized and at the same time the motor is energized.

When the thermoelectric conversion element 14 is energized, the cooling surface starts cooling, and the heat absorbing plate 27 is passed through the heat transfer block 23.
Since the heat is exchanged with the heat absorbing plate 27, the heat absorbing plate 27 is cooled. Since the heat absorbing plate 27 further exchanges heat with the air in the heat insulating space 13, the air in the heat insulating space 13 is cooled. At this time, the air in contact with the vertical portion 27a and the ceiling portion 27b of the heat absorbing plate 27 is cooled and moves downward. In this way, the cool box 10
The whole is cooled down.

Further, the heat generated by the heat radiation surface exchanges heat with the heat radiation fins 25, and the heat radiation fins 25 exchange heat with the air in the duct 18. In the duct 19, the blower fan 26 is rotated by the drive of the motor, air is sucked from the intake port 20, passes through the duct 18 through the duct 19, and is blown to the radiating fins 25, and then the exhaust ports 21 and 22. Is being discharged more. Therefore, the heat radiation fins 25 efficiently exchange heat by this air flow.

Further, when the heat insulating door 12 is opened and closed, moisture in the atmosphere enters the heat insulating space 13 and the heat insulating space 1
Within 3, water droplets are generated. The water droplets are drained from the front of the box-shaped heat insulating wall 11 when the heat insulating door 12 is opened, flow through the passage 28, and are absorbed by the absorber 30. The absorbed waste water is naturally evaporated on the passage 28, or is evaporated by the hot air that is absorbed by the absorbent 30 and is radiated from the radiating fins 25.

As described above, since the water droplets generated in the heat insulating space 13 are drained to the outside of the heat insulating space 13 and evaporated, the wasteful draining work is eliminated.
Further, the heat radiated from the heat radiating portion is used to evaporate the water droplets, so that the heat can be effectively used and the evaporation can be further promoted.

[0034]

According to the above-mentioned invention of claim 1,
The water droplets drained to the passage outside the heat insulating space can be naturally evaporated on the passage or can be evaporated by the heat radiated from the heat radiating portion by being absorbed by the absorber. As a result, the water droplets generated in the heat insulating space are drained to the outside of the heat insulating space and evaporated, so that there is no need to waste the waste water. Further, since the water droplets are evaporated by using the heat radiated from the heat radiating portion, the heat can be effectively used and the evaporation can be further promoted.

According to the second aspect of the present invention, the water drops generated in the cold storage are smoothly drained by draining the water from the drain port provided in the heat insulating space.

According to the third aspect of the present invention, when the heat insulating door is opened, the water droplets generated in the heat insulating space are drained to the outside of the heat insulating space, so that the water droplets can be discharged with a simple structure. You can

[Brief description of drawings]

FIG. 1 is a cross-sectional view of a water droplet evaporation device for a cold store according to a first embodiment of the present invention.

FIG. 2 is a sectional view taken along line XX of FIG.

FIG. 3 is a cross-sectional view of a water droplet evaporation device for a cold storage according to a second embodiment of the present invention.

FIG. 4 is a sectional view taken along line YY of FIG.

[Explanation of symbols]

 11 ... Box-shaped heat insulation wall 12 ... Heat insulation door 13 ... Heat insulation space 14 ... Thermoelectric conversion element 15 ... Storage case 16 ... Rail members 18, 19 ... Duct 28 ... Passage 29 ... Drainage port 30 ... Absorbent

Claims (3)

[Claims] 1. A box-shaped heat insulating wall having a front opening, a heat insulating door that opens and closes the opening, a heat insulating space formed by the box heat insulating wall and the heat insulating door, and the box heat insulating wall. A duct which is formed around the periphery of the duct and has both ends communicating with the outside air; a thermoelectric conversion element in which a cooling portion is in thermal contact with the heat insulating space and a heat radiating portion is in thermal contact with the duct; Water storage device having a storage case, a rail member that holds the storage case in and out of the heat insulation space, and a drainage unit that drains water drops generated in the heat insulation space to the outside of the heat insulation space. In the above, the rail member is provided with a passage for receiving water droplets drained from the drainage means, and an absorber provided at an end portion of the passage for absorbing the water droplets, and the absorber is arranged in the duct. It is characterized by the fact that Water drop evaporation device in cold storage. 2. The water droplet evaporation device for a cold store according to claim 1, wherein a drain port formed below the heat insulating space is used as the drain means. 3. The drainage means for draining water droplets into the passage when the adiabatic door is in contact with the box-shaped adiabatic wall, wherein the adiabatic door is in an open state. Evaporator for cold storage.