KR101871369B1 - Air water system - Google Patents

Abstract

The present invention relates to a high-efficiency air water system for a built-in type suitable for tropical climate, and more particularly, to an air water system for a built- The air conditioner according to any one of claims 1 to 3,
In particular, the present invention provides a system for minimizing the width of a dehumidifying device so as to minimize the protrusion when it is installed on one side wall of a kitchen or a living room.
The configuration is as follows.
A water generating section (20) for condensing the moisture in the air supplied from the air intake section to generate water; and a control section And a purified water supply unit for cooling and heating the purified water through the purified water portion to provide the purified water,
The water generating unit 20 includes a main body 21 having a space therein; In the main body 21
An evaporator (25) for cooling the externally introduced air to below the dew point;
An outlet 23 'through which water generated by the evaporator 25 is discharged to the outside;
A condenser 26 for converting high temperature and high pressure gas refrigerant including heat taken in the evaporator 25 into cold refrigerated low temperature liquid refrigerant; And a compressor (27) connected to the evaporator (25) and a condenser to compress the circulating refrigerant,
The main body 21 is formed in a zigzag shape so as to be discharged to the outside through an air duct 21D formed in a zigzag shape, and an air inlet 21A through which air is introduced and an air outlet 21B through which air is discharged An evaporator 25 is horizontally installed at the upper end of the air inlet 21A and a condenser 26 is installed horizontally at the upper end of the air outlet 21B.

Description

High efficiency air water system for built-in people suitable for tropical climate {Air water system}

The present invention relates to a high-efficiency air water system for a built-in type suitable for tropical climate, and more particularly, to an air water system for a built- The air conditioner according to any one of claims 1 to 3,

In particular, the present invention provides a system for minimizing the width of a dehumidifying device so as to minimize the protrusion when it is installed on one side wall of a kitchen or a living room.

In a typical refrigeration cycle, a high-temperature, high-pressure gas produced by a compressor is drawn into the air by the heat of the compressed gas refrigerant in the condenser, and then becomes liquid again.

This liquid is pushed to the capillary (the expansion valve) and again cooled to the gas evaporator or frozen.

As such, in order to be frozen through the evaporator, the heat of the high-temperature high-pressure refrigerant must be cooled in the condenser. In the tropical climate, the external temperature is high (about 30 ° C to 40 ° C)

There is a problem in cooling the refrigerant flowing through the condenser, and the evaporator does not function.

As a result, water production of the air water is not smooth and hatching occurs in the refrigeration cycle, resulting in malfunction of the device.

To solve these problems, the inventor repeatedly researched and experimented with the air water system to supply air water to water-scarce countries in tropical countries.

As a result of the study, it was found that the technical composition revealed in this case was the most effective for water production. Consider this effort and look at the technology.

Generally, as the industrial pollution and water pollution due to the increase of pollutants are deepening, tap water is purified by using a water purification device such as a water purifier, or bottled water sold on the market is used.

Generally, a water purifier is used to purify water that is present like a river,

The water is supplied as raw water and passes through a number of filters, and is subjected to a process such as precipitation, filtration, sterilization, etc., and the harmful substances contained in the tap water are purified,

However, there is a problem that it is difficult to use a conventional water purifier using raw water in a region where it is difficult to supply the raw water smoothly.

Accordingly, when the temperature of the air is lowered, the relative humidity becomes higher. At a temperature (dew point temperature) at which the relative humidity becomes 100%, the refrigerant is circulated by using the principle that water vapor exceeding the saturated water vapor amount condenses and changes into water A device has been developed in which raw water is obtained by condensing water vapor in the air by cooling the air, and raw water obtained by this method is purified and supplied as drinking water.

Korean Unexamined Patent Publication Nos. 2005-0027843 and 2010-0104336 disclose a compressor that sucks outside air to compress a gaseous refrigerant at a high temperature and a high pressure, and a high-temperature, high-pressure refrigerant gas discharged from the compressor is condensed And condensing the moisture in the air through an evaporator for evaporating the low-pressure refrigerant that has passed through the expansion tube through the condenser to generate a predetermined amount of raw water and purifying the generated raw water to provide the purified raw water as drinking water However, this method has a problem that the production efficiency of the raw water is low, even though a large amount of energy is consumed because the air is cooled through the circulation of the refrigerant.

Accordingly, it is an object of the present invention to provide a technology for condensing water vapor contained in air to produce water, wherein the evaporator is placed in a space for accommodating the water generating unit, and the condenser is installed in a perforation through the water generating unit side wall, The present invention provides an air water system in which dehumidification efficiency is improved by reducing the heat generated in the condenser by using air cooled inside the compartment,

And it is an object of the present invention to provide a system for minimizing the width of the dehumidifying device so as to minimize the protrusion when it is installed on one wall surface of a kitchen or a living room.

In addition, it is a task to produce raw water by accumulating the vapor in the evaporator.

Referring to the accompanying drawings,

The present invention relates to an air conditioning apparatus for an air conditioner, comprising: an air intake unit for supplying outside air; a water generating unit for generating water by condensing the moisture in the air supplied from the air intake unit; And a purified water supply unit for cooling and heating the purified water through the purified water portion to provide the purified water,

The water generating unit 20 includes a main body 21 provided with a receiving space therein and an upper side opened so as to close the opened upper side of the main body 21 and to supply air into the main body 21 An air suction unit 10 installed in the main body 21; A blowing fan (not shown) installed in the air suction unit 10 for blowing outside air into the main body 21;

 An evaporator (25) for cooling the air supplied by the blowing fan to a dew point or less;

 An outlet 23 in which an outlet 23 'is formed such that water generated by the evaporator 25 is collected;

A condenser 26 for converting high temperature and high pressure gas refrigerant including heat taken from the evaporator 25 into cold refrigerated low temperature liquid refrigerant; And a compressor 27 connected to the evaporator 25 and the condenser to compress the circulating refrigerant. The evaporator 25 is accommodated in the main body 21, (21 ') perforated on the side wall of the first blowing fan (21) and cooled by the second blowing fan (26')

And is arranged together with the second blowing fan 26 '.

The condenser 26 is arranged in the perforations 21 'of the main body 21 together with the second blowing fan 26' so that the air introduced into the main body 21 by the blowing fan flows through the second blowing fan The air cooled by the evaporator 25 cools the heat of the condenser 26, thereby improving the efficiency of the refrigeration system,

In addition, air is introduced into the main body 21 through the blowing fan, and the air introduced by the blowing fan is discharged to the outside of the main body 21 by the second blowing fan 26 ' More water vapor contained in the air can condense.

In addition, after the moisture contained in the outside air is cooled by the condenser 26, the refrigeration cycle (the compressor, the condenser, the expansion valve, the evaporator) is stopped and the second blowing fan 26 ' And the ice is frozen in the ice in the condenser 26 to produce water.

A U-trap (80) is installed in the lower outlet (23 ') of the main body (21)

The water passes through the inside of the main body 21 and reaches the water storage portion 24 via the U-trap 80. [

The reason why the U-trap 80 is provided is that the air introduced into the body 21 by blowing to the blowing fan is not discharged in the direction of the water storage part 24 but passes through the condenser 26

So that the heat generated in the condenser 26 is cooled.

The main body 21 is formed in a zigzag shape so as to be discharged to the outside through an air duct 21D formed in a zigzag shape, and an air inlet 21A through which air is introduced and an air outlet 21B through which air is discharged The evaporator 25 is horizontally installed at the upper end of the air inlet 21A and the condenser 26 is installed horizontally at the upper end of the air outlet 21B.

Since the outside air passed through the evaporator 25 passes through the air duct 21D formed by zigzag, the staying time in the body 21 is long, and at this time, the probability that the moisture contained in the air falls due to the weight of the water It will be highly productive in water production.

In addition, since the cold air in the main body 21 cools the condenser 26, the cooling efficiency of the condenser is high.

For reference, in the case of the tropics, due to the hot weather, it is not easy to cool the condenser 26 with only the outside air.

As a result, equipment such as a condenser is continuously operated, and the entire refrigeration system is overheated due to the fatigue, so that the refrigerator often breaks down.

The main body 21 has an air duct as a U-shape, the upper end of the U-shape is provided with an evaporator 25, and a condenser 26 is installed at the upper end of the U- And is discharged to the outside through the condenser 26 via the entire U-shaped body.

In this way, the main body 21 may be U-shaped so that the evaporator 25 and the condenser 26 can be installed on the upper side. The width direction of the main body 21 including the condenser 26 is narrow.

In addition, since the moisture generated in the evaporator 25 passes through the U-shaped duct, moisture is prevented from being discharged to the outside.

Supplementing the description, it is determined that the ice is accumulated in the evaporator at a predetermined time according to the climatic condition, and the ice-making process is stopped by stopping the freezing cycle.

This step is the step of generating water.

The main body 21 is formed into a long cylindrical shape.

According to the present invention, when it is installed on one wall surface of a kitchen, a living room or the like, it is seen as an outer shape protruding from the wall surface by the size. In view of the fact that the structure of the dehumidifier is not good due to the installation structure and the utilization of the space is poor, the present invention minimizes the protrusion by changing the structure of the dehumidifier.

The above-mentioned effects are further clarified in the concrete contents.

FIG. 1 is a perspective view of a high efficiency air water system for a built-in type suitable for the tropical climate of the present invention,
2 is a perspective view showing the inside of the air water system according to the present invention,
3 is a perspective view of the dehumidifying device shown by cutting the dehumidifying device 90 of the present invention,
4 is a perspective view of the dehumidifying device 90 of the present invention as viewed from above,
5) a) and b) are a cross-sectional view and a perspective view showing still another dehumidifying device of the present invention,
6A) is a perspective view of the storage portion of the present invention,
B) is a cross-sectional view of the upper part of the storage part.
7 is a perspective view showing a state in which the air water system according to the present invention is housed inside a wall.

The present invention will now be described in detail with reference to the accompanying drawings.

2 and 3, the dual pressure switches 25A and 25B are omitted,

1 to 6, the present invention comprises an air suction unit 10, a water generating unit 20, a water purification unit 30, a purified water supply unit 40, and an air discharge unit 50 .

The air intake part 10 is connected to a duct 13 capable of selectively collecting indoor air and outdoor air.

At this time, it is preferable that an air filter (not shown) is mounted on the air suction side of the duct 13 so as to remove foreign matter of the air to be sucked.

The water generating unit 20 is coupled to the lower portion of the air intake unit 10 so as to generate water from the air supplied through the air intake unit 10 to be used as raw water and includes a main body 21, An evaporator 25, a condenser 26, and a compressor 27. The condenser 26 and the compressor 27 are connected to each other.

Here, the main body 21 is formed to have an accommodation space therein and an upper side thereof to be opened. The lid 22 is closed at the opened upper side of the main body 21, (10).

The air inlet 23 is formed to collect the water generated in the main body 21 from the air supplied through the air intake part 10 into the storage part 24, (23 ') are formed.

The evaporator 25 cools the air supplied by the air suction unit 10 to below the dew point and the condenser 26 converts the hot gas refrigerant containing the heat taken in the evaporator 25 into cold refrigerated low temperature liquid refrigerant And the compressor 27 is connected to the evaporator 25 and the condenser 26 to compress the circulating gaseous refrigerant to a high temperature and a high pressure.

The water purification unit 30 is installed at one side of the storage unit 24 where the water generated in the water production unit 20 is collected and supplies water supplied through the supply pump 31 to the user through the plurality of filters 32 To be filtered and purified.

The purified water supply unit (not shown) is installed in the front part and is configured to cool or heat the water supplied from the water storage tank 33 in which purified water purified through the purified water part 30 is stored.

The air discharging portion 50 is installed at the rear portion and is formed to discharge dry and warm air generated by the operation of the water generating portion 20 and heat generated by operating the purified water supplying portion (not shown).

The operation of the first embodiment of the present invention air-water system having the above-described structure will be described.

The air sucked into the duct 13 flows into the main body 21 as the air suction part 10 operates.

As described above, the air sucked into the main body 21 is supplied to the compressor 27 for compressing the gaseous refrigerant at a high temperature and a high pressure, and a condenser 26 for condensing the high temperature and high pressure refrigerant gas discharged from the compressor 27 And an evaporator 25 for evaporating low-pressure refrigerant which has passed through a tube (capillary tube) for expanding the refrigerant liquefied through the condenser 26. This refrigeration system is operated by the following principle .

First, the air supplied to the main body 21 by the blowing fan (including the first blowing fan) evaporates the low-pressure refrigerant by the evaporator 25 so that the inside of the main body 21 is cooled to below the dew point due to the heat of vaporization, 21) The moisture in the air flowing into the inside becomes solid state like a frost (frost).

At this time, when the power supply for operating the evaporator 25 is turned off, the liquid state of the solid state is defrosted and defrosted to generate liquid water.

As the power supplied to the evaporator 25 is periodically supplied or turned off by a timer (not shown), a temperature sensor (not shown), or the like, Water is converted from a solid state, such as an aqueous phase, to a liquid state, such as water, to produce water.

In addition, since water can be generated while supplying or shutting off the power supplied to the evaporator periodically, there is no need to continuously operate the evaporator, which is advantageous in that the cost cost for cooling the air can be reduced.

The gas refrigerant containing the heat taken from the evaporator 25 after being compressed by the compressor 27 at a high temperature and a high pressure while being operated by the water generating section 20 is passed through the condenser 26 and transformed into cold refrigerated low temperature liquid refrigerant In this process, the heat generated through the condenser 26 is discharged to the outside through the air discharge part 50.

The water produced as described above flows down from the upper part of the main body 21 and is collected by the storage part 24 located at the discharge port 23 'side and the water collected in the storage part 24 is discharged by the supply pump 31 to the purified water part 30, and is filtered and purified through a plurality of filters 32.

The purified water purified through the water purification unit 30 is supplied to the user through the purified water supply unit 40 through the purified water supply unit 40 so that the water vapor contained in the air is condensed and the collected water is used as the raw water It can be provided as potable water that can be consumed or used.

Here, the heat generated as the purified water supply unit 40 is operated is supplied to the condenser 26

 The air is discharged to the outside through the air discharge portion 50.

The main body 21 is curved so as to discharge outside air through the evaporator 25 and the condenser 26 to the outside while discharging the outside air through the evaporator 25 without passing through the condenser 26, .

The following describes the body more.

The main body 21 is formed by a first vertical pipe 5 and a second vertical pipe 6 having a long length and a lower end of the first and second vertical pipes 5 and 6 is connected to a connection pipe 7 , And the lower end of the connection pipe (7) forms an outlet (23 ') through which water is discharged

The evaporator 25 is accommodated long in the longitudinal direction of the first vertical tube 5,

The condenser (26) is accommodated in the second vertical tube (6).

And the heat insulating material is filled in the first and second vertical tubes in the longitudinal direction thereof.

(See Figs. 2 and 3)

The first and second vertical tubes 5 and 6 may be installed horizontally instead of vertically, and may be a plurality of vertical tubes.

An embodiment of such a configuration will be described.

When the second blowing fan 26 'and the freezing cycle are operated, the outside air flows through the evaporator 26 in the process of passing the cooling fins 25' of the evaporator 26 and the radiating fins 26 '' of the condenser 26, And the cooling fins 25 'of the cooling fins 25' are stacked.

And the first and second vertical tubes are filled with the heat insulating material 5 'in the longitudinal direction thereof.

As described above, when the cooling fins 25 'of the evaporator 25 are accumulated on the side wall of the main body 21, no external air flows into the main body 21 even if the second blowing fan 26' is operated And a vacuum sensor 38 for detecting whether or not the vacuum chamber 38 is in a vacuum state (corresponding to a connection pipe 7 connected to the lower ends of the first and second vertical pipes 5 and 6)

In a state where the suction pipe 29 is positioned inside the main body through the wall surface of the main body

When the vacuum sensor 38 is turned on due to a buildup of the cooling fin 25 'due to the operation of the freezing / cooling cycle (referred to as a refrigeration cycle), the refrigeration cycle is stopped and the second blowing fan 26' To ensure the water,

 When the vacuum sensor 38 is opened during the removal of the sludge, the refrigeration cycle is operated until the vacuum sensor 38 is turned on by accumulating the cooling fin 25 '.

Thus, the lifetime of the freezing cycle can be significantly extended by allowing the freezing cycle to be stopped.

Since the vacuum sensor 38 is described in detail in Patent Document No. 10-1456456, the defrosting device of the heat exchanger, a description thereof will be omitted.

In another configuration, the dual pressure switches 25A and 25B are installed in the gas piping corresponding to the cooling fins 25 'of the evaporator 25

(Power supplied to the refrigeration system) is turned off when the dual pressure switches 25A and 25B are out of the preset pressure value by the cooling fins 25 '

When the cooling fins 25 'are removed, the dual pressure switches 25A and 25B are set to a predetermined pressure value range

 When the dual pressure switches 25A and 25B are turned off when the cooling fins 25 'are frozen due to the operation of the refrigeration cycle, the refrigeration cycle is stopped and the blowing fan 26' is continuously operated to melt water to secure water,

 When the dual pressure switches 25A and 25B are turned on during the removal of the sludge, the refrigeration cycle is operated until the cooling pin 25 'is accumulated and the dual pressure switch 38 is turned off. Citation High Efficiency Air Water System.

The dual pressure switch is a pressure switch mainly used for stopping the refrigeration cycle when the freezing storage is built in the evaporator from the freezing facility. The dual pressure switch is described in Patent Publication No. 1998-0009616.

A water inflow portion 24 'through which the water flows from the discharge port 23' of the main body 21 and a filter net F 'which is accommodated in the water inflow portion 24' (D) due to the water overflowing from the water inflow part (24 ') because the foreign substance is accumulated in the filter net (F) and the water can not pass through the filter net (F) A sensor (E) is formed

The detection sensor E further forms a second water inflow portion 24 "at the upper end of the storage portion 24 in which water overflowing the water inflow portion 24 'flows into the storage portion 24.

When the foreign substance is adsorbed on the filter net F, the water flowing down from the main body 21 flows over the water inflow section 24 '. Even if the filter net (F) fails to function, the filter is normally charged into the storage part (24) for a while, so that water generation is sustainable.

After the beeps are generated, the filter network may be washed.

By way of example, in the present application, by having the U-trap 80, outside air does not flow in the direction of the discharge port 23 '. The advantage of this is that when the outside air flows in the direction of the discharge port 23 ', the amount of air flowing in from the evaporator 25 direction is reduced, thereby reducing water production.

Although the discharge port 23 'is formed to be small as shown in the drawing, when the air water system is manufactured in a large capacity, the diameter of the discharge port will be increased.

10: Air intake part
13: duct 15: auxiliary blower fan
19: Song forming 20: Water producing part
21: main body 21 ': perforated
21 ": braid 22: cover
23: open 23 ': outlet
24: Storage part 24 ': Inflow part
24 ": second water inflow part 25: evaporator
25 ': cooling pin 26: condenser
26 ': blower fan 27: compressor
29: Suction piping 30:
31: feed pump 32: filter
33: Water tank 38: Vacuum sensor
50: air discharging part 80: U-trap
D: Interference E: Sensing sensor
F:

Claims (3)

A water generating section (20) for condensing the moisture in the air supplied from the air intake section to generate water; and a control section And a purified water supply unit for cooling and heating the purified water through the purified water portion to provide the purified water,

The water generating unit 20 includes a main body 21 having a space therein; In the main body 21
An evaporator (25) for cooling the air introduced from the outside to a dew point or less;
An outlet 23 'through which water generated by the evaporator 25 is discharged to the outside;
A condenser 26 for converting high temperature and high pressure gas refrigerant including heat taken in the evaporator 25 into cold refrigerated low temperature liquid refrigerant; And a compressor (27) connected to the evaporator (25) and a condenser to compress the circulating refrigerant,

The main body 21 is formed by a first vertical pipe 5 and a second vertical pipe 6 each having a long cylindrical shape and the connection pipe 7 (23 ') for discharging water to the lower end of the connection pipe (7)

A cooling fin 25 'is received in the cylindrical shape of the first vertical straight pipe 5 in the longitudinal direction thereof
A heat dissipating fin 26 '' is accommodated in the cylindrical shape of the second vertical straight pipe 6 in the longitudinal direction thereof
The air introduced into the air inlet 21A of the first vertical straight pipe 5
Via the cooling fin 25 'and the radiating fin 26'
(5 ') is formed on the outer wall of the first and second vertical tubes (5, 6) so as to be discharged to the air outlet (21B) of the second vertical tube (6) High efficiency air water system for built-in users.
The method according to claim 1,
The dual pressure switches 25A and 25B are installed in the gas piping corresponding to the cooling fins 25 'of the evaporator 25
When the dual pressure switches 25A and 25B are out of the preset pressure value on the cooling fins 25 ', the power supplied to the refrigeration system is turned off
When the cooling fins 25 'are removed, the dual pressure switches 25A and 25B are set to a predetermined pressure value range

When the dual pressure switches 25A and 25B are turned off when the cooling fins 25 'are frozen due to the operation of the refrigeration cycle, the refrigeration cycle is stopped and the blowing fan 26' is continuously operated to melt water to secure water,

When the dual pressure switches 25A and 25B are turned on during the removal of the sludge, the refrigeration cycle is operated until the cooling pin 25 'is filled with the sludge and the dual pressure switch 38 is turned off. High efficiency air water system.
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