KR20240008674A - Multi coil air conditioning system for dehumidification - Google Patents

Abstract

The present invention regulates the refrigerant supplied to each cooling coil through one supply pipe and a plurality of branch pipes in the multi-outdoor unit of the multi-coil type dehumidifying air conditioning system, and adjusts the temperature and humidity of the outdoor air and indoor air to each cooling coil. It relates to a multi-coil type dehumidifying air conditioning system with an improved structure that not only controls each outdoor unit with an inverter to easily control each outdoor unit, but also detects changes in refrigerant temperature for each part of the cooling coil and allows individual control accordingly.

Description

{MULTI COIL AIR CONDITIONING SYSTEM FOR DEHUMIDIFICATION}

The present invention relates to a multi-coil type dehumidifying air conditioning system. In particular, the multi-coil type dehumidifying air conditioning system regulates the refrigerant supplied to a plurality of cooling coils through one supply pipe and a plurality of branch pipes in the multi outdoor unit, and controls the outdoor air. In addition to controlling the compressor of each outdoor unit with an inverter to easily control the temperature and humidity of the indoor air with each cooling coil, the structure has been improved to detect changes in refrigerant temperature for each part of the cooling coil and enable individual control accordingly. This relates to a multi-coil type dehumidifying air conditioning system.

In general, dehumidifying air conditioners are widely used as a means to remove moisture contained in indoor air, and these dehumidifying air conditioners are largely divided into cooling dehumidifying air conditioners and dry dehumidifying air conditioners depending on the dehumidification method.

A cooling-type dehumidifying air conditioner installs a compressor along with an evaporator and condenser inside the main body, and installs a suction fan in front of the evaporator and condenser, so that when the indoor air flowing into the main body comes into contact with the evaporator that maintains the condensation point, the outside air It is designed to liquefy and dehumidify the moisture contained in the indoor air due to the temperature difference between the room and the room.

Therefore, in this cooling-type dehumidifying air conditioner, the temperature of the treated air supplied to the room is lowered by contacting indoor air with an evaporator and the processed air from which moisture has been removed loses heat, so the temperature of the treated air supplied to the room is lower than the indoor temperature. Not only does it affect the indoor temperature, which is significantly low and should be kept as constant as possible, but when the ambient temperature is low, the temperature difference with the evaporator that maintains the condensation point is not large, so the moisture contained in the indoor air cannot be liquefied, making dehumidification difficult. There was a problem with loss of ability.

In addition, since this cooling-type dehumidifying air conditioner must continuously maintain the evaporator in a cooled state below the condensation point as a condition for dehumidifying indoor air, it uses excessive energy compared to the dehumidifying ability during operation, increasing maintenance costs. There was a problem.

On the other hand, a dry dehumidifying air conditioner has a main body divided into a regeneration side passage through which outdoor air passes and a treatment side passage through which indoor air passes through a partition wall installed in the middle of the longitudinal direction of the interior, and a partition wall inside the main body that penetrates the regeneration side and It consists of a dehumidifying unit rotatably installed in a direction perpendicular to the processing side passage, and a heater installed in the regeneration side passage to dry and regenerate the dehumidifying unit.

This dry dehumidifying air conditioner is a dehumidifying unit that absorbs and dehumidifies the moisture contained in the indoor air passing through the passage on the treatment side, and repeats the operation of drying and regenerating the moisture adsorbed in the dehumidifying unit as a heater installed in the passage on the regeneration side. It is true that by dehumidifying indoor air, it has the advantage of significantly reducing maintenance costs by using minimal energy during operation while demonstrating excellent dehumidifying ability regardless of changes in surrounding temperature. In addition, dry dehumidifying air conditioners can achieve humidity conditions of 30% or less, where cooling and dehumidification is difficult.

However, when such a dry dehumidifying air conditioner dehumidifies indoor air by passing it through a dehumidifying unit that dries and regenerates indoor air as a heater, the treated air from which moisture has been removed by the dehumidifying unit receives the hot heat together and its temperature rises, so it is not transported indoors. There was a problem in that the temperature of the supplied treated air was significantly higher than the indoor temperature, affecting the indoor temperature, which should be kept as constant as possible.

Conventional prior art related to existing dehumidifying air conditioners includes a partition installed in the longitudinal middle part of the interior, as disclosed in Domestic Registered Utility Model Publication No. 20-184583 "Large Capacity Dry Dehumidifying Air Conditioner" (registration date: 200.03.23) A main body divided into a regeneration-side passage through which outdoor air passes and a processing-side passage through which indoor air passes, and a dehumidifying unit that penetrates a partition inside the main body and is rotatable in a direction perpendicular to the regeneration-side and processing-side passages. and a heater installed in the regeneration-side passage to dry and regenerate the dehumidifying unit, penetrating the partition wall inside the main body so as to face the regeneration unit with the heater in between, and forming a heater at a right angle to the regeneration-side and processing-side passages. A heat exchange unit is installed so that it can rotate in any direction, and an evaporative cooler is installed near the outdoor air inlet side in the regeneration passage, so as to efficiently lower the temperature of the treated air dehumidified after passing through the dehumidification unit.

Other prior technologies related to existing dehumidifying air conditioning include, as disclosed in Korean Registered Utility Model Publication No. 20-299995 "Dehumidifying Air Conditioning Device" (registration date: December 23, 2002), a vaporization pad and cooling coil that collect air introduced from the room. In constructing a dehumidifying air conditioning device that dehumidifies the air through an arranged path and supplies it back to the room, it includes: a water collection means for collecting condensate generated from the cooling coil, a storage means for storing the condensate collected from the water collection means, and It consists of a supply means for supplying the cooling water in the storage means to the vaporization pad.

However, in existing dehumidifying air conditioners, it is not easy to control the outdoor unit that supplies refrigerant to the cooling coil, and each outdoor unit supplies refrigerant to a plurality of cooling coils through individual supply pipes so that each outdoor unit is matched one to one. For this purpose, there are space restrictions on the equipment that must install each supply pipe, and there is a disadvantage in that the supply of refrigerant is not efficient.

Korea Registered Utility Model Publication No. 20-184583 “Large Capacity Dry Dehumidifying Air Conditioner” (Registration Date: 200.03.23) Korean Registered Utility Model Publication No. 20-299995 “Dehumidifying Air Conditioning Device” (Registration Date: December 23, 2002)

The present invention was created to solve the above-mentioned problems in consideration of the above-mentioned problems, and its purpose is to supply the refrigerant to each cooling coil through one supply pipe and a plurality of branch pipes in the multi-outdoor unit of the multi-coil type dehumidifying air conditioning system. In addition, the inverter controls each outdoor unit to easily control the temperature and humidity of outdoor and indoor air with each cooling coil, and detects changes in refrigerant temperature for each part of the cooling coil to enable individual control accordingly. The purpose is to provide a multi-coil type dehumidifying air conditioning system with an improved structure.

In order to achieve the above object, the present invention includes a first temperature and humidity detection sensor that respectively detects the temperature and humidity of outdoor air flowing in through the outdoor air inflow duct and outputs the sensed information to the control unit, and A second temperature and humidity detection sensor that detects the temperature and humidity of the air and outputs the sensed information to the control unit, and is disposed in each of the plurality of cooling coils to measure the refrigerant temperature and output the measured temperature information to the control unit. a coil temperature detection sensor, a plurality of outdoor units whose on and off operations of the compressor are inverter-controlled by signals from the control unit, and a plurality of cooling coils disposed in the air conditioner and cooling the air dehumidified by the heater, Supply pipes are branched so that the refrigerant of the outdoor units is supplied to each of the plurality of cooling coils through one pipe, and are respectively disposed on the refrigerant inlet side of the plurality of cooling coils and are turned on and off by the control unit to supply the refrigerant to the plurality of cooling coils. It is characterized by having an electronic expansion valve that controls selective supply to the cooling coil side.

The first temperature and humidity detection sensor is designed to output to the control unit when the temperature of the outside air is 20°C or higher.

The second temperature and humidity detection sensor is designed to output to the control unit when the temperature of the indoor air is above 22°C.

The coil temperature detection sensor is disposed at an inlet side where the refrigerant is supplied into the cooling coil, an outlet side where the refrigerant is discharged to the outside of the cooling coil, and an intermediate portion between the inlet side and the outlet side, so that the cooling coil The change in refrigerant temperature for each part is output to the control unit.

The present invention has a structure in which the refrigerant is supplied through one supply pipe in the process of supplying the refrigerant from a plurality of outdoor units to the cooling coil provided inside the dehumidifying air conditioner, thereby reducing the manufacturing cost of the parts constituting the air conditioning system. This not only makes it easier to maintain parts, but also has the advantage of reducing energy waste as the operation of each outdoor unit is individually inverter controlled by the control unit.

In addition, the present invention applies the temperature and humidity information of outdoor and indoor air detected through the first and second temperature and humidity detection sensors and the temperature change information of the refrigerant for each position of the cooling coil detected from the coil temperature detection sensor to the control unit. As a result, the control unit can control the supply of refrigerant and the operation of the outdoor unit and the electronic expansion valve based on the information transmitted from each sensor, which has the advantage of performing optimized system control.

1 is a circuit diagram schematically showing the configuration of a multi-coil type dehumidifying air conditioning system according to the present invention.
Figure 2 is a diagram showing an air conditioner to which the multi-coil type dehumidifying air conditioning system of Figure 1 is applied.
Figure 3 is a schematic diagram of the coil temperature detection sensor disposed in the cooling coil of the present invention.

In describing the present invention, if it is determined that specific descriptions of related known technologies or configurations may unnecessarily obscure the gist of the present invention, detailed descriptions thereof will be omitted. The terms described below are terms defined in consideration of functions in the present invention and may vary depending on the user's intention or custom. Therefore, the definition should be made based on the contents throughout this specification. In addition, 'including' a certain component does not mean excluding other components, but may include other components, unless specifically stated to the contrary.

When described with reference to FIGS. 1 to 3, the multi-coil type dehumidifying air conditioning system according to the present invention detects the temperature and humidity of the outside air flowing in through the outside air inlet duct 320 and sends the sensed information to the control unit 500. A first temperature and humidity detection sensor 510 that outputs to the side, a second temperature that detects the temperature and humidity of indoor air flowing in through the return ducts 310 and 330 and outputs the sensed information to the control unit 500, A humidity sensor 520, a coil temperature sensor 550 disposed in each of the plurality of cooling coils 210 and 220 to measure the refrigerant temperature and output the measured temperature information to the control unit 500, and the control unit ( A plurality of outdoor units 10 in which the on and off operations of the compressor are each inverter controlled by a signal from 500, and a plurality of cooling coils disposed in the air conditioner 100 and cooling the air dehumidified by the heater 110 ( 210,220), a supply pipe 20 branched so that the refrigerant of the outdoor units 10 is supplied to the plurality of cooling coils 210,220 through one pipe, and a refrigerant inlet side of the plurality of cooling coils 210,220. It includes an electronic expansion valve 600 that is disposed in each and is turned on and off by the control unit 500 to control the refrigerant to be selectively supplied to the plurality of cooling coils 210 and 220.

Referring to Figures 1 and 2, the air conditioner 100 is heated by the heater 110 and dehumidified outdoor air is supplied inside through the outdoor air damper, and the dehumidified outdoor air passes through a plurality of cooling coils 210 and 220. After being cooled, it is supplied indoors.

The supply pipe 20 branches to supply the refrigerant of the outdoor unit 10 to a plurality of cooling coils 210 and 220 provided in close proximity to the outdoor air inlet duct 320 and the return duct 310 and 330 in the air conditioner 100, respectively. It has a structure that is

The cooling coils 210 and 220 include a plurality of first cooling coils 210 that are disposed close to the outside air inlet duct 320 and perform the function of cooling outside air, and are disposed close to the rear side of the return duct and It consists of a plurality of second cooling coils 220 that cool the air.

In the case of a large air conditioner (100), the first and second cooling coils (210, 220) are usually provided in five or more units.

The electronic expansion valve 600 is disposed on the refrigerant inlet side of the cooling coils 210 and 220 (more specifically, between the branch pipe 22 and the inlet side of the cooling coils 210 and 220) and responds to a control signal from the control unit 500. Accordingly, the function of opening and closing the flow path of the branch pipe 22 is performed to control the supply of the refrigerant to the cooling coils 210 and 220.

The plurality of outdoor units 10 are inverter controlled to be turned on and off according to a control signal from the control unit 500.

The control unit 500 receives external temperature and humidity information from the first temperature and humidity sensor 510, and receives indoor air temperature and humidity information from the second temperature and humidity sensor 520. , refrigerant temperature information of the cooling coils 210 and 220 is applied from the coil temperature detection sensor 550.

For this reason, the control unit 500 controls the operation of the outdoor unit 10 using the information detected from the first and second temperature and humidity detection sensors 510 and 520 and the coil temperature detection sensor 550, and operates the cooling coil. A control signal is output to control the selective supply of refrigerant to the (210, 220) side.

As shown in FIG. 3, the coil temperature sensor 550 has an inlet side through which the refrigerant is supplied into the cooling coils 210 and 220, an outlet side through which the refrigerant is discharged to the outside of the cooling coils 210 and 220, and It is disposed in the middle of the inlet side and the outlet side, respectively.

As the coil temperature sensor 550 outputs the change in refrigerant temperature for each part of the cooling coils 210 and 220 to the control unit 500, the refrigerant passing through the inside of the cooling coils 210 and 220 from the control unit 500 It is possible to accurately determine temperature change information.

The first temperature and humidity sensor 510 outputs an output to the control unit 500 when the temperature of the outside air is 20°C or higher, and the second temperature and humidity sensor 520 outputs an output to the control unit 500 when the temperature of the indoor air is 22°C. When an abnormality occurs, the output is output to the control unit 500, allowing the control unit 500 to control the operation of the outdoor unit 10 according to the temperature conditions of the outdoor unit 10 and indoor air.

For example, when the temperature of the outside air rises above 20°C, the first temperature and humidity detection sensor 510 detects this, and the control unit 500 supplies refrigerant to the first cooling coil 210. 10) is operated to supply refrigerant into the first cooling coil 210, and when the temperature of the indoor air rises above 22°C, the second temperature and humidity detection sensor 520 detects this and the control unit (500) operates the outdoor unit 10, which supplies refrigerant to the second cooling coil 220, to supply refrigerant into the second cooling coil 220, so that the control unit 500 controls each outdoor unit ( Energy can be saved by individually controlling the operations of 10).

The present invention relates to the operation of the outdoor unit 10 and the electronic expansion valve 600 so that the refrigerant supply system of each outdoor unit 10 for each cooling coil 210, 220 is matched one to one even with a single supply pipe 20. The operation is controlled by the control unit 500.

That is, the present invention provides a plurality of devices so that the control unit 500 supplies refrigerant to the cooling coils 210 and 220 corresponding to cooling the outdoor air and indoor air when the temperature of the outdoor air and the indoor air exceeds the set reference temperature. The outdoor unit (10) is individually controlled.

As described above, the present invention is provided when temperature and humidity information of outdoor and indoor air and temperature change information of the refrigerant are input from the first and second temperature and humidity detection sensors 510 and 520 and the coil temperature detection sensor 550. The control unit 500 outputs a control signal that controls the supply of refrigerant supplied to each of the plurality of cooling coils 210 and 220 and the operation of the outdoor unit 10.

When outdoor air and returned indoor air are supplied indoors through the air conditioner 100, they are heated through the heater 110 and supplied to the inside of the air conditioner 100 in a state in which moisture in the outdoor air is removed, and are heated to remove moisture. The air is cooled while passing through a plurality of cooling coils 210 and 220 disposed inside the air conditioner 100 and supplied to the return ducts 310 and 330 to be supplied indoors.

While the refrigerant of the outdoor unit 10 is supplied from one supply pipe 20, the plurality of cooling coils 210 and 220 are branched and supplied through a branch pipe 22.

The supply pipe 20 is connected to a plurality of branch pipes 22 so that refrigerant is supplied from a plurality of outdoor units 10, and a plurality of branch pipes 22 are connected to supply the refrigerant of the outdoor unit 10 to the plurality of cooling coils 210 and 220. It has a structure in which the branch pipes 22 are connected.

The control unit 500 controls the inverter to control the operation of each of the plurality of outdoor units 10, and performs a function of controlling the flow passage opening and closing operations of the electronic expansion valves 600.

At this time, the control unit 500 controls each outdoor unit (10) based on the temperature and humidity information of the indoor air and outdoor air applied from the first temperature and humidity sensor 510 and the second temperature and humidity sensor 520. ) A control signal is output to control the operation.

The plurality of outdoor units 10 control the operation of each compressor according to the control signal from the control unit 500 and perform the function of supplying refrigerant to the supply pipe 20 when turned on.

In addition, the electronic expansion valve 600 opens and closes the flow path of the branch pipe 22 to adjust the supply of the refrigerant to the cooling coils 210 and 220 in accordance with the control signal from the control unit 500, so that each cooling coil 210 and 220 ) performs the function of supplying or blocking the refrigerant supplied to the side.

Therefore, the present invention is structured in that the refrigerant is supplied through one supply pipe 20 in the process of supplying the refrigerant from the plurality of outdoor units 10 to the cooling coils 210 and 220 provided inside the dehumidifying air conditioner 100. Accordingly, the manufacturing cost of the parts that make up the air conditioning system can be reduced and maintenance of the parts becomes easier. In addition, the operation of each outdoor unit (10) is individually inverter controlled by the control unit (500), thereby reducing energy waste. It has the advantage of reducing

In addition, the present invention provides temperature and humidity information of outdoor and indoor air detected through the first and second temperature and humidity detection sensors (510, 520) and refrigerant for each position of the cooling coil (210, 220) detected by the coil temperature detection sensor (550). As the temperature change information is applied to the control unit 500, the control unit 500 controls the supply of refrigerant based on the information transmitted from each sensor and operates the outdoor unit 10 and the electronic expansion valve 600, respectively. It has the advantage of being able to control and perform optimized system control.

As such, in the detailed description of the present invention, specific embodiments have been described, but of course, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the claims and equivalents thereof as well as the claims described later.

In other words, the present invention described above is not limited to the specific preferred embodiments described above, and anyone skilled in the art to which the invention pertains can use it without departing from the gist of the present invention as claimed in the claims. Of course, various modifications and implementations are possible, and such modifications are within the scope of the claims.

10: Outdoor unit 20: Supply piping
22: branch pipe 100: air conditioner
110: Heater 210,220: (1st, 2nd) cooling coil
310, 330: return duct 320: outdoor air inflow duct
500: Control unit 510,520: 1st and 2nd temperature and humidity detection sensors
550: Coil temperature detection sensor 600: Electronic expansion valve

Claims (4)

A first temperature and humidity detection sensor 510 that respectively detects the temperature and humidity of the outside air flowing in through the outside air inlet duct 320 and outputs the detected information to the control unit 500,
A second temperature and humidity detection sensor 520 that detects the temperature and humidity of indoor air flowing in through the return ducts 310 and 330 and outputs the detected information to the control unit 500,
A coil temperature detection sensor 550 disposed in each of the plurality of cooling coils 210 and 220 to measure the refrigerant temperature and output the measured temperature information to the control unit 500,
A plurality of outdoor units (10) whose on- and off-operations of the compressor are each inverter-controlled by signals from the control unit (500);
A plurality of cooling coils (210, 220) disposed in the air conditioner (100) and cooling the air dehumidified by the heater (110),
A supply pipe (20) branched so that the refrigerant of the outdoor units (10) is supplied to the plurality of cooling coils (210, 220) through one pipe, respectively, and
An electronic expansion valve ( 600) A multi-coil type dehumidifying air conditioning system. In claim 1,
The first temperature and humidity detection sensor 510 is a multi-coil type dehumidifying air conditioning system, characterized in that the first temperature and humidity detection sensor 510 outputs output to the control unit 500 when the temperature of the outside air is 20°C or higher. In claim 1,
The second temperature and humidity detection sensor 520 is a multi-coil type dehumidifying air conditioning system, characterized in that the second temperature and humidity detection sensor 520 outputs output to the control unit 500 when the temperature of the indoor air is above 22°C. In claim 1,
The coil temperature sensor 550 is located on the inlet side where the refrigerant is supplied into the cooling coils (210, 220), the outlet side where the refrigerant is discharged to the outside of the cooling coils (210, 220), and the middle between the inlet side and the outlet side. Arranged in each area,
A multi-coil type dehumidifying air conditioning system, characterized in that the change in refrigerant temperature for each part of the cooling coils (210, 220) is output to the control unit (500).

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