JP3232136B2 - Electronic dehumidifier - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic dehumidifier using a thermoelectric module, and can be suitably used for an apparatus which requires dry air and is operated intermittently.

[0002]

2. Description of the Related Art An electronic dehumidifier using a thermoelectric module is used for dehumidifying a relatively small space such as a storage cabinet or a closet such as a switchboard or a camera. Switchboards and storage are typically used in continuous operation. Therefore, the electronic dehumidifiers used in these methods have a problem of the dehumidification ability after a relatively long time has elapsed since the start of the operation, and the transient dehumidification ability after the start of the operation has not been questioned.

[0003] For this reason, in the conventional electronic dehumidifier, there has been a problem of equilibrium heat exchange between the cooling heat sink and the air or cooling water in the heat radiating heat sink.
186137 or Japanese Utility Model Application Laid-Open No. 3-7924).

[0004]

However, for example, a small-sized deodorizing / sterilizing apparatus utilizing ozone has recently been required. The use of an electronic dehumidifier to supply dry air to this device is being studied (Japanese Utility Model Application No. 3-9).
No. 4825).

[0005] These apparatuses are often operated intermittently, and it is required to supply dry air to the apparatus immediately after the operation of the electronic dehumidifier is started.

However, the conventional electronic dehumidifier has a problem that it takes a long time for the temperature of the cooling heat sink to drop to the target temperature after the operation is started, so that dry air cannot be supplied promptly.

[0007] It is an object of the present invention to provide an electronic dehumidifier capable of supplying dry air immediately after the start of operation.

[0008]

The structure of the present invention includes a thermoelectric module, a cooling heat sink and a heat sink connected to the cooling surface and the heat generating surface of the thermoelectric module, respectively. In an electronic dehumidifier for dew condensation and dehumidification, the heat capacity of the cooling heat sink is C _c , and the heat capacity of the heat sink is C
when the _h, C _h / C _c> is 10, S _c a heat transfer area with respect to air cooling heat sink, when the flow rate of air through the cooling heat sink was Q, 0.5 (cm / s)
<Q / S _c <2 (cm / s).

[0009]

The temperature of the cooling heat sink is determined by the amount of heat transferred to the cooling surface of the thermoelectric module, the latent heat received when moisture condenses from the humid air, the balance of the amount of heat received from the air by convective heat transfer, and its own heat capacity.

However, if the heat capacity of the heat radiating heat sink is large, the temperature rise of the heat radiating heat sink (at the same time, the thermoelectric module) is delayed, so that the amount of heat transfer from the cooling heat sink to the cooling surface of the thermoelectric module can be increased. Also, the heat capacity of the cooling heat sink is small,
This is important for rapidly lowering the temperature of the cooling heat sink. For these reasons, it is preferable that the heat capacity ratio between the heat radiation heat sink and the cooling heat sink is 10 or more.

Furthermore, the ratio of the flow rate of air passing through the cooling heat sink to the heat transfer area of the cooling heat sink to air is as follows:
Determines the dew point of dry air. As shown in FIG. 4, if the above ratio is too large, the air is not dried, and the temperature of the cooling heat sink cannot be rapidly lowered. Conversely, if the ratio is too small, the dew point is lowered more than necessary, and frost tends to adhere. For these reasons, the ratio of the flow rate of the air passing through the cooling heat sink to the heat transfer area of the cooling heat sink to the air is preferably 0.5 (cm / s) to 2 (cm / s).

[0012]

1 and 2 show an example of an electronic dehumidifier 1 of the present invention. A cooling heat sink 4 is thermally conductively connected to a cooling surface of the thermoelectric module 3 provided in the rectangular parallelepiped case 2, and a heat radiating heat sink 5 is thermally conductively connected to a heat generating surface.

The cooling heat sink 4 has a square cross section.
It consists of two hollow rectangular cooling pipes 4a and 4b,
These cooling pipes 4a and 4b are arranged vertically, are arranged side by side at intervals in the horizontal direction, and one of the outer surfaces is in close contact with the cooling surface of the thermoelectric module 3. The cooling heat sink 4 is made of a material having good heat conductivity such as aluminum.

The heat radiating heat sink 5 is formed of a rod-like body having a long and narrow rectangular cross section, is disposed vertically, and one of its outer surfaces is in close contact with the heat generating surface of the thermoelectric module 3. At the center of the cross section of the heat sink 5, a cooling water hole 6 through which cooling water passes is formed in the longitudinal direction to cool the heat sink 5 with water. The heat sink 5 is made of a material having good heat conductivity such as aluminum.

Thermoelectric module 3, cooling heat sink 4,
The length of the heat radiating heat sink 5 in the vertical direction is the shortest for the thermoelectric module 3 and the longest for the heat radiating heat sink 5, and the center position of the thermoelectric module 3, the cooling heat sink 4, and the heat radiating heat sink 5 is in the vertical direction. They are arranged to match. The thermoelectric module 3, the cooling heat sink 4, and the heat radiating heat sink 5 are fixed to each other by two fixing screws 7, 8 arranged vertically. The two fixing screws 7, 8 penetrate through fixing plates 9, 10 respectively arranged vertically over the outer surfaces of the pair of cooling pipes 4 a, 4 b of the cooling heat sink 4, and are provided between the pair of cooling pipes 4 a, 4 b. Through the upper and lower sides of the thermoelectric module 3 and screwed into a pair of screw holes 11 and 12 formed in the heat sink 5. The cooling heat sink 4 and the thermoelectric module 3 are sandwiched between the fixing plates 9, 10 and the heat radiating heat sink 5 by the fixing screws 7, 8.
Are closely fixed to each other. As described above, since the cooling heat sink 4 is formed by the pair of cooling pipes 4 a and 4 b arranged in parallel, it is easy to fix the cooling heat sink 4, and it is possible to closely contact the cooling surface of the thermoelectric module 3 without any gap. As a result, the contact thermal resistance can be reduced.

Below the cooling heat sink 4, a receiving member 13 for dehumidified water is provided. The receiving member 13 has a thickness on the bottom surface and is a rectangular box having an open upper side, and a lower end of a pair of cooling pipes 4 a and 4 b of the cooling heat sink 4 is provided in a space 14 of the receiving member 13. Part is inserted. The inner surface of the bottom of the receiving member 13 is inclined downward toward the center, and a screw hole 15 is formed through the center of the bottom in the vertical direction.

The drain port member 16 of the dehumidifying water has a drain port 16a to which a drain pipe is connected at one end, an intermediate portion 16b has a hexagonal shape, and the other end has a screw portion 16c on the outer periphery. A drain hole is formed in the center portion so as to penetrate the entire length thereof.
6 c is inserted through a through hole formed in the bottom surface of the case 2 from the outside of the bottom surface of the case 2 and screwed into a screw hole 15 provided in the bottom of the receiving member 13, so that the bottom wall of the case 2 is sandwiched therebetween. Dehumidified water receiving member 13 and dehumidified water drain member 16
Is fixed to the bottom wall of the case 2.

Above the cooling heat sink 4, a guide member 17 for dry air is provided. The guide member 17 is a rectangular box whose entire surface is closed, the upper surface has a thickness, and the lower bottom wall has a pair of through holes into which a pair of cooling pipes 4a and 4b of the cooling heat sink 4 are inserted. A hole 18 is formed, and upper ends of a pair of cooling pipes 4 a and 4 b of the cooling heat sink 4 are inserted into the pair of through holes 18 and inserted into the space 19 of the guide member 17. A screw hole 20 is formed in the center of the upper surface of the guide member 17 so as to penetrate vertically.

The dry air outlet member 21 has an outlet 21a at one end to which a discharge pipe is connected, and an intermediate portion 21b.
Has a hexagonal shape, a screw portion 21c is provided on the outer periphery at the other end portion, and a discharge hole is formed so as to penetrate the central portion over the entire length. The screw portion 21c of the discharge port member 21 is Through the through hole formed in the upper surface from the outside of the upper surface of the case 2 and screwed into the screw hole 20 provided in the guide member 17, the dry air is guided across the upper wall of the case 2. Member 17 and dry air outlet member 21
Is fixed to the upper wall of the case 2.

The lower end and the upper end of the cooling water hole 6 of the heat sink 5 are formed with screw holes 6A and 6B. The cooling water inlet member 22 and the cooling water outlet member 23 are provided in these screw holes 6A and 6B. And are respectively fixed.

The cooling water inlet member 22 has an inlet 22a at one end to which a water supply pipe is connected, an intermediate portion 22b has a hexagonal shape, and the other end has a screw portion 22c on the outer periphery. Is formed so as to penetrate the central portion over the entire length, and the screw portion 22 c of the inlet member 22 is inserted through a through hole formed in the bottom surface of the case 2 from the outside of the bottom surface of the case 2, and the lower end of the heat sink 5 is formed. The cooling water inlet member 22 is fixed to the bottom wall of the case 2 by being screwed into the screw hole 6A provided in the portion.

The cooling water outlet member 23 has at one end an outlet 23a to which a drain pipe is connected, an intermediate portion 23b has a hexagonal shape, and the other end has a screw portion 23c on the outer periphery. Is formed in the center portion so as to penetrate the entire length, and the screw portion 23c of the outlet member 23 is inserted through a through hole formed in the upper surface of the case 2 from the outside to the upper end of the heat sink 5. The cooling water outlet member 23 is fixed to the upper wall of the case 2 by being screwed into the screw hole 6B provided in the portion.

On the outer surface of the case 2, an air filter 24 is provided at a lower portion of the cooling heat sink 4 on a side facing the pair of cooling pipes 4 a and 4 b, and a case where the air filter 24 is disposed is provided. An air inlet 25 is opened on the two side walls. Reference numeral 26 denotes a DC power supply installed in the case 2, and reference numeral 27 denotes a power cord extending outside the case 2.

The electronic dehumidifier 1 described above is connected to, for example, an ozone generator as shown in FIG. That is, the dry air discharge member 2 of the electronic dehumidifier 1
Reference numeral 1 denotes a pipe connected to a pump 30, and a downstream side of the pump 30 is connected to a corona discharge unit 32 that converts a part of oxygen in the air into ozone by corona discharge using a high voltage supplied from a high-voltage power supply 31. I have. The pump 30
May be arranged on the upstream side of the electronic dehumidifier 1.

Therefore, the air sucked into the electronic dehumidifier 1 by the operation of the pump 30 is dehumidified in the electronic dehumidifier 1, and the dry air is sent to the corona discharge unit 32, where a part of the air is removed. It is converted into ozone and released.

Hereinafter, the operation of the electronic dehumidifier 1 will be described. When power is supplied to the thermoelectric module 3 from the DC power supply 26, the cooling heat sink 4 connected to the cooling surface side of the thermoelectric module 3 is cooled by the thermoelectric module 3, and condenses moisture in the air when the temperature falls below the dew point temperature.

Therefore, the air that has been cleaned by the air filter 24 and has entered the case 2 through the air inlet 25 provided on the side wall of the case 2 passes through the space 14 of the receiving member 13 of the dehumidified water. A pair of cooling pipes 4a, 4a, 4a,
While entering the inside of the cooling pipes 4a and 4b, it is cooled by the cooling pipes 4a and 4b while ascending inside the pair of cooling pipes 4a and 4b, moisture in the air is dewed and adheres to the inner surfaces of the cooling pipes 4a and 4b. When this dew grows and becomes large water droplets, it drops by gravity, falls on the inner bottom surface of the dehumidified water receiving member 13, flows toward the center of the bottom surface, passes through the drain hole of the dehumidified water drain member 16, and drains. It is accommodated in a dehumidification water tank (not shown) connected to the member 16. In this manner, the air dehumidified while passing through the pair of cooling pipes 4a and 4b is supplied from the pair of cooling pipes 4a and 4b to the guide member 17 for the dry air.
, And is sent to the corona discharge section 32 through the discharge hole of the dry air discharge port member 21. Even when humid air flows in from the drain port member 16 of the dehumidifying water, the air is dehumidified through the pair of cooling pipes 4a and 4b.

The heat generated in the thermoelectric module 3 is radiated by the heat radiating heat sink 5 connected to the heating surface of the thermoelectric module 3. That is, the cooling water inlet member 2
The cooling water is circulated through cooling water holes 6 provided in the heat sink 5 by a pump (not shown) connected between the cooling water outlet member 2 and the cooling water outlet member 23. The heat generated on the heat generating surface of the thermoelectric module 3 is transmitted to the cooling water passing through the inside 5.

An example of the main specifications of the electronic dehumidifier 1 will be specifically described below. Thermoelectric module power consumption: 12V, 3A Cooling heat sink heat capacity: 4.2 cal / ° C Heat sink heat capacity: 55.0 cal / ° C Heat capacity ratio (heat dissipation / cooling): 13.1 Cooling heat sink heat transfer area: 56 cm ² Cooling water flow rate: 70 ml / min Cooling water inlet temperature: 12 ° C. Intake air temperature: 25 ° C. Intake air humidity: 80% Suction air amount: 3 l / min Suction air amount / cooling heat sink heat transfer area: 0.9 cm /
When operated under the condition of s 1, the temperature of the cooling heat sink can be reduced to 5 ° C. or less 15 seconds after the start of operation.

[0030]

As described above, according to the present invention, the temperature of the cooling heat sink can be lowered immediately after the operation of the electronic dehumidifier is started, and the dry air can be supplied promptly.
Therefore, dry air is required promptly and can be suitably used for a device which is operated intermittently.

[Brief description of the drawings]

FIG. 1 is a sectional view of an electronic dehumidifier showing one embodiment of the present invention.

FIG. 2 is a sectional view taken along line II-II of FIG.

FIG. 3 is a graph showing a temperature change of each part after the operation of the electronic dehumidifier of FIG. 1 is started.

FIG. 4 is a graph showing a relationship between a ratio of a flow rate of air passing through a cooling heat sink to a heat transfer area, and a dew point temperature of dry air. The dew point temperature of the dry air indicates a value 15 seconds after the operation of the electronic dehumidifier.

FIG. 5 is a block diagram of an ozone generator.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Electronic dehumidifier 2 Case 3 Thermoelectric module 4 Cooling heat sink 4a, 4b Cooling pipe 5 Heat sink 6 Cooling water hole 7, 8 Fixing screw 9, 10 Fixing plate 6A, 6B, 11, 12, 15, 20 Screw hole 13 Dehumidifying water Receiving member 14, 19 space 16 drainage member for dehumidified water 17 guide member for dry air 18 through hole 21 outlet member for dry air 22 inlet member for cooling water 23 outlet member for cooling water 24 air filter 25 air inlet 26 DC power supply 27 Power cord 30 Pump 31 High voltage power supply 32 Corona discharge section

──────────────────────────────────────────────────続 き Continued on front page (58) Field surveyed (Int.Cl. ⁷ , DB name) B01D 53/26 F25B 21/02

Claims (2)

(57) [Claims] 1. An electronic dehumidifier having a thermoelectric module, a cooling heat sink and a heat radiating heat sink connected to a cooling surface and a heat generating surface of the thermoelectric module, respectively, wherein the moisture air is brought into contact with the cooling heat sink to condense and dehumidify the moisture. , the heat capacity of the cooling heat sink C _c, when the heat capacity of the heat dissipation sink was C _h, a _{C h / C c> 10,} S c a heat transfer area with respect to air cooling the heat sink, the flow rate of air through the cooling heat sink Q is 0.5
An electronic dehumidifier, wherein (cm / s) <Q / _Sc <2 (cm / s). 2. A cooling heat sink is formed of a square pipe and air to be dehumidified passes through the pipe, and the heat radiating heat sink is formed of a rectangular block having a cooling water hole. The electronic dehumidifier according to claim 1, wherein the cooling water flows.