KR101204441B1 - Controlling method for compound air conditioning system - Google Patents

Abstract

The present invention relates to a control method of a mixed air conditioning system, and an object of the present invention is to provide a method for controlling loss of mixing loss in a region in which an indoor unit of a plurality of indoor units of a plurality of indoor units of a system air conditioner adjacent to the central air conditioning system is in charge. It is to provide a control method of a mixed air conditioning system to prevent the occurrence.

To this end, the control method of the mixed air conditioning system according to the present invention determines whether the central air conditioning system for air conditioning the inner compartment region is controlled according to the heating schedule, and according to the determination result, the center peak of the central air conditioning system Calculate the heating peak and cooling peak of the system air conditioner for air conditioning the outer compartment, and compare the central peak with the heating peak and the cooling peak to prevent mixing loss of the central air conditioning system. It controls the opening and closing of the mechanism and the return port and the operation of the indoor unit of the system air conditioner.

Mixed air conditioning system, central air conditioning system, system air conditioner, mixed loss

Description

Controlling method for compound air conditioning system

The present invention relates to a control method of a mixed air conditioning system, and more particularly, mixed air to improve the efficiency of the mixed air conditioning system by preventing the mixing loss caused by operating the central air conditioning system and the system air conditioner in different modes. The control method of a harmonic system.

In general, the central air conditioning system used in large buildings such as buildings generates cold air or warm air by using large-capacity air conditioners installed in the machine room in the lower part of the building or the middle floor of the building for air conditioning. Supply it to the floor or each room so that the temperature in the room is suitable for human living.

However, such a central air conditioning system has a disadvantage in that it responds slowly to load changes and is not easy to change to a cooling operation mode or a heating operation mode.

In order to overcome these shortcomings, the central air conditioning system is in charge of the inner part of the building that does not require rapid response and change in the cooling operation mode or the heating operation mode. In the outer part of the building where the mode or the heating operation mode is required to change, a mixed air conditioning system for the system air conditioner is installed and operated in a large building.

Meanwhile, the central air conditioning system and the system air conditioner of the conventional mixed air conditioning system are operated and controlled according to each algorithm, so that the central air conditioning system and the system air conditioner may be operated according to different operation modes. Accordingly, when the central air conditioning system performs the heating operation and the system air conditioner performs the cooling operation, the air conditioning capacity of the room where the air discharged from the central air conditioning system and the air discharged from the system air conditioner are mixed with each other decreases. There is a problem that loss occurs.

In order to improve the problems of the conventional mixed air conditioning system, Japanese Unexamined Patent Application Publication No. 2000-234781 discloses that the system air conditioner in charge of the outer part of the building is controlled by the skin load considering the skin load and is responsible for the inner part of the building. The central air conditioning system is disclosed a control method of a mixed air conditioning system in which feedback operation is controlled such that a set temperature and a sensed indoor temperature are the same.

However, the control method of the mixed air conditioning system disclosed in Japanese Patent Application Laid-Open No. 2000-234781 described above takes into consideration the entire inner region of the central air conditioning system and the entire outer region of the system air conditioner. The system is feedback controlled and the system air conditioner is under skin load control. Accordingly, there is a possibility that the central air conditioning system and the indoor units of some of the plurality of indoor units of the system air conditioners adjacent to the air supply port and the return port of the central air conditioning system are different from each other. Accordingly, there is a problem that mixing loss may occur in an area in which the air supply and return ports of the central air conditioning system and the indoor units of some of the plurality of indoor units of the system air conditioners adjacent thereto are in charge.

In addition, when the mixing loss occurs, the airflow discharged while performing different operation modes with the indoor air conditioner and the central air conditioning system of the system air conditioner is sucked into the counterpart system, so that the operation rate is excessively increased and the efficiency of the mixed air conditioning system is reduced. There is this.

The control method of the mixed air conditioning system according to the present invention for achieving the object of the present invention as described above determines whether the central air conditioning system for air conditioning the inner compartment area of the building is controlled according to the heating schedule, Calculate the central peak of the central air conditioning system according to the determination result, calculate the heating peak and the cooling peak of the system air conditioner for air conditioning the building outside compartment area, and compare the central peak with the heating peak and the cooling peak. The opening and closing of the air supply and return ports of the central air conditioning system and the operation of the indoor unit of the system air conditioner are controlled to prevent mixing loss.

Here, the heating peak senses the temperature of the outer compartment area that each of the plurality of indoor units of the system air conditioner is in charge, and calculates by subtracting the desired temperature from the minimum value of the temperature of the outer compartment area, the cooling peak is the outer It is calculated by subtracting the maximum value among the temperatures of the partition zone to the desired temperature.

The central peak senses the temperature of the inner compartment regions when the central air conditioning system is controlled according to a heating schedule, and calculates the temperature of the inner compartment region by subtracting the temperature of the inner compartment region to a minimum value. The central peak senses the temperature of the inner compartment regions when the central air conditioning system is controlled according to a cooling schedule, and calculates the maximum value of the temperatures of the inner compartment region by subtracting the maximum value from the desired temperature. The inner compartments may be defined as the inner compartments adjacent to the outer compartments.

When the central air conditioning system is controlled according to a heating schedule, when the cooling peak is larger than the heating peak and the cooling peak is larger than the central peak, the indoor unit of the system air conditioner performs the cooling operation and performs the cooling operation. The air supply and return port of the central air conditioning system adjacent to the indoor unit is closed.

When the central air conditioning system is controlled according to a cooling schedule, when the heating peak is larger than the cooling peak and the heating peak is larger than the central peak, the indoor unit of the system air conditioner performs the heating operation and performs the heating operation. The air supply and return port of the central air conditioning system adjacent to the indoor unit is closed.

In another aspect, the control method of the mixed air conditioning system according to the present invention for achieving the object of the present invention as described above determines whether the central air conditioning system for air conditioning the inner compartment area of the building is controlled according to the heating schedule Calculates a median average of the central air conditioning system according to the determination result, calculates a heating demand average and a cooling demand average of a system air conditioner for air conditioning an outside compartment of the building, and calculates the median average and the heating demand average. And controlling the opening and closing of the air supply and return ports of the central air conditioning system and the operation of the indoor unit of the system air conditioner by comparing the cooling demand averages to prevent mixing loss.

Here, the heating demand average senses the temperature of the outer compartment area that each of the plurality of indoor units of the system air conditioner is responsible for, and the temperature of the outer compartment area smaller than the desired temperature among the temperatures of the outer compartment area at a desired temperature. The cooling demand average is an average of values subtracted, and the cooling demand average is an average of values obtained by subtracting temperatures of the outer compartment area larger than the desired temperature from the temperatures of the outer compartment area by the desired temperature.

The median average senses the temperature of the inner compartment regions when the central air conditioning system is controlled according to a heating schedule, and the inner compartment region smaller than the desired temperature among the temperatures of the inner compartment region at a desired temperature. Is the average of the values subtracted from The median average detects temperatures of the inner compartment regions when the central air conditioning system is controlled according to a cooling schedule, and measures the temperatures of the inner compartment regions that are larger than the desired temperature among the temperatures of the inner compartment region. It is the average of the values subtracted from the desired temperature. The inner compartments may be defined as the inner compartments adjacent to the outer compartments.

When the central air conditioning system is controlled according to a heating schedule, when the cooling demand average is larger than the heating demand average and the cooling demand average is larger than the median average, the indoor unit of the system air conditioner performs the cooling operation and the cooling operation. The air supply and return ports of the central air conditioning system adjacent to the indoor unit performing the operation are closed.

When the central air conditioning system is controlled according to a cooling schedule, when the heating demand average is larger than the cooling demand average and the heating demand average is larger than the median average, the indoor unit of the system air conditioner performs heating operation and the heating. The air supply and return ports of the central air conditioning system adjacent to the indoor unit performing the operation are closed.

According to the control method of the mixed air conditioning system according to the present invention, there is an effect that the generation of the mixing loss is prevented in all areas that are air-conditioned by the mixed air conditioning system.

The generation of the mixing loss is prevented, and the efficiency of the mixed air conditioning system is improved.

Hereinafter, with reference to the accompanying drawings, the specific content of the present invention will be described through preferred embodiments of the present invention.

1 to 3, the mixed air conditioning system 1 according to the first embodiment of the present invention is to air-condition the outside of the building and the central air conditioning system 100 for air conditioning the inner region of the building It includes a system air conditioner 200, the central air conditioning control unit 190 and the main control unit 300 for controlling the system air conditioner control unit 290.

In detail, the central air conditioning system 200 includes a plurality of return ports arranged in pairs with a plurality of air supply ports 190a to 190l and a plurality of air supply ports 190a to 190l for discharging air for air conditioning in a room. 180a to 180l, an air supply duct 150 for supplying air for air conditioning to the air supply ports 190a to 190l, and a return duct for returning the air conditioning unit 120 to the air handling unit 120. 140, the air handling unit 120 that heat-exchanges the air introduced through the return duct 140 to the air supply duct 150, and the refrigerant or water for the air handling unit 120 to perform a heat exchange action. It provides a central air conditioning outdoor unit 110 and the central air conditioning control unit 190 to control the overall central air conditioning system 100.

A plurality of air supply ports 190a to 190l and a plurality of return ports 180a to 180l are paired to handle air conditioning of the plurality of inner compartment areas CA1 to PA12 defined by the inner peripheral part CA of the building. Done. In other words, the first air supply mechanism 190a and the first return port 190a are exposed to the ceiling of the first inner compartment CA1. In addition, a plurality of inner compartment area temperature sensors 170a to 170l are respectively installed in the plurality of air supply ports 190a to 190l to detect the room temperature of each of the inner compartment areas CA1 to PA12 to control the central air conditioning controller 190. To provide. Here, the plurality of inner compartment area temperature sensors 170a to 170l may be installed at the plurality of return ports 180a to 180l, respectively.

The air supply duct 150 includes a main air supply duct 151, a plurality of branch ducts 153, and a plurality of distribution air supply ducts 153a to 153l. The plurality of branch supply air ducts 153 and the plurality of distribution air supply ducts 153a to 153l are main air supply ducts so that the number of the plurality of distribution air supply ducts 153a to 153l corresponds to the number of the plurality of air supply ports 170a to 170l. Branches 151 and a plurality of branch supply ducts 153 are respectively branched. Each of the plurality of distribution air supply ducts 153a to 153l is connected to each of the plurality of air supply ports 190a to 190l, and one side of the main air supply duct 151 is connected to the discharge port 125 of the air handling unit 120.

Each of the plurality of distribution air supply ducts 153a to 153l is provided with a plurality of air supply dampers 191a to 191l to control the discharge of air from the plurality of air supply ports 190a to 190l. The plurality of air supply dampers 191a to 191l are controlled by the central air conditioner controller 190.

The return duct 140 is composed of a main return duct 141, a plurality of branch return ducts 143, and a plurality of distribution return ducts 144a-144l. The plurality of branch return ducts 143 and the plurality of distribution return ducts 144a to 144l are configured as main return ducts so that the number of the plurality of return return ducts 144a to 144l and the number of the return ports 180a to 180l correspond to each other. 141 and a plurality of branch return ducts 143, respectively. Each of the plurality of distribution return ducts 170a to 170l is connected to each of the plurality of return ports 180a to 180l and one side of the main return duct 141 is connected to the inlet 126 of the air handling unit 120.

Each of the plurality of distribution return ducts 144a to 144l is provided with a plurality of return hole dampers 181a to 181l to adjust the intake of air from the plurality of return ports 180a to 180l. The plurality of return outlet dampers 181a to 181l are controlled by the central air conditioning control unit 190.

The central air conditioner outdoor unit 110 includes a compressor, a heat exchanger, and a blower fan, not shown in the drawing, to supply the refrigerant or water to the air handling unit 120 for the heating operation or the cooling operation. Air handling heat exchanger (124).

The air handling unit 120 includes an air unit 127 and an air unit 127 that provide a space for receiving an air handling heat exchanger 124 that receives a refrigerant or water for heat exchange from the central air conditioning outdoor unit 110. It is installed in the machine room of a building, including a suction fan 127 is installed on the inlet 126 side of the and the discharge fan 125 is installed on the discharge port 125 side of the air unit 127.

The air handling unit 120 receives the refrigerant or water from the central air conditioning outdoor unit 110 when the air handling heat exchanger 124 receives the refrigerant or water, and the suction fan 121 and the discharge fan 123 rotate. The air-conditioned air is sucked from 142, and the sucked air is exchanged again to be provided to the main air supply duct 151.

A plurality of inner compartment area temperature sensors 170a to 170l are provided on an input side of the central air conditioning control 190, and a plurality of air supply dampers 191a to 191l and a plurality of return outlet dampers 180a to 180l and air are provided on the output side. The handling unit 120 and the central air conditioning outdoor unit 110 are provided. In addition, the central air conditioner control unit 190 is electrically connected to the main control unit 300 for communication and is controlled by the main control unit 300.

The system air conditioner 200 includes a plurality of indoor units 220a, 220b, 220c and 220d for air conditioning of the outside 4 where the window 2 of the building is installed, and a plurality of indoor units 220a, 220b, 220c and 220d. Air conditioning outdoor unit 210 for providing a refrigerant required to perform the air conditioning action, and a plurality of indoor units (220a, 220b, 220c, 220d) air conditioning for changing the flow direction of the refrigerant to cool or heat operation It includes a system air conditioner control unit 290 for controlling the switching unit 250 and the system air conditioner 200 overall.

The air conditioner outdoor unit 210 includes a compressor (not shown in the figure) and a blower fan provided at one side of the outdoor heat exchanger and the outdoor heat exchanger, so that the plurality of indoor units 220a, 220b, 220c, and 220d are heated or cooled. The refrigerant is condensed or evaporated to be provided to the cooling and heating conversion unit 250 so that the necessary refrigerant may be provided.

The air conditioning unit 250 receives the refrigerant from the air conditioner outdoor unit 210 and the refrigerant having undergone heat exchange in the plurality of indoor units 220a, 220b, 220c, and 220d, and flows into each of the plurality of indoor units 220a, 220b, 220c, and 220d. One of the plurality of indoor units 220a, 220b, 220c, and 220d may perform heating operation or cooling operation by selecting one of the refrigerant in the gas phase and the refrigerant in the liquid phase. Since the air-conditioning conversion unit 250 is generally used for the system air conditioner, a more detailed description thereof will be omitted.

The plurality of indoor units 220a, 220b, 220c, and 220d are responsible for air conditioning of the plurality of outer compartments PA1, PA2, PA3, and PA4, which are defined by the outer circumference of the building.

Hereinafter, since each of the plurality of indoor units 220a, 220b, 220c, and 220d is substantially the same, only the first indoor unit 220a responsible for air conditioning of the first outer compartment area PA1 will be described.

The first indoor unit 220a is installed inside the first indoor unit case 221a and the first indoor unit case 221a to be installed inside the first indoor heat exchanger 222a and the first indoor unit case 221a. 1 an indoor unit suction fan 232a and a first indoor unit discharge fan 261a, a first indoor unit intake port 230a for sucking indoor air, a first indoor unit discharge port 240a for discharging air heat-exchanged into the room, The first indoor unit discharge duct 261a connecting the first indoor unit discharge port 240a and the first indoor unit case 221a, and the first indoor unit connecting the first indoor unit suction port 261a and the first indoor unit case 221a, respectively. A first outer compartment area temperature sensor 260a installed at the suction duct 231a and the first indoor unit suction port 261a is included in the ceiling of the first outer compartment area PA1.

When the first indoor unit 220a is supplied with the refrigerant from the air conditioning unit 250 and the first indoor unit suction fan 232a and the first indoor unit discharge fan 262a are rotated, the first indoor unit 220a is sucked through the first suction port 230a. After heat-exchanging the indoor air of the first outer compartment PA1 using the first indoor heat exchanger 270a, the indoor air is discharged toward the first outer side compartment PA1 through the first indoor unit outlet 240a. Accordingly, the first outer compartment area PA1 is cooled or heated.

On the input side of the system air conditioner control unit 290, a plurality of outer compartment area temperature sensors 260a to 260d having room temperatures of the plurality of outer compartments PA1 to PA4 are provided, and an output side of the air conditioning unit 250 is provided. A plurality of indoor units 220a to 220d and an air conditioner outdoor unit 210 are provided. The system air conditioner controller 290 is electrically connected to the main controller 300 for communication.

The main controller 300 calculates the cooling peak, the heating peak, and the center peak by using the temperature of the inner compartment area and the temperature of the outer compartment area input from the central air conditioning control unit 190 and the system air conditioner control unit 190. The central air conditioning control unit 190 and the system air conditioner control unit 190 are controlled using the calculated cooling peaks, heating peaks, and the central peaks so that mixing loss does not occur.

Hereinafter, a control method of a mixed air conditioning system according to a first embodiment of the present invention will be described with reference to the accompanying drawings.

In the control method of the mixed air conditioning system according to the first embodiment of the present invention, it is largely determined whether the central air conditioning system 100 is controlled according to the heating schedule, and according to the result, the temperature of the inner compartment area and the outer compartment are determined. The mixing loss condition and the mixing loss area are estimated using the indoor temperature and the desired temperature of the area, and the mixing loss prevention operation is performed to prevent the mixing loss from occurring.

4 and 5, when power is applied to the main control unit 300, the central air conditioning system 100, and the system air conditioner 200, the main control unit 300 performs heating operation by the central air conditioning system 100. It is determined whether it is controlled according to the schedule (401).

At this time, if the central air conditioning system 200 is controlled by the central air conditioning system 100 according to the heating operation schedule, the main control unit 300 is the central air conditioning control unit 190 is the central air conditioning system 100 To control according to the heating operation schedule. In this way, the central air conditioning control unit 190 controls the central air conditioning system 100 to perform a heating operation (402).

The central air conditioning controller 190 detects the room temperature of the inner compartment regions CA1 to CA12 that each of the inner compartment region temperature sensors 170a to 170l is in charge of. Accordingly, each of the inner compartment area temperature sensors 170a to 170l senses the temperature of each of the inner compartment areas CA1 to CA12 and provides the respective temperature values to the central air conditioning controller 190. In this case, the main controller 300 extracts the minimum value among the temperature values of the inner compartments CA1 to CA12 and temporarily stores the calculated central peak by subtracting the extracted minimum value from the desired temperature (403, 404).

The main controller 300 then controls the system air conditioner control unit 290 so that the system air conditioner control unit 290 detects the room temperature of the outer compartment area PA1 to PA4 by the outer compartment area temperature sensor 260a to 260d. To supply. Accordingly, the system air conditioner controller 290 controls the outside compartment area temperature sensors 260a to 260d to sense the room temperature of the outside compartment areas PA1 to PA4. Accordingly, each of the outer compartment area temperature sensors 260a to 260d senses the room temperature of each of the outer compartment areas PA1 to PA4, and controls the temperature value of each of the outer compartment areas PA1 to PA4. ), And the system air conditioner control unit 290 supplies the temperature values of each of the outer compartments PA1 to PA4 to the main control unit 300. In this way, the main control unit 300 calculates and stores the cooling peak value by subtracting the maximum value among these temperature values to the desired temperature value, and subtracts the heating peak value by subtracting the desired temperature value to the minimum value among these temperature values. Compute and store (405, 406).

Then, the main controller 300 controls to prevent the mixing loss to be described below by using the heating peak, the cooling peak, and the center peak obtained through the above-described steps 402 to 405.

The main controller 300 determines whether the heating peak is greater than the cooling peak (407).

Here, if the heating peak is greater than the cooling peak, the main control unit 300 controls the system air conditioner control unit 290 to allow the system air conditioner control unit 290 to control the heating operation of the system air conditioner 200. Accordingly, the system air conditioner 200 performs a heating operation (408). The main control unit 300 controls the central air conditioning system control unit 190 so that the central air conditioning system 100 operates normally according to the heating schedule. Accordingly, the central air conditioning system 100 performs normal operation (409). In this way, both the central air conditioning system 100 and the system air conditioner 200 perform a heating operation so that no mixing loss occurs in the interior of the building. Subsequently, the main controller 300 determines whether the reference time has elapsed (410). If the reference time has not elapsed, the main controller 300 continuously determines whether the reference time has elapsed, and if it is determined that the reference time has elapsed, determines whether the operation is terminated. In operation 411, if the operation is terminated, the operation is terminated. If the operation is not the end condition, the operation returns to step 401, and the steps 401 and 401 are performed. Here, the reference time may be selected by experiment as a time at which the temperature distribution of the room is changed and again, a mixing loss may occur.

If the heating peak is not greater than the cooling peak, the main controller 300 determines whether the central peak is larger than the cooling peak (412).

At this time, if the central peak is larger than the cooling peak, the main control unit 300 determines that the entire area of the room is preferentially heated, and the central air conditioning system 100 and the system air conditioner 200 perform heating operation. The central air conditioner control unit 190 and the system air conditioner control unit 290 are controlled (413, 414). In this way, although the discomfort index in the outer area PA that the system air conditioner 200 is in charge is rather high, the mixing loss does not occur in the interior of the building. Subsequently, the main controller 300 performs step 410 and subsequent steps.

If the central peak is not larger than the cooling peak, the main controller 300 controls the central air conditioning controller 190 and the system air conditioner controller 290 so that mixing loss does not occur. In this way, the system air conditioner control unit 290 controls the system air conditioner 200 according to the cooling operation mode. Accordingly, the system air conditioner 200 performs the cooling priority operation according to the cooling operation mode (415). The central air conditioning control unit 190 is an air supply damper adjacent to a system air conditioner indoor unit that performs cooling operation among the system air conditioner indoor units 220a to 220d among the air supply dampers 191a to 191l and the return hole dampers 180a to 180l. And the control to close the return port damper (416), and the central air conditioning system 100 controls the central air conditioning system 100 to perform normal operation according to the heating operation schedule (417). , The warm air discharged to the air supply unit adjacent to the system air conditioner indoor unit performing the cooling operation and the cold air discharged from the system air conditioner indoor unit performing the cooling operation among the system air conditioner indoor units 220a to 220d are mixed. This is prevented from mixing loss, is prevented from a return port go close to the air conditioning system, the indoor units performing the cooling operation, cooled air is introduced it can be prevented a phenomenon that the efficiency of the central air conditioning system decreases.

Next, the main controller 300 performs step 410 and subsequent steps.

When the central air conditioning system 200 is controlled by the central air conditioning system 100 according to the cooling operation schedule in step 401, the main air controller 300 may include the central air conditioning controller 190. Control to control the 100 according to the cooling operation schedule. In this case, the central air conditioning controller 190 controls the central air conditioning system 100 to perform a cooling operation (418). In addition, the central air conditioning controller 190 detects the room temperature of the inner compartment regions CA1 to CA12 that each of the inner compartment region temperature sensors 170a to 170l is in charge of. Accordingly, each of the inner compartment area temperature sensors 170a to 170l senses the temperature of each of the inner compartment areas CA1 to CA12 and provides the respective temperature values to the central air conditioning controller 190. Accordingly, the main controller 300 extracts the maximum value among the temperature values of the inner compartments CA1 to CA12 and temporarily stores the calculated central peak by subtracting the extracted maximum value from the desired temperature (419, 420).

Next, the main controller 300 controls the system air conditioner control unit 290 to allow the system air conditioner control unit 290 to detect the room temperature of the outer compartment area PA1 to PA4 by the outer compartment area temperature sensor 260a to 260d. Supply the signal. Accordingly, the system air conditioner controller 290 controls the outside compartment area temperature sensors 260a to 260d to sense the room temperature of the outside compartment areas PA1 to PA4. Accordingly, each of the outer compartment area temperature sensors 260a to 260d senses an indoor temperature of each of the outer compartment areas PA1 to PA4, and controls the temperature value of each of the outer compartment areas PA1 to PA4. ), And the system air conditioner control unit 290 supplies the temperature values of each of the outer compartments PA1 to PA4 to the main control unit 300. In this way, the main control unit 300 calculates and stores the cooling peak value by subtracting the maximum value among these temperature values to the desired temperature value, and subtracts the heating peak value by subtracting the desired temperature value to the minimum value among these temperature values. Calculate and store (421,422).

Then, the main control unit 300 controls to prevent the mixing loss to be described below by using the heating peak, the cooling peak, and the center peak obtained through the above-described steps 418 to 422.

In other words, the main controller 300 determines whether the cooling peak is greater than the heating peak (423).

Here, if the cooling peak is greater than the heating peak, the main control unit 300 controls the system air conditioner control unit 290, so that the system air conditioner control unit 290 controls the air conditioner operation of the system air conditioner 200. Accordingly, the system air conditioner 200 performs the cooling operation (424).

The main control unit 300 controls the central air conditioning system control unit 190 so that the central air conditioning system 100 operates normally according to the cooling schedule. Accordingly, the central air conditioning system 100 performs normal operation (425). In this way, both the central air conditioning system 100 and the system air conditioner 200 perform the cooling operation so that the mixing loss does not occur in the interior of the building. Subsequently, the main controller 300 performs step 410 and subsequent steps.

If the cooling peak is not larger than the heating peak, the main controller 300 determines whether the central peak is larger than the heating peak (426).

At this time, if the central peak is larger than the heating peak, the main control unit 300 determines that the entire area of the room is preferentially required to be preferentially, and the central air conditioning system 100 and the system air conditioner 200 perform the cooling operation. The central air conditioner controller 190 and the system air conditioner controller 290 are controlled (427, 428). In this way, although the discomfort index in the outer area PA that the system air conditioner 200 is in charge is rather high, the mixing loss does not occur in the interior of the building. Subsequently, the main controller 300 performs step 410 and subsequent steps.

If the central peak is not larger than the heating peak, the main control unit 300 controls the central air conditioning control unit 190 and the system air conditioner control unit 290 so that mixing loss does not occur. In other words, the system air conditioner control unit 290 controls the system air conditioner 200 according to the heating operation mode, and accordingly, the system air conditioner 200 performs the cooling priority operation according to the heating operation mode (429). The central air conditioning control unit 190 is an air supply damper adjacent to a system air conditioner indoor unit which performs heating operation among the system air conditioner indoor units 220a to 220d among the air supply dampers 191a to 191l and the return outlet dampers 180a to 180l. And the control to close the return hole damper (430), and the central air conditioning system 100 controls the central air conditioning system 100 to perform normal operation according to the cooling operation schedule (431). , The cold air discharged from the air supply unit adjacent to the system air conditioner indoor unit performing the heating operation and the warm air discharged from the system air conditioner indoor unit performing the heating operation among the system air conditioner indoor units 220a to 220d This is prevented the mixing loss, from being excessively close to the air conditioning system, the return port to the indoor unit flows the warm air to perform heating operation is prevented thereby preventing the phenomenon in which the efficiency of the central air conditioning system decreases.

Next, the main controller 300 performs step 410 and subsequent steps.

Hereinafter, a mixed air conditioning system and a method of controlling the same according to the second embodiment of the present invention will be described with reference to the drawings, but the part compared with the mixed air conditioning system and the control method according to the first embodiment of the present invention As described above, the mixed air conditioning system according to the second embodiment of the present invention will be referred to the mixed air conditioning system according to the first embodiment of the present invention.

6 and 7, the method for calculating the center peak of the control method of the mixed air conditioner system according to the second embodiment of the present invention is compared with the method for calculating the center peak according to the first embodiment of the present invention.

In other words, when the central air conditioning system 100 is controlled according to the heating schedule, the central air conditioning controller 190 is adjacent to the inner compartment zone temperature sensor 170a to 170d adjacent to the outer compartment PA1 to PA4. The indoor temperature of each of the adjacent inner compartments CA1 to CA4 is sensed. Accordingly, each of the inner compartment area temperature sensors 170a to 170d senses the temperature of each of the inner compartment areas CA1 to CA4 and provides each temperature value to the central air conditioning controller 190. In this way, the main controller 300 extracts the minimum value among the temperature values of the adjacent inner compartments CA1 to CA4 and temporarily stores the center peak calculated by subtracting the extracted minimum value from the desired temperature (603, 604).

When the central air conditioning system 100 is controlled according to the cooling schedule, the central air conditioning control 190 may include the adjacent inner compartment region temperature sensors 170a to 170d adjacent to the outer compartments PA1 to PA4. The indoor temperature of the adjacent inner compartment area (CA1 ~ CA4) is detected. Accordingly, each of the inner compartment area temperature sensors 170a to 170d senses the temperature of each of the inner compartment areas CA1 to CA4 and provides each temperature value to the central air conditioning controller 190. In this way, the main controller 300 extracts the maximum value among the temperature values of the adjacent inner compartments CA1 to CA4, and temporarily stores the center peak center peak calculated by subtracting the extracted maximum value from the desired temperature ( 619, 620).

Hereinafter, a control method of a mixed air conditioning system according to a third embodiment of the present invention will be described with reference to the accompanying drawings. However, a mixed air conditioning system according to a third embodiment of the present invention will be described in the first embodiment of the present invention. Reference is made to a mixed air conditioning system according to the present invention.

 8 and 9, when power is applied to the main control unit 300, the central air conditioning system 100, and the system air conditioner 200, the main control unit 300 performs heating operation by the central air conditioning system 100. It is determined whether it is controlled according to the schedule (801).

At this time, if the central air conditioning system 200 is controlled by the central air conditioning system 100 according to the heating operation schedule, the main control unit 300, the central air conditioning control unit 190 is the central air conditioning system 100 To control according to the heating operation schedule. In this case, the central air conditioning control unit 190 controls the central air conditioning system 100 to perform a heating operation (802).

The central air conditioning controller 190 detects the room temperature of the inner compartment regions CA1 to CA12 that each of the inner compartment region temperature sensors 170a to 170l is in charge of. Accordingly, each of the inner compartment area temperature sensors 170a to 170l senses the temperature of each of the inner compartment areas CA1 to CA12 and provides the respective temperature values to the central air conditioning controller 190. In this way, the main controller 300 calculates and stores the median average, which is an average value of the values obtained by subtracting the temperature values of the inner compartments CA1 to CA12 from the desired temperature, respectively (803 and 804).

Next, the main controller 300 controls the system air conditioner control unit 290 to allow the system air conditioner control unit 290 to detect the room temperature of the outer compartment area PA1 to PA4 by the outer compartment area temperature sensor 260a to 260d. Supply the signal. Accordingly, the system air conditioner controller 290 controls the outside compartment area temperature sensors 260a to 260d to sense the room temperature of the outside compartment areas PA1 to PA4. Accordingly, each of the outer compartment area temperature sensors 260a to 260d senses the room temperature of each of the outer compartment areas PA1 to PA4, and controls the temperature value of each of the outer compartment areas PA1 to PA4. ), And the system air conditioner control unit 290 supplies the temperature values of each of the outer compartments PA1 to PA4 to the main control unit 300. In this way, the main control unit 300 selects the outside compartment region temperatures smaller than the desired temperature among the temperature values of the respective outside compartment regions, and heats the average value of the values obtained by subtracting the desired compartment temperature from the selected outside compartment region temperatures. Calculate and store the required average, and select the outside compartment zone temperatures that are greater than the desired temperature among the temperature values of each outside compartment zone, and then calculate the cooling demand which is the average value of the values obtained by subtracting the selected outside compartment zone temperatures to the desired temperature. The average is calculated and stored (805, 806).

Then, the main control unit 300 controls to prevent the generation of mixing loss to be described below by using the heating demand average, the cooling demand average, and the median average obtained through steps 802 to 805 described above.

The main controller 300 determines whether the heating demand average is greater than the cooling demand average (807).

Here, if the heating demand average is larger than the cooling demand average, the main controller 300 controls the system air conditioner control unit 290 to allow the system air conditioner control unit 290 to control the heating operation of the system air conditioner 200. Accordingly, the system air conditioner 200 performs a heating operation (408). The main control unit 300 controls the central air conditioning system control unit 190 so that the central air conditioning system 100 operates normally according to the heating schedule. Accordingly, the central air conditioning system 100 performs normal operation (409). In this way, both the central air conditioning system 100 and the system air conditioner 200 perform a heating operation so that no mixing loss occurs in the interior of the building. Subsequently, the main controller 300 determines whether the reference time has elapsed (810), and if the reference time has not elapsed, continuously determines whether the reference time has elapsed, and if it is determined that the reference time has elapsed, determines whether the operation termination condition has passed. In operation 811, if the operation is terminated, the operation is terminated, and if the operation is not an operation termination condition, the operation returns to step 801, and the steps 801 and 801 are performed. Here, the reference time may be selected by experiment as a time at which the temperature distribution of the room is changed and again, a mixing loss may occur.

If the heating demand average is not greater than the cooling demand average, the main controller 300 determines whether the median average is larger than the cooling demand average (812).

At this time, if the median average is larger than the cooling demand average, the main controller 300 determines that the entire area of the room is preferentially heated, and the central air conditioning system 100 and the system air conditioner 200 perform heating operation. The central air conditioner control unit 190 and the system air conditioner control unit 290 are controlled (813, 814). In this way, although the discomfort index in the outer area PA that the system air conditioner 200 is in charge is rather high, the mixing loss does not occur in the interior of the building. Subsequently, the main controller 300 performs step 810 and subsequent steps.

If the median average is not greater than the cooling demand average, the main control unit 300 controls the central air conditioning control unit 190 and the system air conditioner control unit 290 so that mixing loss does not occur. In this way, the system air conditioner control unit 290 controls the system air conditioner 200 according to the cooling operation mode, and accordingly, the system air conditioner 200 performs the cooling priority operation according to the cooling operation mode (815). The central air conditioning control unit 190 is an air supply damper adjacent to a system air conditioner indoor unit that performs cooling operation among the system air conditioner indoor units 220a to 220d among the air supply dampers 191a to 191l and the return hole dampers 180a to 180l. And control to close the return vent damper (816), and the central air conditioning system 100 controls the central air conditioning system 100 to perform normal operation according to the heating operation schedule (817). , The warm air discharged to the air supply unit adjacent to the system air conditioner indoor unit performing the cooling operation and the cold air discharged from the system air conditioner indoor unit performing the cooling operation among the system air conditioner indoor units 220a to 220d are mixed. This is prevented from mixing loss, is prevented from the excessive return port adjacent to the air-conditioning system, the indoor units performing the cooling operation, cooled air is introduced it can be prevented a phenomenon that the efficiency of the central air conditioning system decreases.

Next, the main controller 300 performs step 810 and subsequent steps.

If the central air conditioning system 200 is controlled by the central air conditioning system 100 according to the cooling operation schedule in step 801, the main controller 300 may include the central air conditioning control unit 190 as the central air conditioning system. Control to control the 100 according to the heating operation schedule. In this case, the central air conditioning control unit 190 controls the central air conditioning system 100 to perform a cooling operation (818).

The central air conditioning controller 190 detects the room temperature of the inner compartment regions CA1 to CA12 that each of the inner compartment region temperature sensors 170a to 170l is in charge of. Accordingly, each of the inner compartment area temperature sensors 170a to 170l senses the temperature of each of the inner compartment areas CA1 to CA12 and provides the respective temperature values to the central air conditioning controller 190. In this case, the main controller 300 calculates and stores the median average, which is an average value of the values obtained by subtracting the temperature values of the inner compartments CA1 to CA12 to the desired temperature, respectively (819 and 820).

Next, the main controller 300 controls the system air conditioner control unit 290 to allow the system air conditioner control unit 290 to detect the room temperature of the outer compartment area PA1 to PA4 by the outer compartment area temperature sensor 260a to 260d. Supply the signal. Accordingly, the system air conditioner controller 290 controls the outside compartment area temperature sensors 260a to 260d to sense the room temperature of the outside compartment areas PA1 to PA4. Each of the outside compartment area temperature sensors 260a to 260d senses the indoor temperature of each of the outside compartment areas PA1 to PA4 and supplies the temperature values of the respective outside compartment areas PA1 to PA4 to the system air conditioner control unit 290. The system air conditioner controller 290 supplies the temperature values of the respective outer compartments PA1 to PA4 to the main controller 300. In this way, the main control unit 300 selects the outside compartment region temperatures smaller than the desired temperature among the temperature values of the respective outside compartment regions, and heats the average value of the values obtained by subtracting the desired compartment temperature from the selected outside compartment region temperatures. Calculate and store the required average, and select the outside compartment zone temperatures that are greater than the desired temperature among the temperature values of each outside compartment zone, and then calculate the cooling demand which is the average value of the values obtained by subtracting the selected outside compartment zone temperatures to the desired temperature. The average is calculated and stored (821, 822).

Then, the main control unit 300 controls to prevent the generation of mixing loss to be described below by using the heating demand average, the cooling demand average, and the median average obtained through steps 819 to 822 described above.

The main controller 300 determines whether the cooling demand average is larger than the heating demand average (807).

Here, if the cooling demand average is larger than the heating demand average, the main controller 300 controls the system air conditioner control unit 290 to allow the system air conditioner control unit 290 to control the heating operation of the system air conditioner 200. Accordingly, the system air conditioner 200 performs a cooling operation (824). The main control unit 300 controls the central air conditioning system control unit 190 so that the central air conditioning system 100 operates normally according to the cooling schedule. Accordingly, the central air conditioning system 100 performs normal operation (825). In this way, both the central air conditioning system 100 and the system air conditioner 200 perform a heating operation so that no mixing loss occurs in the interior of the building. Subsequently, the main controller 300 performs steps 810 and subsequent steps for determining whether the reference time has elapsed.

If the cooling demand average is not larger than the heating demand average, the main controller 300 determines whether the median average is larger than the heating demand average (826).

At this time, if the median average is larger than the heating demand average, the main control unit 300 determines that the entire area of the room is preferentially required to be preferred, the central air conditioning system 100 and the system air conditioner 200 is heating operation The central air conditioner controller 190 and the system air conditioner controller 290 are controlled to perform the operation (827, 828). In this way, although the discomfort index in the outer area PA that the system air conditioner 200 is in charge is rather high, the mixing loss does not occur in the interior of the building. Subsequently, the main controller 300 performs step 810 and subsequent steps.

If the median average is not greater than the heating demand average, the main control unit 300 controls the central air conditioning control unit 190 and the system air conditioner control unit 290 so that mixing loss does not occur. In this way, the system air conditioner control unit 290 controls the system air conditioner 200 according to the heating operation diagram, and accordingly, the system air conditioner 200 performs the heating priority operation according to the heating operation mode (829). The central air conditioning control unit 190 is an air supply damper adjacent to a system air conditioner indoor unit which performs heating operation among the system air conditioner indoor units 220a to 220d among the air supply dampers 191a to 191l and the return outlet dampers 180a to 180l. And the control to close the return port damper (830), and the central air conditioning system 100 controls the central air conditioning system 100 to perform normal operation according to the heating operation schedule (831). , Cold air discharged from the air supply unit adjacent to the system air conditioner indoor unit performing heating operation and warm air discharged from the system air conditioner indoor unit performing heating operation among the system air conditioner indoor units 220a to 220d are mixed. Is a loss is prevented from mixing, that is a transient return port adjacent to the air-conditioning system, the indoor unit is heated to perform a heating operation, air flows can be prevented thereby preventing the phenomenon in which the efficiency of the central air conditioning system decreases.

Next, the main controller 300 performs step 810 and subsequent steps.

Hereinafter, a mixed air conditioning system and a method of controlling the same according to the fourth embodiment of the present invention will be described with reference to the drawings, but in a part compared with the control method of the mixed air conditioning system according to the third embodiment of the present invention. A limited description will be given and the mixed air conditioning system according to the fourth embodiment of the present invention will be referred to the mixed air conditioning system according to the first embodiment of the present invention.

10 and 11, the method of calculating the median average of the control method of the mixed air conditioning system according to the fourth embodiment of the present invention is compared with the method of calculating the median average according to the third embodiment of the present invention. .

In other words, if the central air conditioning system 200 is controlled by the central air conditioning system 100 according to the heating operation schedule, the central air conditioning system control unit 190 may have an inner compartment adjacent to the outer compartments PA1 to PA4. It detects the room temperature of the adjacent inner compartment area (CA1 ~ CA4) each of the area temperature sensor (170a ~ 170d). Accordingly, each of the adjacent inner compartment region temperature sensors 170a to 170d senses the temperature of each of the inner compartment regions CA1 to CA4 and provides respective temperature values to the central air conditioning controller 190. In this case, the main controller 300 calculates and stores the median average, which is an average value of values obtained by subtracting the temperature values of the inner compartments CA1 to CA4 from the desired temperature, respectively (904 and 905).

If the central air conditioning system 200 is controlled by the central air conditioning system 100 according to the cooling operation schedule, the control unit 190 of the central air conditioning system has an inner compartment area adjacent to the outer compartment areas PA1 to PA4. To sense the room temperature of the adjacent inner compartment area (CA1 ~ CA4) each of the temperature sensors (170a ~ 170d). Accordingly, each of the inner compartment region temperature sensors 170a to 170d senses the temperature of each of the adjacent inner compartment regions CA1 to CA4 and provides each temperature value to the central air conditioning controller 190. In this case, the main controller 300 calculates and stores the median average, which is an average value of the values obtained by subtracting the desired temperature into the temperature values of the inner compartments CA1 to CA4, respectively (919 and 920).

1 is a schematic view showing a mixed air conditioning system according to the present invention.

FIG. 2 is a plan view showing the arrangement of the air supply and exhaust ports of the central air conditioning system and the indoor units of the system air conditioner according to the first embodiment of the present invention.

3 is a block diagram illustrating a control system of a mixed air conditioning system according to a first embodiment of the present invention.

4 and 5 are flowcharts showing a control procedure of the mixed air conditioning system according to the first embodiment of the present invention.

6 and 7 are flowcharts illustrating a control procedure of the mixed air conditioning system according to the second embodiment of the present invention.

8 and 9 are flowcharts illustrating a control procedure of a mixed air conditioning system according to a third embodiment of the present invention.

10 and 11 are flowcharts illustrating a control procedure of a mixed air conditioning system according to a fourth embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: central air conditioning system 170a ~ 170l: inner compartment area temperature sensor

180a-180l: Return opening damper 190: Central air conditioning control

191a-191l: Air supply damper 200: System air conditioner

260a to 260d: outside compartment area temperature sensor 290: system air conditioner control unit

Claims (14)

It is determined whether the central air conditioning system which controls the inner compartment area of the building is controlled according to the heating schedule, Calculating a center peak of the central air conditioning system according to the determination result; It senses the temperature of the outside compartment area which each of the plurality of indoor units of the system air conditioner which air-conditions the outside compartment area of a building, The heating peak of the system air conditioner is calculated by subtracting the minimum value of the detected temperatures of the outside compartment from the desired temperature. The cooling peak of the system air conditioner is calculated by subtracting a maximum value of the detected outside compartment area from the desired temperature. Control method of the mixed air conditioning system for controlling the opening and closing of the air supply and return port of the central air conditioning system and the operation of the indoor unit of the system air conditioner by comparing the central peak, the heating peak and the cooling peak, to prevent mixing loss . delete The method of claim 1, The central peak senses the temperature of the inner compartment regions when the central air conditioning system is controlled according to a heating schedule, and calculates by subtracting the temperature of the inner compartment region from the desired temperature to the minimum value. Control method. The method of claim 1, The central peak senses the temperature of the inner compartments when the central air conditioning system is controlled according to a cooling schedule, and calculates by subtracting a maximum value of the temperatures of the inner compartments to a desired temperature. Control method. The method according to claim 3 or 4, And the inner compartment regions are defined by the inner compartment regions adjacent to the outer compartment regions. The method of claim 1, When the central air conditioning system is controlled according to a heating schedule, when the cooling peak is larger than the heating peak and the cooling peak is larger than the central peak, the indoor unit of the system air conditioner performs the cooling operation and performs the cooling operation. And controlling the air supply and return ports of the central air conditioning system adjacent to the indoor unit. The method of claim 1, When the central air conditioning system is controlled according to a cooling schedule, when the heating peak is larger than the cooling peak and the heating peak is larger than the central peak, the indoor unit of the system air conditioner performs the heating operation and performs the heating operation. And controlling the air supply and return ports of the central air conditioning system adjacent to the indoor unit. It is determined whether the central air conditioning system which controls the inner compartment area of the building is controlled according to the heating schedule, Calculating a median average of the central air conditioning system according to the determination result; It senses the temperature of the outside compartment area which each of the plurality of indoor units of the system air conditioner which air-conditions the outside compartment area of a building, Calculating a heating demand average, which is an average of values obtained by subtracting the temperatures of the outer compartment region smaller than the network temperature among the temperatures of the outer compartment region to the desired temperature; Calculating a cooling demand average, which is an average of values obtained by subtracting temperatures of the outer compartment area larger than the desired temperature from the temperatures of the outer compartment area to the desired temperature; Control of the mixed air conditioning system to control the opening and closing of the air supply and return ports of the central air conditioning system and the operation of the indoor unit of the system air conditioner by comparing the median average, the heating demand average and the cooling demand average, to prevent the mixing loss. Way. delete 9. The method of claim 8, The median average senses the temperature of the inner compartment regions when the central air conditioning system is controlled according to a heating schedule, and thus the temperature of the inner compartment region smaller than the desired temperature among the temperatures of the inner compartment region at a desired temperature. Control method of a mixed air conditioning system, which is the average of the values subtracted from each other. 9. The method of claim 8, The median average senses temperatures of the inner compartment regions when the central air conditioning system is controlled according to a cooling schedule, and selects temperatures of the inner compartment regions that are greater than the desired temperature among the temperatures of the inner compartment regions. A method of controlling a mixed air conditioning system that is an average of values subtracted by temperature. The method according to claim 10 or 11, And the inner compartment regions are defined by the inner compartment regions adjacent to the outer compartment regions. 9. The method of claim 8, When the central air conditioning system is controlled according to a heating schedule, when the cooling demand average is larger than the heating demand average and the cooling demand average is larger than the median average, the indoor unit of the system air conditioner performs the cooling operation and the cooling operation. The control method of the mixed air conditioning system to close the air supply and return port of the central air conditioning system adjacent to the indoor unit. 9. The method of claim 8, When the central air conditioning system is controlled according to a cooling schedule, when the heating demand average is larger than the cooling demand average and the heating demand average is larger than the median average, the indoor unit of the system air conditioner performs the heating operation and the heating operation. The control method of the mixed air conditioning system to close the air supply and return port of the central air conditioning system adjacent to the indoor unit.

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