JP2003227677A - Dehumidifying/cooling unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dehumidifying/cooling unit that ensures efficient dehumidification. <P>SOLUTION: The dehumidifying/cooling unit 11 dehumidifies and cools air in a chamber 2 of a cooling storage 1. The dehumidifying/cooling unit comprises: a rotary dehumidifier 12 whose moisture adsorbing element 21 is rotated to adsorb moisture in a moisture adsorbing region 22 and emit moisture from a moisture emitting region 23; a cooler 36 for cooling passing air; a dehumidifying blower 16 for drawing air in the chamber from a chamber air inlet 3 to pass the air in the moisture adsorbing region of the rotary dehumidifier and the cooler and returning the air again to the chamber from a chamber air outlet 6; and a regenerating blower 17 for drawing regenerative air to pass the air in a regenerative heater 14 and the moisture emitting region of the rotary dehumidifier in sequence and discharging the air. The cooler is arranged downstream of the moisture adsorbing region of the rotary dehumidifier. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dehumidifying / cooling unit installed in a refrigerator such as a prefabricated refrigerator.

[0002]

2. Description of the Related Art In a conventional low temperature and low humidity chamber, a box body and a dehumidifying and cooling unit are integrated. This dehumidifying cooling unit consists of a refrigeration cycle, and frost adheres to the cooler during cooling,
By defrosting this frost, it is dehumidified.

[0003]

If a conventional dehumidifying / cooling unit is used in a large refrigerator such as a prefabricated refrigerator, the dehumidifying capacity is low, and the humidity of the entire refrigerator cannot be kept low. There is. Further, the conventional dehumidifying cooling unit has a relatively long time required for defrosting,
Cooling efficiency decreases. Since the inside of the refrigerator cannot be cooled during defrosting, if the time of defrosting becomes long, the time during which the inside of the refrigerator cannot be cooled increases.

The present invention is intended to solve the above problems, and an object thereof is to provide a dehumidifying and cooling unit capable of efficiently dehumidifying.

[0005]

The dehumidifying and cooling unit (11) of the present invention dehumidifies and cools the air inside the refrigerator (1) (2). The dehumidifying and cooling unit rotates the moisture adsorbing element (21) to adsorb the moisture in the moisture adsorbing region (22) and releases the moisture in the moisture releasing region (23), and the rotary dehumidifying device (12). A cooler (36) for cooling the passing air and an air intake (3) for the air in the refrigerator
A dehumidifying blower (16) that sucks in the air and passes this air through the moisture adsorption region of the rotary dehumidifier and the cooler and returns it again from the in-compartment air discharge port (6) to the inside.
A regeneration heater (14) and a regeneration air blower (17) for sequentially passing the air to the moisture release region of the rotary dehumidifier and discharging the moisture, wherein the cooler is the rotary dehumidifier. Is arranged on the downstream side of the water adsorption region.

Further, an air inlet (4) for mixing inside the storage is connected to a flow path between the moisture adsorption region of the rotary type dehumidifier and the cooler, and the dehumidifying blower is disposed in the moisture adsorption region. In some cases, the dehumidified air is mixed with the in-compartment air taken in from the in-compartment in-compartment air intake port and is flowed to the cooler.

Further, the in-compartment air intake is provided on one side of the in-compartment, the in-compartment air discharge port is provided on the other side of the in-compartment, and the mixing-in-compartment air intake is It may be arranged between the indoor air intake port and the internal air discharge port.

Another dehumidifying and cooling unit of the present invention rotates a moisture adsorbing element to adsorb moisture in the moisture adsorbing region and releases the moisture in the moisture releasing region, and cools passing air. And a cooling device for sucking the air in the refrigerator, passing the air through the moisture adsorption region of the rotary dehumidifier and the cooler, and returning the air to the refrigerator again together with the cooler. )
The condenser (32) that constitutes the
The condenser, the regeneration heater, and a blower device for regeneration that passes through the moisture release area of the rotary dehumidifier to discharge the air, and the condenser, the regeneration heater, and the moisture release area of the rotary dehumidifier are sequentially disposed. It is arranged from the upstream side to the downstream side.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Next, an embodiment of a dehumidifying and cooling unit according to the present invention will be described with reference to FIG. FIG. 1 is a schematic view of a dehumidifying and cooling unit according to an embodiment installed in a prefabricated refrigerator.

The prefabricated refrigerator 1 serving as a refrigerator is provided with an in-compartment air intake 3 for sucking air in the in-compartment 2, a mixing in-compartment air intake 4 and an in-compartment air discharge port 6.
The inside air intake 3 is on one side of the inside 2 (left side in FIG. 1), and the inside air discharge port 6 is on the other side of the inside 2 (right side in FIG. 1). The mixing in-compartment air intake port 4 is arranged between the in-compartment air intake port 3 and the in-compartment air discharge port 6.

A dehumidifying and cooling unit 11 is installed above or adjacent to the prefabricated refrigerator 1. The dehumidifying and cooling unit 11 includes a rotary dehumidifying device 12, a refrigeration cycle 13,
Regenerative heater 14 such as electric heater, dehumidifying blower 16
And a blower device 17 for reproduction. The rotary dehumidifier 12 is a so-called desiccant dehumidifier, and the rotary dehumidifier 12 is provided with a moisture adsorbing element 21 such as disk-shaped silica gel. The moisture adsorbing element 21 is a motor (not shown). Is driven to rotate. The flow path of the air flowing through the moisture adsorbing element 21 is divided into two, one of which flows through the moisture adsorbing region 22 and the other of which flows through the moisture releasing region 23. Then, when the water adsorption element 21 rotates, the water adsorption region 2
2 and the moisture release area 23 are alternately passed. That is,
When the moisture adsorbing element 21 rotates, the portion located in the moisture adsorbing region 22 moves to the moisture releasing region 23, and then moves to the moisture adsorbing region 22 again in sequence.

The refrigeration cycle 13 includes a compressor 31, a condenser 32, a receiver tank 33, and an expansion valve 34 which is a pressure reducing device.
And a cooler 36 and the like are sequentially connected by a refrigerant pipe 37. During the cooling operation, the compressor 31
The compressor 31 pressurizes the gaseous refrigerant and discharges it to the condenser 32. In the condenser 32, the refrigerant is air-cooled and liquefied, and then the expansion valve 34 is passed through the receiver tank 33.
And is decompressed, and then supplied to the cooler 36.
In this cooler 36, the refrigerant takes heat from the surroundings, and then returns to the compressor 31 again. In this way, when the refrigeration cycle 13 operates, the temperature of the cooler 36 decreases and the passing air can be cooled.

The air flow path blown by the dehumidifying blower 16 is from the upstream air intake 3 on the upstream side to the moisture adsorbing region 22 of the rotary dehumidifier 12, the cooler 36, the dehumidifying blower 16 and The in-compartment air discharge port 6 is sequentially connected, and the mixing-in-compartment air intake port 4 is connected between the moisture adsorption region 22 and the cooler 36.

Further, the air flow path blown by the regeneration blower 17 is from the regeneration air intake 41 on the upstream side,
The condenser 32, the regeneration heater 14, the moisture release area 23 of the rotary dehumidifier 12, the regeneration blower 17, and the regeneration air exhaust port 42 are sequentially connected. The motor of the rotary dehumidifier 12, the dehumidifying blower 16, the regenerating blower 17, the compressor 31, and the like are controlled by a controller (not shown). This controller consists of a microcomputer,
It is built in the dehumidification cooling unit 11.

Next, the operation of the dehumidifying / cooling unit 11 of the embodiment having the above-described structure for dehumidifying and cooling the inside 2 of the prefabricated refrigerator 1 will be described. During the dehumidifying cooling, the dehumidifying blower 16, the regenerating blower 17, and the compressor 31 are operated, and the water adsorption element 21 of the rotary dehumidifier 12 is rotated by the motor. Then, by the operation of the dehumidifying blower 16, the air in the inside 2 is sucked from the inside air intake 3 and flows into the moisture adsorption area 22 of the rotary dehumidifier 12. In this moisture adsorption area 22, moisture contained in the air is adsorbed by the moisture adsorption element 21, and the humidity of the air is reduced. Further, the moisture adsorbed on the moisture adsorbing element 21 is
It moves from the water adsorption area 22 to the water release area 23. The outside air heated by the condenser 32 and the regeneration heater 14 flows into the moisture release region 23, as described later,
Water is released from the water adsorption element 21 and dried. Further, the temperature of the moisture adsorbing element 21 rises due to the heated outside air. The portion of the moisture adsorbing element 21 where the temperature rises and is dried moves from the moisture releasing area 23 to the moisture adsorbing area 22 as the moisture adsorbing element 21 rotates, and as described above, the air from the inside air intake 3 is removed. It absorbs moisture from the air and raises the temperature of the air.

The low-humidity and relatively high-temperature air from the moisture adsorption region 22 is mixed with the low-temperature air in the compartment 2 sucked from the mixing compartment air intake 4, and the temperature is lowered. Next, the mixed air passes through the cooler 36, is cooled, and flows into the inside 2 of the inside from the inside air discharge port 6. The air that has flowed into the inside 2 flows from the inside air outlet 6 toward the inside air inlet 4 for mixing and the inside air intake 3 in the inside 2 to dehumidify and cool the whole inside 2. .

By the operation of the regeneration blower 17, the outside air which is the regeneration air is sucked from the regeneration air intake 41, and the suctioned regeneration air flows to the condenser 32 and the condenser 32.
Air cool. During this air cooling, the temperature of the regeneration air rises. Next, the regeneration air is heated by the regeneration heater 14, the temperature further rises, and flows into the moisture release area 23 of the moisture adsorption element 21. In this moisture release area 23,
The regeneration air causes the moisture adsorption element 21 to release moisture, and the humidity of the regeneration air rises. The regeneration air having the increased humidity is discharged from the regeneration air exhaust port 42. In this way, the water in the inside 2 is discharged from the inside air intake 3 through the rotating rotary dehumidifier 12 to the outside through the regenerated air exhaust port 42.

As described above, in this embodiment, since the cooler 36 is arranged on the downstream side of the water adsorption region 22, the cooler 36 is less likely to be frosted. for that reason,
The cooling efficiency of the cooler 36 can be improved and the defrosting time can be reduced. Further, although the temperature of the air rises in the moisture adsorbing region 22, the mixing in-compartment air intake port 4 is connected between the moisture adsorbing region 22 and the cooler 36, and the temperature from the in-compartment air discharge port 6 is high. It is possible to prevent the air from being released into the interior 2.

Further, the inside air intake 3 is arranged on one side of the inside 2 and the inside air discharge port 6 is arranged on the other side of the inside 2, and the inside air intake 3 and the inside air are arranged. Since the in-compartment air intake port 4 is arranged between the in-compartment air intake port 4 and the discharge port 6, the air in the vicinity of the in-compartment air discharge port 6, the air in the vicinity of the mixing in-compartment air intake port 4, and the in-compartment air intake port 3 Humidity increases in the order of nearby air. Therefore, the humidity of the air flowing into the moisture adsorbing region 22 is high, the dehumidifying efficiency is improved, and the air mixed with the dehumidified air in the moisture adsorbing region 22 has a relatively low humidity, so that the cooler 36 is attached. Frost can be reduced as much as possible. Since the condenser 32 is arranged on the upstream side of the regeneration heater 14, the condenser 32 can be air-cooled by the regeneration blower 17, and it is not necessary to separately provide a blower dedicated to the condenser 32. Manufacturing costs are reduced. Moreover, the waste heat of the condenser 32 can be used for heating the air to the moisture release region 23, and the heating capacity of the regenerative heater 14 can be reduced, so that the component cost and the running cost can be reduced. it can.

The embodiment of the present invention has been described above in detail.
The present invention is not limited to the above embodiment,
Within the scope of the present invention as set forth in the claims,
Various changes can be made. Modifications of the present invention are exemplified below. (1) The dehumidifying and cooling unit can be adopted in a refrigerator other than the prefabricated refrigerator, for example, a refrigerator or refrigerators of various sizes.

(2) The dehumidifying blower 16 and the regenerating blower 17 are provided on the downstream side of the air flow path, but the arrangement can be changed as appropriate. For example, it may be provided on the upstream side. (3) The in-compartment air intake 4 does not necessarily have to be provided. (4) In the embodiment, the pressure reducing device is the expansion valve 34, but the pressure reducing device may be a capillary tube or the like.

(5) The material of the moisture adsorbing element 21 can be appropriately selected as long as it can adsorb moisture and can be regenerated, and a material other than silica gel can be used. (6) The regeneration heater 14 is not limited to an electric heater as long as it can heat regeneration air (outside air), and its structure and type can be appropriately selected.

[0023]

According to the present invention, the dehumidifying blower sucks the air in the refrigerator from the air inlet in the refrigerator, passes the air through the moisture adsorption region of the rotary dehumidifier and the cooler, and discharges the air in the refrigerator. Since it is returned to the inside of the refrigerator from the outlet, the air in the refrigerator can be efficiently dehumidified by the rotary dehumidifier. Since the water is discharged from the rotary dehumidifier together with the regenerating air, the drainage device can be eliminated. In addition, the moisture adsorbing region of the rotary dehumidifier is arranged on the upstream side of the cooler, the moisture is adsorbed in this moisture adsorbing region, and the air of low humidity flows into the cooler. Therefore, frost formation on the cooler is reduced, the cooling efficiency is improved, and the time required for defrosting is reduced. As a result, a cooler having a relatively small cooling capacity can be adopted, and manufacturing costs, running costs, etc. can be reduced.

Further, when the dehumidifying blower mixes the air dehumidified in the moisture adsorbing region with the air inside the chamber taken in from the air inlet for mixing, and makes it flow to the cooler, Since the air whose temperature has risen in (1) is mixed with the air having a low temperature from the air inlet for mixing in the storage, it is possible to prevent the air having a relatively high temperature from being discharged into the storage.

Further, since the in-compartment air intake port is provided on one side of the interior and the in-compartment air discharge port is provided on the other side of the interior, the air is efficiently supplied over substantially the entire area of the interior. Can be well dehumidified. The mixing inside air intake is arranged between the inside air intake and the inside air discharge port, and the humidity of the air depends on the inside air discharge port, the mixing inside air intake port, and the inside air conditioner. It becomes higher in the order of the inner air intake. Therefore, since air of relatively high humidity flows into the rotary dehumidifier, dehumidification can be performed efficiently. Moreover, since the mixing air has a relatively low humidity, it is possible to prevent frost formation on the cooler as much as possible.

Since the regeneration blower takes in the regeneration air and passes the air through the condenser, the regeneration heater, and the moisture release area of the rotary dehumidifier in order, and discharges the air, the regeneration blower is used. The condenser of the refrigeration cycle can be air cooled. As a result, it is not necessary to separately provide an air blower for air-cooling the condenser, the waste heat of the condenser can be effectively used, and the number of parts and running cost can be reduced.

[Brief description of drawings]

FIG. 1 is a schematic diagram of a dehumidifying and cooling unit according to an embodiment installed in a prefabricated refrigerator.

[Explanation of symbols] 1 Prefabricated refrigerator (cooling cabinet) 2 inside 3 Inside air intake 4 Internal air intake for mixing 6 Inside air outlet 11 Dehumidifying cooling unit 12 Rotary dehumidifier 13 Refrigeration cycle 14 Regeneration heater 16 Dehumidifying blower 17 Regeneration blower 21 Moisture adsorption element 22 Moisture adsorption area 23 Water release area 32 condenser 36 Cooler

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Shigeru Okamoto             2-5-3 Keihan Hondori, Moriguchi City, Osaka Prefecture             Within Yo Denki Co., Ltd.

Claims (4)

[Claims] 1. A dehumidifying / cooling unit for dehumidifying and cooling the air in a cold storage, wherein the water adsorbing element is rotated to adsorb water in the water adsorbing area and release the water in the water releasing area. Type dehumidifier, a cooler for cooling the air passing therethrough, and the air in the refrigerator is sucked in through the air inlet in the refrigerator, and this air is passed through the moisture adsorption area of the rotary dehumidifier and the cooler to cause the inside of the refrigerator to move. A dehumidifying blower returning from the air discharge port to the inside of the refrigerator again, and a regenerating blower that takes in regenerating air and sequentially passes this air to the moisture releasing regions of the regenerating heater and the rotary dehumidifying device and discharges it, The dehumidifying and cooling unit, wherein the cooler is arranged on a downstream side of a water adsorption region of the rotary dehumidifying device. 2. A mixing chamber air intake is connected to a flow path between the water adsorption region of the rotary dehumidifier and the cooler, and the dehumidification blower is dehumidified in the moisture adsorption region. 2. The inside air taken in from the inside air intake for mixing is mixed with the air, and the mixed air is made to flow to the cooler.
The dehumidifying and cooling unit described. 3. The in-compartment air intake is provided on one side of the in-compartment, the in-compartment air discharge port is provided on the other side of the in-compartment, and the mixing-in-compartment air intake is The dehumidifying and cooling unit according to claim 2, wherein the dehumidifying and cooling unit is arranged between the in-compartment air intake port and the in-compartment air discharge port. 4. A dehumidifying / cooling unit for dehumidifying and cooling the air in the cold storage, wherein the water adsorbing element is rotated to adsorb the water in the water adsorbing area and release the water in the water releasing area. Type dehumidifier, a cooler for cooling the passing air, and a dehumidifying blower that sucks in the air and passes the air through the moisture adsorption area of the rotary dehumidifier and the cooler and returns it to the refrigerator again. A device, a condenser that constitutes a refrigeration cycle together with the cooler, and regeneration air that takes in regeneration air and passes this air through the condenser, regeneration heater, and moisture release area of the rotary dehumidifier to discharge it. The dehumidifying and cooling unit comprising: the condenser, the regeneration heater, and the moisture releasing regions of the rotary dehumidifying device, which are sequentially arranged from the upstream side to the downstream side.