KR840000852B1 - Dehydrofzellzing apparatus at low dew point - Google Patents

Abstract

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Description

Low dew point cooling dehumidifier

Arrangement of the whole apparatus of the present invention.

The present invention relates to a novel low dew point cooling and dehumidifying apparatus capable of continuously obtaining the outlet air of a dehumidifier below 0 ° C.

Conventional dehumidification is not only in our daily lives, but also in various industrial manufacturing processes, seedlings, fertilizers, storage and storage of iron, food, and chemicals, drying of synthetic resins, tobacco and aquatic products, or sterilization in hospitals, laboratories, laboratories, etc. It is widely used as an indispensable element for clean use. As a dehumidification method used for such use, four methods are known until now, and there are a method of using a refrigerator in combination here.

In the four dehumidification methods currently used, that is, the cooling dehumidification method, the solid dehumidification method, the liquid dehumidification method, and the extrusion dehumidification method,

1. The cooling dehumidification method is a method of lowering the air temperature by using a freezer. While the temperature and humidity can be easily controlled, the dew point of the outlet air cannot be lowered below 5 ° C, and requires reheating.

2. The solid dehumidification method is a method of adsorbing moisture by using solid absorbents such as silica gel and activated aluminum, which can achieve low dew point and easy handling, but it is difficult to arbitrarily control the humidity of the outlet, If the moisture absorbent is differentiated and the fine powder of the moisture absorbent is mixed in the dehumidifying air, the installation area of the apparatus is large.

3. The liquid dehumidification method is a method of adsorbing moisture by using a liquid absorbent such as an aqueous solution of salt merium and tri-ethylene glycol. The humidity control can be easily controlled and the dust collection or sterilization can be performed simultaneously. Expensive, requires a high temperature heat source for regeneration,

4. Compression and dehumidification is a method of compressing air above a certain pressure to condense moisture in the air. A low dew point can be obtained and operation is easy, while the temperature is high during air compression. In addition, the power consumption was higher than that of other dehumidification methods, and there were some spots that were difficult to use in the large air volume.

As described above, there are many problems in the dehumidification method currently used, and in the case of dehumidification by cooling, the condensed water in the coil is frosted when the temperature of the cooling coil is 0 ° C or lower, and thus the frost coils with time. It was impossible to continuously obtain outlet air below 0 ° C. because it was attached to the whole so that the air could not directly contact the cooled coil and could not pass through the coil.

In a well-known document (see air conditioning and refrigeration, page 8-1970, page 24), it is preferable to use a dew point temperature of 6 ° C or higher in the dehumidification method by cooling because it is difficult to bring the dew point temperature below freezing point.

The present invention solves the above problems in the conventional dehumidification method, has a wide range of application from small capacity to large capacity, low installation cost and operation cost, and can continuously obtain low dew point outlet air below 0 ° C. I have a dehumidifier.

That is, in order to achieve the above object, the present invention continues to operate the compressor in a refrigeration apparatus of 0 ° C. or less having two cooling coils having the same capacity while continuing to cool one of the two coolers for a predetermined time and to maintain air. Pass through to lower the temperature, and when frost is attached little by little, it immediately cools the other side of the cooler. This time, air passes through the coil of this cooler and the frosted coil is defrosted. As this device is operated, it is possible to easily obtain an outlet air of 0 ° C or less by continuing such opposing operations.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The air of 26 ° C. in the atmosphere introduced into the primary heat exchange coil 5 and the humidity of 40% is −5 ° C. which is pumped from the secondary heat exchange coil 9 by the circulation pump 11 in the primary heat exchange coil 5. Heat exchanged with the fluid of -5 ℃, the fluid rises to 0 ℃ and is pumped and circulated to the secondary heat exchange coil 9. The air at 26 ℃ is cooled to 14 ℃ with 85% humidity (air precooled) It is supplied to (6).

The primary cooler (6) is supplied from the primary receiver (3) and heat exchanged with the liquid refrigerant at 0 ° C. decompressed at the expansion valve (4 ″). The liquid refrigerant absorbs heat from the air and vaporizes with vapor refrigerant at 0 ° C. It is supplied to the primary compressor (1), the air of 14 ° C is dehumidified to 2 ° C, 95% humidity, dehumidified and supplied to the secondary coolers (7) and (8) alternately, [At this time, the secondary cooler ( The damper motor 12 is in charge of the alternating operation of 7) and (8), and the damper motor 12, the expansion valve 4, 4 ', the refrigerant supply valve A, B and A timer (not shown) is responsible for the operation of the condensation heat supply valves A 'and B'.

Dehumidified air supplied to the secondary cooler (7) is supplied from the secondary receiver (3 ') and heat exchanged with the liquid refrigerant of -15 ℃ decompressed to the low temperature in the expansion valve (4) so that the liquid refrigerant absorbs heat from the air Vaporized by -15 ℃ vapor refrigerant is supplied to the secondary compressor (1 '), the air of 2 ℃ is lowered to -10 ℃, 95% humidity, dehumidified and supplied to the secondary heat exchange coil (9). Then, when the drop is dropped during operation of the secondary cooler (7), the refrigerant supply side (A) and the expansion valve (4) of the secondary cooler (7) is immediately closed by a timer, on the contrary, the refrigerant supply of the secondary cooler (8) at the same time. The bottle B and the expansion valve 4 'are opened to perform a heat exchange effect as in the above operation, and the secondary compressor 1' is opened while the condensation heat supply valve A 'is opened and the supply valve B' is closed by the simultaneous operation. After defrosting the heat of condensation compressed and supplied to a high temperature from the mixture, it is mixed with the condensate passed through the secondary condensation coil 2 'and supplied to the secondary receiver 3'. Air is continuously dehumidified below freezing point.

The cooled and dehumidified air is heat-exchanged with the fluid of 0 ° C supplied from the primary heat exchange coil 5 in the secondary heat exchange coil 9 so that the fluid of 0 ° C. is cooled to -5 ° C. again by the circulation pump 11. Pressure is circulated, and the air of -10 ° C is raised (air preheating) to 2 ° C and humidity of 35% and supplied to the indoor condenser 10.

The preheated air supplied to the indoor condenser 10 is heat-exchanged with a 50 ° C. gas refrigerant that is compressed and supplied at a high temperature in the primary compressor 1 so that the gas refrigerant loses heat to air and condenses into a 50 ° C. liquid refrigerant to condense the primary. It is mixed with the condensate passed through the coil (2) and supplied to the primary water receiver (3). The air at 2 ° C is supplied to the dehumidification chamber (13) as dry air whose temperature is raised to 26 ° C and 7% humidity. The dry air supplied to the dehumidification chamber 13 absorbs moisture from the object to be dried and is released into the atmosphere as 26 ° C wet air.

Referring to the effects of the present invention as described above are as follows.

The fluid is pumped and circulated by the circulation pump 11 between the primary heat exchange coil 5 and the secondary heat exchange coil 9, and the primary compressor 1 between the primary cooler 6 and the indoor condenser 10. , The primary condensing coil (2), the primary fluid receiver (3) is interconnected to have an organic flow state, the secondary coolers (7) and (8) is the secondary compressor (1 '), secondary condensing coil ( 2 '), the damper motor 12, which is connected to the secondary receiver 3' and operated by a timer, and the expansion change (4) and (4 '), the refrigerant supply valve (A) (B) and the condensation heat supply valve ( A ') (B') alternately cools each other.

In dehumidifying the air in the air by using the dehumidifier configured as described above, the air in the air is introduced into the primary heat exchange coil 5 to be heat-exchanged with the fluid at -5 ° C to be cooled (air precooled). Is raised to 0 ° C and circulated to the secondary heat exchange coil 9.] The cooled air is dehumidified to a low temperature by heat exchange with the liquid refrigerant of 0 ° C in the primary cooler 6, wherein the liquid refrigerant is 0 ° C. Vaporized by steam refrigerant and supplied to the primary compressor (1)] The dehumidified air is alternately passed through the secondary coolers (7) and (8) by the action of a timer to exchange heat with the liquid refrigerant at 1-15 ° C and freeze point. It is dehumidified at the following low temperature and high humidity, and is supplied to the secondary heat exchange coil 9. [At this time, the liquid refrigerant is vaporized with a vapor refrigerant of -15 ℃ and supplied to the secondary compressor (1 '), by the timer damper motor 12, expansion valve (4) (4'), refrigerant supply valve (A) (B) and the condensation heat supply valves (A ') and (B') alternately operate to cool and defrost.

In the secondary heat exchange coil 9, the temperature is increased by heat exchange with a 0 ° C. fluid, and the preheated air is supplied to the indoor condenser 10, and the air supplied to the indoor condenser 10 is a 50 ° C. gas refrigerant. The heat exchange results in the drying air of which the temperature is increased, and the drying air absorbs moisture from the object to be dried in the dehumidification chamber 13 to release the humid air into the atmosphere.

The present invention circulates the fluid as described above, the flow of the refrigerant is connected to each other organically, and by operating two coolers alternately, saving energy as well as easy operation, while maintaining a constant temperature and humidity at all times Dehumidification is the effect made.

Claims (3)

(Secondary correction) The compressor (1), the primary condenser (2), the primary receiver (3) and the indoor condenser (10) are connected to the cooler (6), and the indoor condenser (10) and the dehumidification chamber ( In the known device in communication with 13), a primary heat exchange coil 5 and a secondary heat exchange coil 9 are provided to connect a circulation pump 11 therebetween, and to the primary heat exchange coil 5. A low dew point cooling and dehumidifying apparatus, characterized in that the secondary cooler (7) (8) is installed between the connected primary cooler (6) and the secondary heat exchange coil (9). (Secondary correction) The method according to claim 1, wherein the secondary cooler (7) (8) is connected with a known secondary compressor (1 '), secondary condensing coil (2'), and secondary receiver (3 '). And a damper motor 12 connected by a timer, an expansion valve (4) (4 '), a refrigerant supply valve (A) (B), and a condensation heat supply valve (A') (B '). delete

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