KR102137021B1 - Facility control system, central control apparatus of the system and facility control method - Google Patents

Abstract

The technical problem to be achieved by the present invention is to solve the conventional problem, and in the case of providing the user with the amount of power used measured by the watt hour meter, a facility control system capable of providing information on the amount of power used corrected according to the type of load, It is to provide a central control device and a facility control method included therein.
As a means for solving the above-described technical problem, the present invention provides a first watt-hour meter for measuring the amount of power consumed by load group for at least one facility or equipment, and a correlation coefficient based on a power factor calculated through the amount of power consumed by each load group. And calculating the corrected power consumption for each load group by applying the correlation coefficient to the power consumption for each load group.
The facility control system according to the present invention, the central control device and the facility control method included therein, can provide information on the amount of power used corrected according to the type of load when the amount of power used measured by the power meter is provided to the user. .

Description

Facility control system, central control unit and facility control method included therein {FACILITY CONTROL SYSTEM, CENTRAL CONTROL APPARATUS OF THE SYSTEM AND FACILITY CONTROL METHOD}

The present invention relates to a facility control system, a central control device and a facility control method included therein, and in detail, a facility control system for measuring the amount of power of a load group having different characteristics, a central control device and a facility control method included therein It is about the invention.

In general, buildings are supplied with 380V of 3-phase, 4-wire type provided by the power company, and the power provided by the power company is supplied to the load as it is, or the power is supplied to the load in the form of single-phase 220V. do.

For example, electric power provided by a power company is distributed to an air conditioner for performing air conditioning such as cooling and heating for each zone divided into several zones.

1 is a diagram showing a connection relationship between a conventional air conditioner group and a power meter.

In a typical building, as shown in FIG. 1, power is supplied from a power company through a power lead-in line, and the second watt-hour meter 12 is connected to the power lead-in line to measure the amount of power used by the load for a predetermined time.

At this time, the second watt-hour meter 12 may display the maximum allowable power value allowed for each building limited by the power company, and if the maximum allowable power value is exceeded, the electricity bill is progressively levied or the fuse is blown. It can also automatically cut off the power applied to the inside.

The first watt-hour meters 11a and 11b measure the amount of power used for a predetermined period of time by each load group by distributing and supplying the power introduced to the building.

The load group includes at least one load connected to the first watt hour meter 11a, 11b, and in this case, the load means, as an example, a facility or equipment that uses power in a building, and a facility (a drawing of FIG. 4 Reference numeral 200) may be, for example, an air conditioner (including air conditioners, ventilation devices, fans, boilers, cooling towers, etc.), various pumps, lighting, electric devices, etc. In the case of using the cooling tower system as a facility, the facility (Fig. 4 Reference numeral 300) may be a cooling tower, a pump, a temperature sensor, or the like.

As shown in FIG. 1, a load group connected to the first watt hour meters 11a and 11b may be an air conditioner in which a plurality of indoor units 14a and 14b are connected to, for example, one outdoor unit 13a and 13b.

In this case, the outdoor units 13a and 13b are operated by the power distributed from the power received in the building through the second watt-hour meter 12, and the power consumed during operation for a certain period of time is the first watt-hour meters 11a and 11b. It can be measured by

Therefore, the conventional central control device 15 receives the amount of power used measured by the first watt-hour meters 11a and 11b and the second watt-hour meter 12, and monitors the amount of power measured by the watt-hour meter.

On the other hand, although the sum of the amount of power used by each load group received from the first power meter 11a and 11b by the central control device 15 must be equal to the total amount of power used received from the second power meter 12, the first power meter (11a, 11b) When the types of load groups connected to each are different, the sum of the amount of power used measured by the first watt-hour meter (11a, 11b) is not the same as the total amount of power used measured by the second watt-hour meter (12). And there was a problem that an error occurred.

Therefore, there is an urgent need for a necessary technology to solve this problem.

The technical problem to be achieved by the present invention is to solve the conventional problem as described above, and in the case of providing the user with the amount of power used measured by the watt hour meter, it is possible to provide information on the amount of power used corrected according to the type of load. It is to provide a facility control system, a central control device included therein, and a facility control method.

As a means for solving the above-described technical problem, the present invention provides a first watt-hour meter for measuring the amount of power consumed by load group for at least one facility or equipment, and a correlation coefficient based on a power factor calculated through the amount of power consumed for each load group. And calculating the corrected power consumption for each load group by applying the correlation coefficient to the power consumption for each load group.

According to an embodiment, a second power meter for measuring the total amount of power consumed by the at least one load group may be further included.

According to an embodiment, the total power consumption measured by the second watt hour meter is equal to a sum of the corrected power consumption amounts for each load group, regardless of a type of load between the load groups.

According to an embodiment, the correlation coefficient may be calculated by the following equation.

Here, λ is a correlation coefficient, D is an error between the sum of the total power consumption measured by the second watt hour meter and the power consumption for each load group measured by the first watt hour meter, and G _k is the consumption of the load group. The amount of power, l is the number of the load groups.

According to an embodiment, the corrected amount of power consumption for each load group may be calculated by the following equation.

According to an embodiment, the reference load group may be any load group among all load groups.

According to an embodiment, the central control device may include a communication unit that transmits and receives data to and from the first watt-hour meter or the second watt-hour meter through wireless communication.

According to an embodiment, the central control device may transmit a control command to at least one facility or equipment belonging to the load group directly or through a facility control device.

According to an embodiment, the central control device may compare the corrected power consumption amount for each load group with a reference power amount, and control the operation of the at least one facility or equipment according to the comparison difference.

In addition, the present invention calculates a correlation coefficient based on the power factor calculated from the power consumption of each load group for at least one facility or equipment measured by the first power meter, and the correlation coefficient is applied to the power consumption of each load group. It provides a central control device for a facility, characterized in that it calculates the corrected power consumption for each load group by applying.

According to an embodiment, the correlation coefficient may be calculated by the following equation.

Here, λ is a correlation coefficient, D is an error between the sum of the total amount of power consumed by the at least one load group measured through the second watt-hour meter and the sum of the amount of power consumed by the load group measured through the first watt-hour meter, G _k is the power consumption of the load group, and l is the number of the load groups.

According to an embodiment, the corrected amount of power consumption for each load group may be calculated by the following equation.

According to an embodiment, the central control device may include a communication unit that transmits and receives data to and from the first watt-hour meter or the second watt-hour meter through wireless communication.

According to an embodiment, the central control device may compare the corrected power consumption for each load group with a preset reference power amount, output an alarm signal according to the comparison difference, or control the operation of the at least one load. have.

In addition, the present invention includes the steps of measuring power consumption for each load group for at least one facility or equipment, calculating a power factor from the power consumption for each load group, calculating a correlation coefficient based on the power factor, and the It provides a facility control method comprising the step of calculating the corrected power consumption for each load group by applying a correlation coefficient to the measured power consumption for each load group.

According to an embodiment, it may further include measuring the total amount of power consumption consumed by the at least one load group.

According to an embodiment, the measured total power consumption is equal to a sum of the corrected power consumption for each load group, regardless of the type of load between the load groups.

According to an embodiment, the correlation coefficient may be calculated by the following equation.

Here, λ is a correlation coefficient, D is an error between the sum of the total power consumption and the power consumption for each load group, G _k is the power consumption of the load group, and l is the number of the load groups.

According to an embodiment, the corrected amount of power consumption for each load group may be calculated by the following equation.

According to an embodiment, the reference load group may be any load group among all load groups.

According to an embodiment, the method may further include receiving the amount of power consumption for each load group or the total amount of power consumption through wireless communication.

According to an embodiment, it may further include transmitting a control command to at least one facility or equipment belonging to the load group directly or through a facility control device.

According to an embodiment, the method may further include comparing the corrected power consumption amount for each load group with a reference power amount, and controlling the operation of the at least one facility or equipment according to the comparison difference.

Further, the present invention provides a computer-readable recording medium in which a computer program for executing the facility control method is recorded.

The facility control system according to the present invention, the central control device and the facility control method included therein, can provide information on the amount of power used corrected according to the type of load when the amount of power used measured by the power meter is provided to the user. .

Accordingly, the facility control system according to the present invention, the central control device and the facility control method included therein, prevents the occurrence of unintended control due to an error when operating a load or a load group through the central control device. Can be prevented.

That is, by controlling the operation of facilities or equipment based on the corrected power consumption for each load group, it is possible to increase satisfaction by maintaining the user's comfort as much as possible when controlling the air conditioner facilities.

1 is a diagram showing a connection relationship between a conventional air conditioner group and a power meter.
2 is a diagram schematically showing an example of a connection relationship between a power lead-in line and a load in the facility control system according to an embodiment of the present invention.
3 is a schematic diagram of a partial configuration of a facility control system according to an embodiment of the present invention.
4 is a diagram illustrating a configuration in which a central control device is connected to facilities or equipment according to an embodiment of the present invention.
5A is a step-by-step flowchart of a facility control method according to an embodiment of the present invention.
5B is a step-by-step flowchart of a facility control method according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. However, the present invention may be configured in various different forms and is not limited to the embodiments described herein. In the drawings, parts not related to the description are omitted in order to clearly describe the present invention, and similar parts will be described with like reference numerals throughout the specification.

Hereinafter, with reference to the accompanying drawings, specific technical content to be implemented in the present invention will be described in detail and clearly.

First Example

3 is a schematic diagram of a partial configuration of a facility control system according to an embodiment of the present invention.

As shown in FIG. 3, the facility control system 100 according to the present invention may include a first watt hour meter 110, a second watt meter 120, and a central control device 130.

The first watt-hour meters 111 to 116 measure the amount of power used for a predetermined period of time, in which power input to the building is distributed and supplied by each load group.

That is, the first watt hour meters 111 to 116 measure the amount of power used in the load groups G ₁ to G ₆ connected thereto. At this time, the first watt hour meters 111 to 116 may measure the amount of power used by the load groups G ₁ to G _{6 as} reactive power (or apparent power) in addition to active power, and further, the active power and reactive power (or Apparent power) can also be used to calculate the power factor (PF).

Meanwhile, the facility control system 100 according to the present invention may further include a second watt hour meter 120.

The second watt-hour meter 120 is connected to a power lead-in line so that power supplied from a power company is introduced into the building, and the power supplied from the power lead-in line is distributed and supplied to each group load (G ₁ to G ₆ ). .

Accordingly, the second watt hour meter 120 measures the total amount of power consumed by the entire at least one load group G ₁ to G ₆ .

2 is a diagram schematically showing an example of a connection relationship between a power lead-in line and a load in the facility control system according to an embodiment of the present invention.

As shown in FIG. 2, in general, a three-phase, four-wire type 380V power supply is supplied to a building, and a single-phase 220V type power supply is supplied for each group load.

As an example, 4 lines of R, S, T, and N are connected to the output terminal of the second watt hour meter 120, from which to supply single-phase 220V power to each load group (G ₁ to G ₆ ), Based on N, any one of R, S, and T may be wired to be connected to the input terminals of the first watt hour meters 111 to 116.

That is, the output terminals of the first watt-hour meters 111 to 116 are electrically connected to any one load group to supply power to the load groups G ₁ to G ₆ , for example, as shown in FIG. 2, Each of the input terminals of the six first watt-hour meters 111 to 116 is sequentially S, N / T, N / R, N / N, R / N, S / N, among the four lines of the output terminal of the second watt-hour meter 120. Can be connected with T.

At this time, the number of the first watt-hour meters 111 to 116, or the connection method between the first watt-hour meters 111 to 116 and the second watt-hour meter 120 may be designed differently, and the above example is the scope of the present invention. It is not intended to limit

In addition, the central control device 130 is connected to enable communication with the first watt hour meter 110 to receive the power factor calculated by the first watt hour meter 111 to 116, or the central control unit 130 The power factor may be directly calculated by receiving active power and reactive power (or apparent power) from the watt hour meters 111 to 116.

In addition, as will be described later, the central control device 130 may receive the total amount of power consumption measured through the second power meter 120 in order to calculate the correlation coefficient λ and the like.

The central control unit 130 calculates a correlation coefficient λ based on the power factor, and calculates the correlation coefficient λ based on the load groups G ₁ to G ₆ measured by the first watt hour meters 111 to 116 It is corrected by applying to each power consumption.

Specifically, the correlation coefficient λ may be calculated through Equation 1 below.

Here, D is the error between the sum of the total power consumption calculated by the second watt hour meter 120 and the total amount of power consumption for each load group (G ₁ to G ₆ ) measured by the first watt hour meter 111 to 116, G _k is the amount of power consumption of the load group (in the case of the example shown in Figs. 2 and 3, n is a value of 1 to 6), l is the number of the load group (in the case of the example shown in Figs. 2 and 3, l value is 6).

That is, the error between the total amount of power consumption calculated by the second watt hour meter 120 and the sum of the total amount of power consumption for each load group (G ₁ to G ₆ ) measured through the first watt hour meter 111 to 116 By distributing and correcting according to a ratio based on the amount of power consumption and the power factor, it is possible to improve the accuracy in calculating the amount of power consumption distributed and supplied to load groups having different characteristics, that is, different power factor, unlike in the related art.

And, among the factors used to calculate the correlation coefficient λ, the amount of power consumption of the load group measured by the first watt hour meter 111 to 116 and the second watt hour meter 120 and corrected by the correlation coefficient λ is the watt hour meter. It is generally the amount of active power (kWh) displayed in.

The corrected power consumption amount for each load group (G ₁ to G ₆ ) may be calculated through Equation 2 below using the correlation coefficient λ calculated as described above.

Here, G _n is the power consumption of the load group, and G _n ′ is the corrected power consumption.

As described above, the facility control system 100 according to the present invention corrects the amount of power consumption measured for the group loads G ₁ to G ₆ through at least one first watt hour meter 111 to 116, thereby Regardless of the type of load, the sum of the corrected power consumption for each load group (G ₁ to G ₆ ) becomes the same as the sum of the total power consumption measured through the second power amount 120, and thus, is introduced into the building. It is possible to improve the accuracy of calculating the amount of power consumption distributed by load groups G ₁ to G ₆ .

According to an embodiment of the present invention, the central control device 130 includes a communication unit (not shown) to communicate with the first watt hour meter 111 to 116 and/or the second watt hour meter 120 as described above. It is desirable to do it.

At this time, the communication unit of the central control device 130 may be built-in or external, and the first watt hour meter 111 to 116 and/or the second watt hour meter 120 and RS-232, RS-485, USB (Universal Serial Bus) , IEEE 1394, Thunderbolt, etc. are connected through a wired communication method to transmit and receive data. However, when the number of the first power meters 111 to 116 increases, it is preferable to connect and transmit data through a wireless communication method to facilitate installation.

Accordingly, the central control unit 130 includes the first watt-hour meters 111 to 116 and/or the second watt-hour meters 120 and the WLAN (Wireless LAN), Wibro (Wireless broadband), WIMAX (World Interoperability for Microwave Access), HSDPA ( High Speed Downlink Packet Access) can be used to communicate.

Second Example

Meanwhile, the central control device 130 compares the corrected power consumption for each load group (G ₁ to G ₆ ) with a reference power amount, and outputs an alarm signal according to the comparison difference, or at least one facility 200 or device A control command may be transmitted to at least one facility or equipment belonging to the load group directly or through the facility control devices 131a and 131b to 300 (see FIG. 4).

At this time, so that the power consumption _per load group (G ₁ ~ G ₆ ) does not exceed the target standard power amount, the central control device 130 directly or through the facility control devices 131a, 131b, the facility 200 or the equipment The operation of the 300 may be controlled (for example, when the load is an air conditioner, a set temperature is lowered, an operation mode is changed from a cooling/heating mode to a blasting mode, a cooling/heating operation time is lowered, etc.). In this case, the reference power amount may be set according to a user input, or may be preferably scheduled to be dynamically set for each time slot or for each season.

Therefore, by controlling the operation of the facility 200 or the equipment 300 based on the corrected power consumption for each load group (G ₁ to G ₆ ), the central control device 130 according to the present invention prevents incorrect measurement of the power consumption. By preventing the corresponding control, it is possible to increase the satisfaction level by maintaining the user's maximum comfort when controlling the load of the air conditioner.

In addition, as described above, the central control device 130 according to the present embodiment transmits an alarm signal to a display means or a speaker according to the comparison result, and the amount of power used by the load groups G ₁ to G ₆ You can warn the user that is exceeded. At this time, the central control device 130 may control the facility 200 or the equipment 300 separately or simultaneously with the warning.

4 is a diagram illustrating a configuration in which a central control device is connected to facilities or equipment according to an embodiment of the present invention.

The central control device 130 according to the present embodiment can comprehensively control and/or monitor the situation of the entire building, and the facilities 200, for example, machine facilities, lighting, power, access control, disaster prevention , Parking management, facility management, etc. may be provided with separate terminals for controlling and/or monitoring.

According to the present embodiment, the central control device 130 registers at least one facility 200 or equipment 300 and one or more control points for the facility 200 or equipment 300, and The facility can be controlled using the control point.

The central control device 130 includes a control program for operating the facility 200 or the equipment 300 through the control point, and the facilities 200 or equipment 300 using the control program Can be controlled and/or monitored.

For example, when the facility 200 is an air conditioner, the central control device 130 outputs conditions such as whether an outdoor unit or an indoor unit is operated, a driving mode, temperature, humidity, wind speed, wind direction, etc. through a display unit, or input by a user. A control command may be transmitted to the outdoor unit or indoor unit so that the outdoor unit or the indoor unit is controlled by.

The central control device 130 includes at least one station (or “virtual server”) generated by registering at least a part of the control point, and each station is registered according to a control command input through a user input. It can be configured to control the facilities for some of the control points. As an example, the central control device 130 is a device that comprehensively controls and/or monitors the situation of the entire building, and the facilities 200, for example, machine facilities, lighting, power, access control, disaster prevention, Separate terminals for parking management and facility management can be provided.

In addition, the central control device 130 shares information with each other through network communication with the facility control devices 131a and 131b, and controls the facility 200 or the equipment 300 included therein through a control point. It may be an automation server that controls or monitors.

The facility control devices 131a and 131b may be positioned between the central control device 130 and the at least one facility 200 and may execute a control program received from the central control device 130.

The facility control devices 131a and 131b may be a direct controller (DDC; Direct Digital Controller or PLC; Programmable Logic Controller) that controls the facilities 200.

In addition, the facility control device (131a, 131b) communicates with the central control device (130) to exchange information, and receives and executes the control program or a control command according to the control program. Alternatively, the equipment 300 can be controlled.

In addition, the facility control device (131a, 131b), through one or more equipment (300) provided in the facility (200), for example, control output of the facilities in the building through a control point set in each sensor and operation devices And equipment-related information such as state change, etc. can be recorded or stored.

The facility control devices 131a and 131b may be, for example, a microcomputer that controls or monitors the facility 200 or the equipment 300 according to the control program. In other words, the facility control devices 131a and 131b are connected to the central control device 130 through a communication network, transmit and receive necessary information to each other, and accordingly, control points for air conditioning and other facilities installed in the building. They are monitored or controlled, and input/output signals of the equipment 200 or 300 may be directly controlled by using a function built in each of the control points.

Specifically, the facility control devices 131a and 131b are connected between the central control device 130 and the one or more facilities 200 to receive a control program or a control command according to the control program, and execute it. have.

Further, the facility control devices 131a and 131b may transmit the execution result to the central control device 130. To this end, the central control device 130 transmits the control program or a control command according to the control program to the facility control devices 131a and 131b, and the control program from the facility control devices 131a and 131b. Alternatively, a communication unit may be provided as a means for receiving an execution result according to a control command according to the control program.

Facility control method

5A is a step-by-step flowchart of a facility control method according to an embodiment of the present invention.

As shown in FIG. 5A, in the facility control method according to an embodiment of the present invention, the step of measuring, by a first watt hour meter, the amount of power consumed for each load group (S110), the central control device or the first watt hour meter Calculating a power factor from power consumption (S120), calculating a correlation coefficient based on the power factor by the central control device (S130), and calculating the correlation coefficient to the measured power consumption for each load group Applying and calculating the corrected power consumption for each load group (S140).

In addition, FIG. 5B is a step-by-step flowchart of a facility control method according to another embodiment of the present invention.

As shown in Fig. 5B, the step of measuring the total amount of power consumption consumed by the at least one load group by the second watt-hour meter (S101), wherein the central control device receives the measured amount of power consumption from the first and second watt-hour meters. Step (S111), the central control device comparing the corrected consumption strategy amount for each load group with the reference power amount (S150) and outputting an alarm signal or controlling the operation of at least one load according to the comparison difference ( S160) may be further included.

Since some of the steps of FIG. 5B are duplicated with each of the steps of FIG. 5A, in order to omit the redundant description, each step will be described below with reference to FIG. 5B. I will omit it.

First, the first watt-hour meters 111 to 116 measure the amount of electricity used for a predetermined time by each load group by distributing the power introduced to the building by load group (S110), and the second watt-hour meter 120 is at least one The total amount of power consumed by the entire load group (G ₁ ~ G ₆ ) is measured (S101).

5B shows that step S110 is a step after step S101, but it is not intended to limit the order, and step S101 may be performed after step S110.

As described above, the first watt-hour meters 111 to 116 measure the consumption of the supplied power by being distributed to each load group G ₁ to G ₆ through the second watt-hour meter 120.

In addition, the second watt hour meter 120 is connected to the power lead line so that the power supplied from the power company is introduced into the building, and the power supplied from the power lead line is distributed and supplied by group loads (G ₁ ~ G ₆ ). However, measure the amount of power consumed by the entire load group (G ₁ ~ G ₆ ).

The central control device 130 according to an embodiment of the present invention may include a communication unit (not shown) and communicate with the first watt hour meters 111 to 116 and/or the second watt hour meter 120 (S111).

At this time, the communication unit of the central control device 130 may be built-in or external, and the first watt hour meter 111 to 116 and/or the second watt hour meter 120 and RS-232, RS-485, USB (Universal Serial Bus) , IEEE 1394, Thunderbolt, etc. are connected through a wired communication method to transmit and receive data. However, when the number of the first power meters 111 to 116 increases, it is preferable to connect and transmit data through a wireless communication method to facilitate installation.

Accordingly, the central control unit 130 includes the first watt-hour meters 111 to 116 and/or the second watt-hour meters 120 and the WLAN (Wireless LAN), Wibro (Wireless broadband), WIMAX (World Interoperability for Microwave Access), HSDPA ( High Speed Downlink Packet Access) can be used to communicate.

In addition, the central control device 130 is connected to enable communication with the first watt hour meter 110, and receives the power factor calculated by the first watt hour meter 111 to 116, or is effective from the first watt hour meter 111 to 116. The power factor may be directly calculated by receiving the power and reactive power (or apparent power) (S120).

A method of calculating the power factor from active power and reactive power (or apparent power) may be calculated by various known methods, and detailed descriptions thereof will be omitted.

In addition, the central control device 130 calculates a correlation coefficient λ based on the power factor (S130).

Specifically, the correlation coefficient λ may be calculated through Equation 1 above.

That is, the error between the total amount of power consumption calculated by the second watt hour meter 120 and the sum of the total amount of power consumption for each load group (G ₁ to G ₆ ) measured through the first watt hour meter 111 to 116 By distributing and correcting according to a ratio based on the amount of power consumption and the power factor, it is possible to improve the accuracy of calculating the amount of power consumption that has been distributed and supplied to load groups having different characteristics, that is, different power factor, unlike the conventional one.

In addition, the central control apparatus 130 corrects by applying the correlation coefficient λ to the power consumption for each load group G ₁ to G ₆ measured by the first watt hour meters 111 to 116 (S140).

Accordingly, the corrected amount of power consumption for each load group (G ₁ to G ₆ ) may be calculated through Equation 2, using the correlation coefficient λ calculated as described above.

As described above, the facility control system 100 according to the present invention corrects the amount of power consumption measured for the group loads G ₁ to G ₆ through at least one first watt hour meter 111 to 116, so that the load between the load groups Regardless of the type of, the sum of the corrected power consumption for each load group (G ₁ to G ₆ ) becomes the same as the sum of the total power consumption measured through the second power amount 120, and thus, the load entering the building It is possible to improve the accuracy of calculating the amount of power consumption distributed by groups G ₁ to G ₆ .

Meanwhile, the central control device 130 may compare the corrected amount of power consumption for each of the load groups G ₁ to G ₆ with a reference amount of power (S150).

Accordingly, the central control device 130 outputs an alarm signal according to the comparison difference, or directly to the at least one facility 200 or device 300 or through the facility control devices 131a and 131b, the load group A control command may be transmitted to at least one facility or equipment belonging to (S160).

That is, when the amount of power consumption for each load group (G ₁ to G ₆ ) exceeds the target standard amount of power, the central control device 130 determines the amount of power consumption for each load group (G ₁ to G ₆ ). In order not to exceed, control the operation of the facility 200 or the equipment 300 directly or through the facility control devices 131a, 131b (for example, when the load is an air conditioner, the set temperature decreases, and the operation mode is blown in the cooling/heating mode. Mode can be changed, cooling and heating operation time can be lowered.

Therefore, by controlling the operation of the facility 200 or the equipment 300 based on the corrected power consumption for each load group (G ₁ to G ₆ ), the central control device 130 according to the present invention prevents incorrect measurement of the power consumption. By preventing the corresponding control, it is possible to increase the satisfaction level by maintaining the user's maximum comfort when controlling the load of the air conditioner.

In addition, as described above, the central control device 130 according to the present embodiment transmits an alarm signal to a display means or a speaker according to the comparison result, and the amount of power used by the load groups G ₁ to G ₆ It is possible to warn the user that it exceeds the warning, and control the facility 200 or the equipment 300 separately or simultaneously with the warning.

Computer-readable recording medium

The facility control method according to an embodiment of the present invention described above may be implemented in the form of program commands that can be executed through various computer components and recorded in a computer-readable recording medium. The computer-readable recording medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the computer-readable recording medium may be specially designed and configured for the present invention, or may be known and usable to those skilled in the computer software field. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical recording media such as CD-ROMs and DVDs, and magneto-optical media such as floptical disks. optical media), and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of the program instructions include not only machine language codes such as those produced by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware device may be configured to operate as one or more software modules to perform the processing according to the present invention, and vice versa.

The preferred embodiments of the present invention described above are disclosed to solve the technical problem, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications, changes, additions, etc. within the spirit and scope of the present invention. , Such modifications and changes should be viewed as falling within the scope of the following claims.

10, 100: facility control system 11a, 11b, 111~116: first power meter
12, 120: second power meter 13a, 13b: outdoor unit
14a, 14b: indoor unit 15, 130: central control unit
131a, 131b: facility control device 200: facility
300: equipment

Claims (22)

A first watt hour meter that measures the amount of power consumed by load group for at least one facility or equipment;
A second watt-hour meter measuring a total amount of power consumption consumed by at least one load group; And
A central control unit for calculating a correlation coefficient based on the power factor calculated through the power consumption for each load group, and calculating a corrected power consumption for each load group by applying the correlation coefficient to the power consumption for each load group;
Including,
The correlation coefficient is,
The error between the total amount of power consumption measured by the second watt-hour meter and the sum of the amount of power consumed by each load group measured through the first watt-hour meter, the amount of power consumed by the load group, and the number of the load groups are calculated. Characterized by
Facility control system. delete The method of claim 1,
The total amount of power consumption measured by the second power meter is,
Regardless of the type of the load between the load groups, the facility control system is the same as the sum of the corrected power consumption for each load group. The method of claim 1,
The correlation coefficient is calculated by the following equation,

Here, λ is a correlation coefficient, D is an error between the sum of the total power consumption measured by the second watt hour meter and the power consumption for each load group measured by the first watt hour meter, and G _k is the consumption of the load group. The facility control system, wherein the amount of power, l is the number of the load groups. The method of claim 4,
The corrected power consumption for each load group is,

Facility control system, characterized in that calculated by the above equation. The method of claim 1,
The central control device,
A communication unit for transmitting and receiving data to and from the first watt-hour meter or the second watt-hour meter through wireless communication;
Facility control system comprising a. The method of claim 1,
The central control device,
A facility control system comprising transmitting a control command to at least one facility or equipment belonging to the load group directly or through a facility control device. The method of claim 7,
The central control device,
And comparing the corrected power consumption for each load group with a reference power amount, and controlling the operation of the at least one facility or equipment according to the comparison difference. A correlation coefficient is calculated based on the power factor calculated from the power consumption of each load group for at least one facility or equipment measured by the first watt-hour meter, and correction for each load group by applying the correlation coefficient to the power consumption of each load group Calculate the consumed power consumption,
The correlation coefficient is calculated based on an error between the total amount of power consumption measured by a second watt-hour meter and the sum of the amount of power consumption for each load group measured through the first watt-hour meter, the amount of power consumed by the load group, and the number of load groups. A central control device for equipment, characterized in that calculating. The method of claim 9,
The correlation coefficient is calculated by the following equation,

Here, λ is a correlation coefficient, D is an error between the sum of the total amount of power consumed by the at least one load group measured through the second watt-hour meter and the sum of the amount of power consumed by the load group measured through the first watt-hour meter, G _k is the power consumption of the load group, and l is the number of the load groups. The method of claim 10,
The corrected power consumption for each load group is,

The central control device of the facility, characterized in that calculated by the above equation. The method of claim 9,
The central control device,
A communication unit for transmitting and receiving data to and from the first watt-hour meter or the second watt-hour meter through wireless communication;
Central control device of the facility, characterized in that it comprises a. The method of claim 9,
The central control device,
And comparing the corrected amount of power consumption for each load group with a reference amount of power, outputting an alarm signal according to the comparison difference, or controlling the operation of the at least one load. Measuring an amount of power consumption for each load group for at least one facility or equipment;
Calculating a power factor from the power consumption for each load group;
Calculating a correlation coefficient based on the power factor; And
Calculating a corrected power consumption for each load group by applying the correlation coefficient to the measured power consumption for each load group;
Including,
Measuring a total amount of power consumption consumed by at least one load group;
Including more,
The step of calculating the correlation coefficient,
The correlation coefficient is calculated based on an error between the sum of the total power consumption measured through a second watt-hour meter and the sum of the power consumption for each load group measured through a first watt-hour meter, the power consumption of the load group, and the number of load groups. Equipment control method characterized in that to calculate. delete The method of claim 14,
The measured total power consumption is,
Regardless of the type of load between the load groups, the facility control method is the same as the sum of the corrected power consumption for each load group. The method of claim 14,
The correlation coefficient is calculated by the following equation,

Where λ is a correlation coefficient, D is an error between the sum of the total power consumption and the power consumption for each load group, G _k is the power consumption of the load group, and l is the number of the load groups. . The method of claim 17,
The corrected power consumption for each load group is,

Facility control method, characterized in that calculated by the above equation. The method of claim 16,
Receiving the power consumption for each load group or the total power consumption through wireless communication;
Facility control method further comprising a. The method of claim 14,
Transmitting a control command to at least one facility or equipment belonging to the load group directly or through a facility control device;
Facility control method further comprising a. The method of claim 20,
Comparing the corrected amount of power consumption for each load group with a reference amount of power; And
Controlling the operation of the at least one facility or equipment according to the comparison difference;
Facility control method further comprising a. 22. A computer-readable recording medium storing a computer program for executing the facility control method according to any one of claims 14 and 16 to 21.

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