KR20220092120A - Air conditioner capable of large-capacity cooling ventilation - Google Patents

Abstract

The present invention provides an air conditioner capable of cooling and ventilation in a large capacity while cooling and ventilation are simultaneously performed. According to one embodiment, the air conditioner comprises: an evaporator; an expansion valve, a compressor, an evaporative condenser, and an evaporative cooler providing cooled air to the evaporative condenser. The air conditioner comprises: a dehumidification rotor disposed before the evaporative cooler on an inlet flow passage and dehumidifying the introduced air; and a heating unit disposed before the dehumidification rotor on a regeneration flow passage where the air for regenerating the dehumidification rotor passes to heat the air. The dehumidification rotor is disposed over the regeneration flow passage and the inlet flow passage, and an indoor exhaust flow passage connected to an indoor space has a ventilation cooling mode connected to a condenser supply flow passage. Provided is the air conditioner connected to an accumulation supply flow passage.

Description

Air conditioner capable of large-capacity cooling ventilation

The present invention relates to an air conditioner, and more particularly, to an air conditioner capable of large-capacity cooling and ventilation.

An air conditioner is a device that controls indoor temperature and humidity or ventilates or purifies indoor air according to user needs to keep the room comfortable.

However, there is no device that can actually control room temperature and humidity, ventilate the room air, and even purify the room air. A huge machine room to accommodate all of the above is required, and high power consumption is consumed to perform all of the above functions, thereby reducing space efficiency and energy efficiency.

An object of the present invention is to solve the problems of the prior art as described above, and an object of the present invention is to provide an air conditioner capable of cooling and ventilation of a large capacity while simultaneously performing cooling and ventilation.

In order to achieve the above object, the present invention provides an air conditioner as follows.

In one embodiment, the present invention is an air conditioner comprising an evaporator through which a refrigerant circulates, an expansion valve, a compressor, an evaporative condenser and an evaporative cooler providing air cooled to the evaporative condenser, wherein the evaporative cooler is a channel, a wet channel disposed to exchange heat with the dry channel, and a cooler water supply module for providing water to the wet channel, wherein an inlet passage connected to the outdoors is connected to the dry channel, and the evaporative condenser is a refrigerant passage through which the refrigerant passes. cooling path; a condenser water supply module for supplying water to the cooling passage and a blower module for forming an air flow passing through the cooling passage, wherein the inflow passage passes through the evaporative cooler and then connects to the indoor supply passageway; a dehumidifying rotor branched into a condenser supply passage connected to the evaporative condenser, disposed before the evaporative cooler on the inflow passage, and dehumidifying the incoming air; and a heating unit disposed before the dehumidification rotor on a regeneration passage through which air for regenerating the dehumidification rotor passes and heating the air, wherein the dehumidification rotor is disposed over the regeneration passage and the inlet passage, and is connected to a room The exhaust passage provides an air conditioner connected to the condenser supply passage.

In an embodiment, the condenser supply passage includes a first damper disposed on a portion connected to the inlet passage and a portion connected to the indoor exhaust passage; and a second damper disposed on the indoor exhaust passage, wherein the first and second dampers, the evaporative condenser, the evaporative cooler, the dehumidifying rotor, and a control unit connected to the heating unit further include: the control unit may be operated in a plurality of modes.

In an embodiment, a 3-way valve is disposed at a junction connected to the condenser supply flow path and the indoor exhaust flow path, and the 3-way valve, the evaporative condenser, the evaporative cooler, the dehumidification rotor, and a control unit connected to the heating unit It further includes, wherein the control unit may be operated in a plurality of modes.

In one embodiment, when the control unit is operated in the cooling and ventilation mode, the 3-way valve operates to supply only air from the indoor exhaust flow path to the condenser, and allows outdoor air to flow into the inlet flow path and the regeneration flow path, and An evaporative condenser, an evaporative cooler, a dehumidifying rotor and a heating unit can be operated.

In one embodiment, when the control unit is operated in the cooling mode, the 3-way valve operates to supply only the air of the inlet flow path to the condenser, and allows outdoor air to flow into the inflow flow path and the regeneration flow path, and the evaporative type A condenser, an evaporative cooler, a dehumidifying rotor and a heating unit can be operated.

The present invention can provide an air conditioner capable of cooling and ventilation of a large capacity while cooling and ventilation are performed simultaneously through the above configuration.

1 is a schematic diagram of an air conditioner including an evaporative condenser;
FIG. 2 is a schematic diagram when a cooling mode is performed in the air conditioner of FIG. 1 .
3 is a schematic diagram when a cooling ventilation mode is performed in the air conditioner according to an embodiment of the present invention.
4 is a schematic diagram when a cooling mode is performed in the air conditioner according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be mainly described with reference to the accompanying drawings.

In the present invention, the flow of air means driving the fan disposed on the corresponding flow path, and the damper is not essential at the branch or junction, and if there is no fan driven in the other connected flow path, it is also maintained in an open state. It is possible.

1 and 2 are schematic views of the air conditioner 100 including the dehumidification rotor 180 , the evaporative cooler 170 and the evaporative condenser 110 .

The air conditioner 100 includes a refrigerant cycle R1 in which a refrigerant circulates, and the refrigerant cycle R1 includes an evaporative condenser 110 that condenses the refrigerant into the condenser, an expansion valve 120, and the refrigerant evaporates. It passes through an evaporator 130 and a compressor 140 that cools the air. Since the expansion valve 120 , the evaporator 130 , and the compressor 140 of the refrigerant cycle R1 may be the same as those of a conventional air conditioner, a detailed description thereof will be omitted.

Evaporative condenser 110 has a structure that helps the cooling of the refrigerant while water evaporates by spraying water on the surface of the condenser on the conventional condenser, and the evaporative condenser 110 includes a cooling passage through which the refrigerant passes; and a condenser water supply module for providing water to the cooling passage and a blower module for forming an air flow passing through the cooling passage. The evaporative condenser 110 is disclosed in Patent Document 1 or Korean Patent Application Laid-Open No. 10-2019-0006781 described above, and if it is a condenser structure that utilizes evaporation of water even if it is not such a structure, other evaporative condensers may be applied. .

In the refrigerant cycle R1, the compressor 140, the evaporative condenser 110, and the expansion valve 120 may be disposed in the outdoor unit, and the evaporator 130 may be disposed in the indoor unit 150, except for the evaporative condenser 110 Then, it may be arranged in an indoor unit, or it may be arranged in another air-conditioning space.

The outdoor unit is disposed on the inflow passage (A1) through which the outdoor air is introduced, and includes a dry channel and a wet channel, and an evaporative cooler 170 for cooling the air passing through the dry channel; a dehumidifying rotor 180 disposed before the evaporative cooler 170 on the inflow passage A1 and dehumidifying the incoming air; and a heating unit 185 disposed before the dehumidifying rotor 180 on the regeneration passage A12 through which air for regenerating the dehumidifying rotor 180 passes and heating the air.

The evaporative cooler 170 includes a dry channel through which air that needs cooling passes, and a wet channel adjacent to the dry channel, where water from the water supply module is supplied and evaporation occurs to exchange heat with the dry channel. The wet channels are alternately arranged, and a water supply module is disposed on the upper part of the wet channel to provide water to the wet channel, and a blower module is provided on the upper or lower part to generate a flow. It goes without saying that the evaporative cooler 170 may have a different structure if it can utilize evaporation.

The dehumidification rotor 180 is disposed over the regeneration passage A12 and the inflow passage A1, and the dehumidification rotor 180 absorbs moisture from the inlet passage A1 through the rotating rotor, and the regeneration passage In (A12), it operates by discharging the absorbed moisture. After passing through the evaporative cooler 170, the inflow passage A1 includes an indoor supply passage A5 connected to the room at branch points P2 and P3, and a condenser supply passage connected to the evaporative condenser 110 ( A4), the evaporative cooler 170 is branched into the cooler supply passage A2 connected to the wet channel. In this embodiment, after branching from the branch point P2 to the cooler supply flow path A2, the flow path A3 branches into the condenser supply flow path A4 and the indoor supply flow path A5 at the next branch point P3. It may be branched from one branch point into three places, a cooler supply passage (A2), a condenser supply passage (A4), and an indoor supply passage (A5).

The indoor supply flow path A5 is connected to the indoor unit 150 and may be supplied into the room in a cooled state after passing through the evaporator 130 . However, the present invention is not limited thereto, and the indoor circulation passage A10 passes through the evaporator 130 , and the indoor supply passage A5 may be supplied to the room through the ceiling or wall.

Meanwhile, the air conditioner 100 may include an indoor exhaust flow path A11 for discharging indoor air to the outside by an amount corresponding to the amount of air supplied to the room.

The water supply flow path W1 connected to the water supply source WS includes a water supply flow path W2 toward the evaporative condenser 110 at a branch point P1 and a water supply flow path W3 toward the evaporative cooler 170 . ), and water supplying latent heat for condensing the refrigerant passing through the evaporative condenser 110 by the water supply passages W2 and W3 and cooling the air passing through the evaporative cooler 170 Water is supplied to provide latent heat for The water passing through the evaporative cooler 170 and the water passing through the evaporative condenser 110 are drained to the outside.

2 shows a cooling mode of the air conditioner 100 . As shown in FIG. 2 , when cooling is performed, air does not flow in the indoor supply passage A5 and the indoor exhaust passage A11, and the air introduced from the outside is the evaporative condenser 110 and the evaporative cooler 170 . It is used to drive or regenerate the dehumidification rotor 180 . In the case of the air conditioner 100, if ventilation is required while the evaporative condenser 110 is being driven, the indoor supply passage A5 and the indoor exhaust passage A11 are opened. of the air exits directly without heat exchange, and the amount of air supplied to the inflow passage A1 increases by the amount of air that exits the indoor exhaust passage A11 than in the cooling mode, so that the cooling load of the evaporative cooler 170 increases. there is a problem.

3 is a schematic diagram of an air conditioner 100 according to an embodiment of the present invention. The air conditioner 100 of FIG. 3 basically includes all the configurations of the air conditioner 100 of FIG. 1 except for the flow path.

The air conditioner 100 includes a refrigerant cycle R1 in which a refrigerant circulates, and the refrigerant cycle R1 includes an evaporative condenser 110 that condenses the refrigerant into the condenser, an expansion valve 120, and the refrigerant evaporates. It passes through an evaporator 130 and a compressor 140 that cools the air.

The outdoor unit is disposed on the inflow passage (A1) through which the outdoor air is introduced, and includes a dry channel and a wet channel, and an evaporative cooler 170 for cooling the air passing through the dry channel; a dehumidifying rotor 180 disposed before the evaporative cooler 170 on the inflow passage A1 and dehumidifying the incoming air; and a heating unit 185 disposed before the dehumidifying rotor 180 on the regeneration passage A12 through which air for regenerating the dehumidifying rotor 180 passes and heating the air.

The dehumidification rotor 180 is disposed over the regeneration passage A12 and the inflow passage A1, and the dehumidification rotor 180 absorbs moisture from the inlet passage A1 through the rotating rotor, and the regeneration passage In (A12), it operates by discharging the absorbed moisture. After passing through the evaporative cooler 170, the inflow passage A1 includes an indoor supply passage A5 connected to the room at branch points P2 and P3, and a condenser supply passage connected to the evaporative condenser 110 ( A4), the evaporative cooler 170 is branched into the cooler supply passage A2 connected to the wet channel. In this embodiment, although it has been described that dry air of the evaporative cooler 170 is supplied to the wet channel of the evaporative cooler 170, the present invention is not limited thereto, and external air may be supplied to the wet channel.

The indoor supply flow path A5 is connected to the indoor unit 150 and is supplied to the room in a cooled state after passing through the evaporator 130 , and the air conditioner 100 is supplied to the room as much as it corresponds to the amount of air supplied into the room. It may include an indoor exhaust passage A11 for discharging indoor air to the outside. The indoor exhaust passage A11 is connected to the condenser supply passage A4 at a connection point P5. A three-way valve is provided at the connection point P5, and only one of the air in the condenser supply passage A4 and the air in the indoor exhaust passage A11 is the condenser supply passage A15 at the rear end of the connection point P5. The evaporative condenser (110) is configured to be supplied. Accordingly, in the ventilation or cooling ventilation mode, the indoor exhaust passage A11 may be discharged to the outside after passing through the evaporative condenser 110, and in this case, the condenser supply passage A4 at the front end is blocked. Accordingly, the entire amount of air introduced from the outside can be supplied to the room, which makes it possible to quickly ventilate the room. As will be described later, in the cooling mode, the indoor exhaust flow path A11 is blocked, and the condenser supply flow path A4 at the front end of the connection point P5 and the condenser supply flow path A15 at the rear end are connected, so that the cooling mode of FIG. Cooling may be performed in the same flow path as

Meanwhile, instead of the three-way valve at the connection point P5 , the first valve and the second valve may be respectively disposed in the condenser supply passage A4 and the indoor exhaust passage A11 at the front stage. In this case, in the cooling ventilation mode or ventilation mode, the second valve on the indoor exhaust passage (A11) side may be opened, and the first valve on the condenser supply passage (A4) side may be blocked, and in the cooling mode, the indoor exhaust passage (A11) The second valve on the side may be blocked, and the first valve on the side of the condenser supply flow path A4 may be opened.

The water supply flow path W1 connected to the water supply source WS includes a water supply flow path W2 toward the evaporative condenser 110 at a branch point P1 and a water supply flow path W3 toward the evaporative cooler 170 . ), and water for condensing the refrigerant passing through the evaporative condenser 110 and water for cooling the air passing through the evaporative condenser 170 are supplied by the water supply passages W2 and W3.

The air conditioner 100 controls the flow of air in the flow path through a damper disposed at the branch and the part connected to the indoor and outdoor in the flow path, for example, a 3-way valve or a fan connected to the first and second valves and the flow path. It includes a control unit that Here, the fan may be installed on the flow path, and includes a fan installed on other components installed on the flow path, for example, the evaporative condenser 110 or the evaporative cooler 170 . In addition, the control unit is also connected to the evaporative condenser 110 , the evaporative cooler 170 , the dehumidification rotor 180 , and the heating unit 185 , and may control the refrigerant cycle R1 .

This control unit can be operated in a plurality of modes by controlling the operation of the connected configuration, whereby the evaporative cooler 170, the evaporative condenser 110, and the dehumidifying rotor 180 are utilized to optimize the room in each mode. It is possible to maintain or improve the air condition of

3, the control unit operates all of the evaporative condenser 110, the evaporative cooler 170, the dehumidification rotor 180, the heating unit 185, and the refrigerant cycle (R1) in the cooling and ventilation mode, and the connection point ( The three-way valve disposed in P5) operates so that the indoor exhaust passage A11 is connected to the condenser supply passage A15. Accordingly, all of the air introduced from the outside through the inflow passage A1 is provided to the room except for a partial branching for driving the evaporative cooler 170, and in the room, the corresponding amount of air is evaporated. It is supplied to the condenser 110 . Therefore, since ventilation is performed quickly, indoor air quality can be quickly improved, and energy efficiency can be improved by performing cooling again after the air quality is improved. In addition, since the air supplied to the room is air that has passed through the evaporative cooler 170 primarily, and the evaporator 130 of the refrigerant cycle R1 is also driven, cooling can also be performed smoothly.

4 is a schematic diagram of an air conditioner according to an embodiment of the present invention performing a cooling mode. As shown in FIG. 4 , the control unit operates all of the evaporative condenser 110 , the evaporative cooler 170 , the dehumidification rotor 180 , the heating unit 185 , and the refrigerant cycle R1 in the cooling mode, and the connection point P5 ), the 3-way valve is operated so that the condenser supply flow path A4 of the front stage is connected to the condenser supply flow path A15 of the rear stage. Accordingly, indoor air is not discharged to the outside, and all of the air introduced through the inflow passage A1 can be used for cooling. In the case of this structure, in that it is not different from the cooling structure of FIG. 2 , the present invention can perform the cooling ventilation mode without affecting the cooling.

Although the above description has been focused on the embodiments of the present invention, it goes without saying that the present invention is not limited thereto, and may be implemented with various modifications.

100: air conditioner 110: evaporative condenser
120: expansion valve 130: evaporator
140: compressor 150: indoor unit
160: first heat exchanger 165: second heat exchanger
168: third heat exchanger 170: evaporative cooler
180: dehumidification rotor 185: heating unit

Claims (5)

An air conditioner comprising an evaporator through which a refrigerant circulates, an expansion valve, a compressor, an evaporative condenser, and an evaporative cooler providing air cooled to the evaporative condenser,
The evaporative cooler includes a dry channel, a wet channel disposed to exchange heat with the dry channel, and a cooler water supply module for supplying water to the wet channel, and an inflow passage connected to the outdoors is connected to the dry channel,
The evaporative condenser includes a cooling passage through which the refrigerant passes; and a condenser water supply module for providing water to the cooling passage and a blower module for forming an air flow passing through the cooling passage.
After passing through the evaporative cooler, the inflow passage branches into an indoor supply passage connected to the room and a condenser supply passage connected to the evaporative condenser,
a dehumidifying rotor disposed before the evaporative cooler on the inflow passage and dehumidifying the incoming air; and
Further comprising a heating unit disposed before the dehumidification rotor on a regeneration passage through which air for regenerating the dehumidification rotor passes and heating the air,
The dehumidification rotor is disposed over the regeneration passage and the inflow passage,
The indoor exhaust passage connected to the room is an air conditioner capable of large-capacity cooling and ventilation connected to the condenser supply passage.
The method of claim 1,
a first damper disposed on a portion of the condenser supply passage connected to the inflow passage and a portion connected to the indoor exhaust passage; and
a second damper disposed on the indoor exhaust passage;
Further comprising a control unit connected to the first and second dampers, the evaporative condenser, the evaporative cooler, the dehumidifying rotor, and the heating unit,
The control unit is an air conditioner capable of large-capacity cooling and ventilation, characterized in that it operates in a plurality of modes.
The method of claim 1,
A three-way valve is disposed at a junction connected to the condenser supply passage and the indoor exhaust passage,
The 3-way valve, the evaporative condenser, the evaporative cooler, the dehumidification rotor, further comprising a control unit connected to the heating unit,
The control unit is an air conditioner capable of large-capacity cooling and ventilation, characterized in that it operates in a plurality of modes.
4. The method of claim 3,
When the control unit is operated in the cooling ventilation mode
The 3-way valve is operated to supply only air from the indoor exhaust flow path to the condenser,
outdoor air is introduced into the inflow passage and the regeneration passage,
An air conditioner capable of large-capacity cooling and ventilation, characterized in that the evaporative condenser, the evaporative cooler, the dehumidifying rotor and the heating unit are operated.
4. The method of claim 3,
When the control unit is operated in the cooling mode
The three-way valve is operated to supply only the air of the inlet flow path to the condenser,
outdoor air is introduced into the inflow passage and the regeneration passage,
An air conditioner capable of large-capacity cooling and ventilation, characterized in that the evaporative condenser, the evaporative cooler, the dehumidifying rotor and the heating unit are operated.

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