KR100810508B1 - Air conditioning system and control method thereof - Google Patents

Abstract

An air conditioning system and a method for controlling the same are provided to reduce power consumption by reflecting a request from a user by controlling at least one of indoor units, outdoor units, and a relay. An air conditioning system includes a plurality of indoor units(30), a plurality of outdoor units(20), and a control unit(50) calculating priority of the indoor units by applying weight defined by a user to variables by first periods. The control unit turns on and off at least one of the indoor units and the outdoor units based on the calculated priority. An alarm generator(40) receives a peak power message or a normal message from the outside by second periods longer than or equal to the first periods. In case the alarm generator receives the peak power message, the alarm generator transmits an alarm message.

Description

System air conditioner and its control method {AIR CONDITIONING SYSTEM AND CONTROL METHOD THEREOF}

1 is a block diagram of a system air conditioner according to an embodiment of the present invention.

2 is a control flowchart of a system air conditioner according to an embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

  10: repeater 20: outdoor unit

  30: indoor unit 40: alarm generating unit

  50 control unit 100 system air conditioner

The present invention relates to a system air conditioner and a control method thereof, and more particularly, to reduce power consumption by reflecting a user's request.

The system air conditioner includes at least one indoor unit, at least one outdoor unit, at least one repeater, an alarm generating unit, and a control unit for controlling them.

The driving of such a plurality of devices consumes a lot of power, and the power consumed by the devices requires proper control.

The periodicity of power consumption from the power source receives the message and controls the power consumed by the received message.

When a conventional system air conditioner periodically receives a message exceeding a peak for power consumption, the control unit operates a power control function. At this time, the control unit operates at least one of the indoor unit and the outdoor unit by a control algorithm that does not reflect the user's request. Turn on / off. This has a problem that the system air conditioner operates by ignoring the surrounding environment and the user's request, so that the user can determine that the system air conditioner is not performing proper operation.

The present invention is to solve the above-described problem, to allow to control the power consumption in consideration of the user's needs and the surrounding environment.

In order to achieve the above object, the system air conditioner according to the present invention calculates the priority of the indoor unit by applying a user-defined weight to at least one variable at least one indoor unit, at least one outdoor unit, and at least one first period And a controller for turning on / off at least one of the at least one indoor unit and the at least one outdoor unit based on the calculated priority.

The variable here includes the operating time of the indoor unit, the wind strength of the indoor unit, the compressor operation rate of the indoor unit, the room temperature of the space in which the indoor unit is placed, and the set temperature of the indoor unit.

The system air conditioner according to the present invention further includes an alarm generating unit for receiving a peak power message or a normal message every second period greater than or equal to the first period from the outside, wherein the alarm generating unit receives a peak power message The alarm message is sent to the control unit.

When the controller receives the alarm message, the controller calculates the priority of the indoor unit and turns on / off at least one of the at least one indoor unit and the at least outdoor unit based on the priority.

The above object of the present invention is a control method of a system air conditioner including at least one indoor unit, at least one outdoor unit, and an alarm generating unit for transmitting an alarm message,

(a) receiving an alarm message from the alarm generating unit; and (b) determining the priority of the indoor unit by applying a weight defined by the user to at least one variable for every first period when the alarm message is received. And (c) turning on / off at least one of the at least one indoor unit and the at least one outdoor unit based on the priority.

Here, before step (a), the alarm generation unit may further include receiving a normal message or peak power message every second period greater than or equal to the first period from the outside and transmitting an alarm message when the peak power message is received.

And, in step (b), at least one variable includes the operation time of the indoor unit, the wind strength of the indoor unit, the operation rate of the compressor of the indoor unit, the room temperature of the space in which the indoor unit is placed, and the set temperature of the indoor unit.

1 is a block diagram of a system air conditioner according to an embodiment of the present invention.

As shown in FIG. 1, the system air conditioner 100 according to the present invention includes at least one outdoor unit 20, at least one indoor unit 30, and a controller 50 for controlling them.

The system air conditioner 100 further includes a control unit 50 and at least one repeater to allow at least one of the outdoor unit 20 and the indoor unit 30 to transmit and receive a control message.

System air conditioners are classified functionally into compressors, condensers, expansion valves and evaporators.

The compressor performs a function of increasing the pressure to a saturation pressure corresponding to the condensation temperature so as to suck the low-temperature low-temperature gas refrigerant evaporated in the evaporator to liquefy condensation in the next condenser.

The condenser heat-exchanges the high-temperature, high-pressure gas refrigerant discharged from the compressor to the surrounding air or cooling water to release the heat of the gas refrigerant to condense and liquefy.

The expansion valve functions to condense the condensed liquefied refrigerant that has passed through the narrow area to a wide area to release the refrigerant from pressure and evaporate it.

An evaporator is a device that exchanges heat with a cooled object by introducing a low temperature low pressure refrigerant through an expansion valve. That is, the device achieves the purpose of refrigeration and freezing using the heat of evaporation of the refrigerant.

The outdoor unit 20 includes a condenser that heat-exchanges the high-temperature, high-pressure gas refrigerant discharged from the compressor of the indoor unit 30 to surrounding air or cooling water to release heat of the gas refrigerant to condense and liquefy. A plurality of outdoor units 20 may be provided, and at least one indoor unit 30 may be connected to one outdoor unit 20. That is, one refrigerant pipe from the outdoor unit 20 is classified into various types, and the indoor unit 30 is connected to each branch. At this time, the expansion valve is attached to each branch pipe and to connect the indoor unit (30). In addition, at least one outdoor unit 20 may be connected to one repeater 10.

The indoor unit 30 includes a compressor and further includes various sensors. It includes a sensor for sensing the surrounding environment, such as a sensor for detecting the current temperature of the place where the indoor unit 30 is placed, a sensor for detecting the humidity. In addition, the indoor unit 30 may include a user input unit (not shown). The user may set the set temperature such that the current temperature of the place where the indoor unit 30 is currently placed reaches the set temperature through the user input unit, and may set the current humidity or the like to reach the set value. The indoor unit 30 collects and stores the environmental information detected by the sensor, and also transmits the environmental information to the controller 50.
On the other hand, the controller 50 calculates the priority of the indoor unit 30 by applying a user-defined weight to at least one variable for every first period, and based on the calculated priority, the at least one indoor unit 30. ) And at least one of the at least one outdoor unit 20 may be turned on / off.

The repeater 10 allows the controller 50 and at least one of the outdoor unit 20 and the indoor unit 30 to transmit and receive control messages to each other. The repeater 10 is generally provided between the control unit 50 and the outdoor unit 20 to transmit and receive a control message, and when the indoor unit 30 collects environmental information of the space in which it is placed and transmits it to the control unit 50, the repeater ( 10) receives this environmental information and delivers it to the controller 50.

The system air conditioner 100 further includes an alarm generator 50.

The alarm generating unit 50 is connected to a power supply company such as KEPCO and is also connected to the control unit 50. The power supply company may measure and monitor the power consumed by the system air conditioner 100 through the alarm generator 50.

The power supplier monitors the power consumed by the system air conditioner 100 every second cycle through the alarm generator 50, and transmits a normal message if the power consumed by the system air conditioner 100 is less than or equal to the reference value. If abnormal, the peak power message is transmitted. When the alarm generator 50 receives the normal message or the peak power message from the power supply company, the alarm generator 50 transmits the corresponding normal power message or alarm message to the controller 50.

Here, the second period refers to a period of a predetermined time, and may be set to one of several values, such as 10 minutes, 15 minutes, and 20 minutes.

When the controller 50 receives the normal power message or the alarm message from the alarm generator 50, the controller 50 maintains the operation of the current indoor unit 30 or the outdoor unit 20 in the case of the normal power message. However, upon receiving the alarm message, the controller 50 controls the indoor unit 30, the outdoor unit 20, and the repeater 10 every first cycle. Here, the first period is a time equal to or less than the first period. The first period may be set to 5 minutes, 10 minutes, 15 minutes, and generally 5 minutes.

The controller 50 sets the priority of the indoor unit 30 by applying the weight of the user's request to at least one variable after receiving the alarm message. The control unit 50 transmits a control message to the indoor unit 30 so that the indoor unit 30 having a lower priority is turned off by the set priority. The off control message transmitted from the controller 50 is transmitted to the indoor unit 30 through the repeater 10 and the outdoor unit 20, and the indoor unit 30 is powered off according to the control message. Although the control message has been described as an example of the power off message, the power off message may include not only a power off message but also a message about the wind strength and a set temperature message. At least one variable used by the controller 50 to set the priority of the indoor unit 30 includes environmental information received from each indoor unit 30. At least one variable determines the priority based on the environmental information transmitted by each indoor unit 30 by sensing the environment of the space in which it is placed. The environmental information, that is, the variables include the operating time of the indoor unit 30, the wind strength of the indoor unit 30, the operation rate of the compressor of the indoor unit 30, the room temperature of the space in which the indoor unit 30 is placed, and the indoor unit 30. Contains information about temperature.

If one indoor unit 30 is connected to the outdoor unit 20, the controller 50 may transmit a control message for turning off both the outdoor unit 20 and the indoor unit 30.

In addition, if the outdoor unit 20 to which one indoor unit 30 is connected to the repeater 10 is connected, the controller 50 controls a control message for turning off the repeater 10, the outdoor unit 20, and the indoor unit 30. I can send it.

The following describes in more detail the features of the system air conditioner 100 through one embodiment of the present invention.

 The system air conditioner 100 according to the present invention includes an alarm generator 50 for communicating with at least one indoor unit 30, at least one outdoor unit 20, at least one repeater 10, and a power supply company. Include.

The indoor unit 30 may be installed on the ceiling of the place where it is placed, and may be installed upright as a tower, and may be attached to a wall or the like. In addition, the tongue () includes at least one sensor. The indoor unit 30 may detect and store the actual temperature and the actual humidity of the current place where it is placed through the sensor. The indoor unit 30 may periodically detect and store the actual temperature and the actual humidity of the place where it is placed, and transmit the same to the controller 50.

The indoor unit 30 may include a user input unit (not shown), and the user may set the actual temperature and the actual humidity of the place where the indoor unit 30 is currently placed to reach a value set by the user through the user input unit. The user input unit may be provided on the surface of the indoor unit 30 and may be provided as a remote device such as a remote controller. The indoor unit 30 also transmits information on a set temperature, a set humidity, and the like input through the user input unit to the controller 50.

The outdoor unit 20 is connected to the at least one indoor unit 30 to operate in conjunction with the indoor unit 30 so that the current temperature of the place where the indoor unit 30 is placed reaches a set temperature. In addition, the outdoor unit 20 may transmit the information received from the indoor unit 30 to the controller 50. The outdoor unit 20 does not transmit only the information received from the indoor unit 30 to the control unit 50. The outdoor unit 20 may also transmit environmental information of the place where it is placed, and may transmit its own state information and the like to the control unit 50.

The repeater 10 has at least one outdoor unit 20 connected thereto, and functions to transmit a message so that the controller 50 and at least one of the outdoor unit 20 and the indoor unit 30 can communicate with each other.

The alarm generating unit 50 is connected to the power supplier and the controller 50 so that the power supplier and the controller 50 can transmit and receive control messages.

The controller 50 may be connected to the repeater 10 and the alarm generator 50 to control the repeater 10, the outdoor unit 20, and the indoor unit 30, and supply power through the alarm generator 50. You can send and receive control messages with your company.

The controller 50 periodically receives, stores, and updates various environmental information from the repeater 10, the outdoor unit 20, and the indoor unit 30. In addition, the control unit 50 may receive information on power currently being consumed through the alarm generating unit 50 from a power supply company.

The power supply company monitors the power consumed by the system air conditioner 100 every second cycle (for example, 15 minutes) and transmits it to the alarm generator 50. The alarm generator 50 receives the normal message or the peak power message from the power supply company, and transmits the power normal message in the case of the normal message, and the alarm message to the controller 50 in the case of the peak power message.

When the controller 50 receives the alarm message from the alarm generator 50, the controller 50 determines the priority of the indoor unit 30 by applying a weight defined by the user to at least one variable. When the priority is determined, the controller 50 controls the indoor unit 30 in order from the indoor unit 30 having the lowest priority to the indoor unit 30 having the highest priority. The control unit 50 controls the indoor unit 30 includes a method of turning off the indoor unit 30, changing a set temperature, and adjusting wind strength. The variable to which the control unit 50 applies the weight defined by the user includes the operation time of the indoor unit, the wind strength of the indoor unit, the operation rate of the compressor of the indoor unit, the indoor temperature of the space where the indoor unit is placed, the set temperature of the indoor unit, and the like. .

As a method of determining the priority of the indoor unit 30 by the controller 50, the following equation may be used as an example.

Score = F (current temperature, set temperature, compressor running rate, wind strength, running time)

F (v, w, x, y, z) = k (current temperature-set temperature) + (1-k) (compressor operation rate X wind strength X operating time)

[Equation]

Here, k (present temperature-set temperature) is a desire index for the user's coolness, and (1-k) (compressor operation rate X wind strength X operating time) is an indicator of power consumption. That is, according to the setting of the k value, the user may further weight one of the desire index for coolness and the index for power consumption. k corresponds to a weight defined by the user.

Variables such as current temperature, set temperature, compressor operation rate, wind strength, and operating time are values detected by a sensor of the indoor unit 30 or a value received through a user input unit. The controller 50 may periodically collect variables such as a current temperature, a set temperature, a compressor operation rate, a wind strength, and an operating time from each indoor unit 30. The controller 50 may collect variables for the outdoor unit 20 and the repeater 10 from the outdoor unit 20 and the repeater 10 as well as the indoor unit 30, and the outdoor unit 20 and the repeater 10. The variable for may also serve as a variable for determining the priority of the indoor unit 30.

The controller 50 determines the priority of the indoor unit 30 every first period (eg, 5 minutes) and controls the indoor unit 30 according to the priority. In addition, the controller 50 controls the indoor unit 30 by the above algorithm (Algorithm) for each first period during the first second period, and stops controlling the indoor unit 30 when receiving the normal power message in the second second period. The operating state of the indoor unit 30 is maintained. If the controller 50 receives the alarm message in the second second period, the controller 50 continuously controls the operation of the indoor unit 30.

The controller 50 alarms from the alarm generator 50 in a state where one outdoor unit 20 is connected to one repeater 10 and one indoor unit 30 is connected to one outdoor unit 20. Upon receiving the message, the power of both the repeater 10, the outdoor unit 20, and the indoor unit 30 may be turned off.

The calculating of the priority of the indoor unit 30 may be performed by the controller 50, but the control of the indoor unit 30 and the outdoor unit 20 by the priority may be performed by the repeater 10.

The system air conditioner 100 according to the present invention may calculate the priority of the indoor unit 30 based on at least one of the user's desire index and the power consumption index, and according to the calculated priority, the indoor unit 30, At least one of the outdoor unit 20 and the repeater 10 may be controlled.

2 is a control flowchart of a system air conditioner according to an embodiment of the present invention.

As shown in FIG. 2, a control method of a system air conditioner including at least one indoor unit, at least one outdoor unit, and an alarm generating unit for transmitting an alarm message includes a normal power message or an alarm message from the alarm generating unit every second period. Receive (S10). When receiving the alarm message, the priority of the indoor unit is determined by applying a weight defined by the user to at least one variable for each first period (S20). At least one of the at least one indoor unit 30 and the at least one outdoor unit 20 is turned on / off based on the priority (S30).

Wherein the first period is less than or equal to the second period.

At least one variable includes the operating time of the indoor unit 30, the wind strength of the indoor unit 30, the operation rate of the compressor of the indoor unit 30, the room temperature of the space in which the indoor unit 30 is placed, and the setting of the indoor unit 30. Includes temperature.

Variables used to determine the priority may include variables for the repeater 10 and the outdoor unit 20 in addition to the above variables.

Although some embodiments of the invention have been shown and described, it will be apparent to those skilled in the art that modifications may be made to the embodiment without departing from the spirit or spirit of the invention. will be. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.

As described above, the system air conditioner and its control method according to the present invention are for controlling at least one of an indoor unit, an outdoor unit, and a repeater based on a weight defined by a user.

Claims (7)

In the system air conditioner, At least one indoor unit; At least one outdoor unit; Calculate the priority of the indoor unit by applying a user-defined weight to at least one variable for every first period and turn on at least one of the at least one indoor unit and the at least one outdoor unit based on the calculated priority. A system air conditioner comprising a control unit for turning on / off. The method of claim 1, The variable includes the operating time of the indoor unit, the wind strength of the indoor unit, the operation rate of the compressor of the indoor unit, the room temperature of the space in which the indoor unit is placed, and the set temperature of the indoor unit. The method of claim 1, The apparatus may further include an alarm generator configured to receive a peak power message or a normal message every second period that is greater than or equal to the first period from the outside. And the alarm generating unit transmits an alarm message to the control unit when the peak power message is received. The method of claim 3, The control unit calculates a priority of the indoor unit when receiving the alarm message, and turns on / off at least one of the at least one indoor unit and the at least outdoor unit based on the priority.   A control method of a system air conditioner including at least one indoor unit, at least one outdoor unit, an alarm generating unit for transmitting an alarm message, and a control unit for turning on / off at least one of the indoor unit and the outdoor unit. (a) receiving the alarm message from the alarm generator; (b) determining the priority of the indoor unit by applying a weight defined by a user to at least one variable at any first period when the alarm message is received; (c) turning on / off at least one of the at least one indoor unit and the at least one outdoor unit based on the priority. The method of claim 5, before the step (a), the alarm generation unit receives a normal message or a peak power message every second period that is greater than or equal to the first period from the outside and sends the alarm message to the controller when the peak power message is received. The control method of the system air conditioner further comprising. The method of claim 5, In step (b), the at least one variable includes an operating time of the indoor unit, a wind strength of the indoor unit, an operation rate of the compressor of the indoor unit, an indoor temperature of a space in which the indoor unit is placed, and a set temperature of the indoor unit. The control method of the system air conditioner, characterized in that.

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