KR101368456B1 - Demand Controller of an electric system - Google Patents

Abstract

The demand control device of the electric machine system of the present invention sets demands based on power consumption of each air conditioner to perform demand control. Therefore, it is possible to quickly create the air conditioning environment desired by the user within the range that the comfort of the user is not impaired.

Demand control, predicted power, power meter, power divider

Description

[0001] The present invention relates to a demand control device for an electric equipment system,

The present invention relates to a demand control device for an electric machine system, and more particularly, to a demand control device for an electric machine system for performing demand control by setting priority based on power consumption of each air conditioner.

Generally, a demand control device of an electric equipment system is designed to control the operation rate of the multi-type air conditioner within the allowable electric power amount, in order to control the operation rate of the multi-type air conditioner, And controlling power by turning the device on or off.

Such a demand control system focuses on power control rather than the convenience of the user, and proceeds in a manner of suppressing power consumption by sequentially turning off the power consumption load.

However, the demand control device of the conventional electric machine system is controlled in such a way that the air conditioner is sequentially selected to cut off or input the power regardless of the user's convenience. There is a problem in that the comfort that the user actually feels.

SUMMARY OF THE INVENTION An object of the present invention is to provide a demand control apparatus for an electric machine system that performs demand control by setting priorities based on power consumption of each air conditioner.

The demand control device of the electric machine system of the present invention comprises: electric devices including a plurality of air conditioners including at least one indoor unit and an outdoor unit supplying a refrigerant to the indoor unit, and detecting an estimated amount of power of the electric devices. And a demand controller for controlling an operation state of the electric devices when the predicted power amount sensing unit and the predicted power amount detected by the predicted power amount sensing unit exceed a set power amount, wherein the demand control unit corresponds to the power consumption of each indoor unit. On the basis of this, priority is set for the plurality of indoor units, and the air conditioners are controlled based on the priority. The power divider may further include a power divider configured to calculate and display the power consumption of each indoor unit based on indoor unit information of each indoor unit, and the power consumption of each air conditioner is the consumption of each indoor unit calculated by the power divider. It may be a power amount.

In the present invention, further comprising a demand database for storing the power consumption of each indoor unit calculated by the power divider, the demand control unit based on the power consumption of each indoor unit stored in the demand database, the amount of power consumption Low priority can be set for small indoor units.

In the present invention, the demand database further includes a demand database for storing a rate of change of the power consumption of each indoor unit calculated by the power divider, wherein the demand control unit is a change rate of a predetermined time of the power consumption of each indoor unit stored in the demand database On the basis of this, it is possible to set a low priority of the indoor unit having a small rate of change of the amount of power consumption per predetermined time. At this time, when it is determined that the estimated power amount exceeds the set power amount, the demand control unit first reduces the operation rate of the indoor unit having a low priority.

According to another aspect of the present invention, there is provided a demand control apparatus for an electrical system, the electrical apparatus including a plurality of air conditioners including at least one indoor unit and an outdoor unit supplying a refrigerant to the indoor unit, and the amount of predicted power of the electrical apparatuses. And a demand controller configured to control an operation state of the electric devices when the estimated power amount detected by the predicted power amount detector is greater than a set power amount, wherein the demand controller includes a plurality of indoor units. Each of the groups may be divided into groups, and the priorities may be set based on the power consumption of each group, and the respective groups may be controlled based on the priorities.

In the demand control device of the electric machine system according to the present invention, by setting the priority based on the power consumption of each air conditioner to perform the demand control, the user's desired air conditioning environment within the range that the user's comfort is not impaired It can be quickly formed.

1 is a block diagram showing the configuration of an electrical equipment system 190 including a demand control device 100 according to an embodiment of the present invention. FIG. 2 is a block diagram showing the configuration of the air conditioner 141 shown in FIG.

Referring to FIG. 1, an electrical equipment system 190 includes air conditioners 141, ventilators 142, and lighting devices 143.

The electrical equipment system 190 includes a first local control device 161 for controlling the air conditioning devices 141, a second local control device 162 for controlling the ventilation devices 142, and a lighting device 143 And a third local control unit 163 for controlling the second local control unit 163. However, the first local control device 161 may control at least some of the air conditioners 140 as well as at least some of the ventilation devices 142, the lighting devices 143. That is, the first, second, and third local control devices 141, 142, and 143 may control electrical devices of different types. The demand control device 100 and the first, second and third local control devices 161, 162, and 163 are connected to a network 164.

2, the plurality of air conditioners 141 include a plurality of indoor units 141b and at least one outdoor unit 141a for controlling the indoor units 141b. The indoor units 141b may each include an indoor temperature detector 141c that detects an indoor temperature. The indoor units 141b are disposed in the indoor spaces, respectively, and the outdoor units 141a are disposed in the outdoor spaces. However, the configuration of the air conditioner 141 is not limited to the above.

Referring to FIG. 1, the demand control apparatus 100 may include a predicted power amount detector 170, a demand controller 110, an input unit 120, a demand database 130, and a display unit 150. The input unit 120 receives a user's operation signal and includes a plurality of input keys (not shown). However, the input unit 120 may have a touch panel method.

The demand database 130 stores a plurality of demand control methods. Demand control methods are methods for demand control of the electrical equipment system 190 based on the method of charging the electric power charges according to the countries. The demand control unit 110 performs demand control of the first, second, and third local control devices 161, 162, and 163 according to the demand control method selected from the demand database 130. Therefore, the demanded control device 100 can control the air conditioners 141, the ventilation devices 142, and the lighting devices 143 in a demand-controlled manner.

The display unit 150 displays image data. The display unit 150 may be a user interface (UI) screen, and may be a GUI (Graphic User Interface) screen to improve user's operational convenience.

The predicted power amount sensing unit 170 is connected to a watt-hour meter 171 connected to a plurality of electric devices, receives data on the measured amount of electric power for a predetermined time from the watt-hour meter 171, estimates the amount of electric power after a predetermined time, Detects whether the amount of power exceeds a predetermined amount of demanded power, and transmits the sensed information to the demand control unit 110. The demand controller 110 is connected to each of the outdoor unit 141a and the indoor unit 141b of the predicted power amount sensing unit 170 and the air conditioner 141, and the outdoor unit 141a when the predicted power amount exceeds the set power amount. And controlling the operation of the indoor unit 141b.

As an example of a demand control method according to a country, a demand control method in a Japanese country is as follows. In Japan, the total electricity use for one month is measured in units of 30 minutes, and the maximum value is set as the maximum electricity consumption for the month, and the maximum value of electricity consumption for any 30 minutes in the previous year including the month is set to 1 Year contract electricity usage. That is, the electric power charge for this year is a value obtained by multiplying the contract electricity consumption by the unit price. And, when the user consumes more power than the contract electricity consumption amount, it imposes a surcharge. Therefore, if the amount of electric power used increases during a specific 30-minute period of the previous year, there is a problem that the electric power consumption of the year is unnecessarily increased. From the above, the demand control method in Japan is to limit the total electricity usage for 30 minutes to less than the set electric power amount in order to limit the monthly electric power charge price for next year. The specific method of limiting the total electricity usage for 30 minutes to less than the set electric power can be variously selected. The demand control device 100 can reduce the electricity consumption by stopping the operation of some of the air conditioners 141 or by raising the set temperature of the indoor units to be air-cooled. Japanese Patent Application Laid-Open Nos. 2000-131688 and 2000-182920 disclose specific control methods. The method of calculating the electric power charge of the Republic of Korea is similar to the method of calculating the electric power charge of the Japanese government, and the above-mentioned demand control method of Japan can be similarly applied to the Republic of Korea.

In a country that limits the total amount of electricity used during the year, the demand control device 100 uses a demand control method for restricting the total amount of electricity used during the year to be less than or equal to the set power amount. In addition, in a country in which a power fee is premium only in a specific month, the demand control apparatus 100 uses a demand control method of limiting the amount of electricity used to the specific power amount or less only in the specific month.

On the other hand, the demand control unit 110 sets the priority to the plurality of indoor units (141b) based on the power consumption of each indoor unit (141b), and controls the air conditioning (value 141) based on the priority. Here, in order to calculate the power consumption of each indoor unit 141b, a power meter is installed for each indoor unit 141b to transmit the power consumption of each indoor unit 141b to the demand control device 100 to thereby execute the demand control unit 110. ) Can be detected. However, it is not only cumbersome to install an electricity meter for each indoor unit 141b, but also has disadvantages in cost. Therefore, in the present invention, the power consumption of each indoor unit 141b is calculated through the power consumption of each indoor unit 141b calculated through the power divider 180. Specifically, referring to FIG. 1, the demand control device 100 of the present invention controls each outdoor unit 141a to calculate power consumption of each indoor unit 141b according to indoor unit information of each indoor unit 141b. The power divider 180 further displays an amount of power consumption. As shown in FIG. 1, the power divider 180 may be installed to be connected with all outdoor units through a common communication line 181 commonly connected to all outdoor units. However, the power divider 180 may be installed in the same number as the number of the outdoor units 141a to be connected to each outdoor unit 141a and allocated to each outdoor unit 141a.

The power divider 180 is connected to the electricity meter 171 and the pulse data communication method (PDL), and the electricity meter 171 measures the accumulated power consumption supplied to the outdoor unit 141a and transmits the data to the power divider 180. Send it.

The power divider 180 displays information on the current power consumption of each indoor unit 141b based on the indoor unit information of each indoor unit 141b, and transmits it to the demand control unit 110 based on the accumulated power consumption. Adjust the power distributed to 141a. Here, the indoor unit information includes information on the capacity and operation state of each indoor unit (141b), the power divider 180 calculates the power consumption of each indoor unit from the indoor unit information. Specifically, the power divider 180 adds the presence or absence of the operation of the indoor unit 141b, the opening amount of the electronic expansion valve, the air flow rate, and the like in the indoor unit information of each indoor unit 141b at a predetermined ratio. Calculate power consumption proportional to the capacity of. The operation of the indoor unit 141b, the opening amount of the electronic expansion valve, the air flow rate, and the like may be varied for optimization. Even if the ratio is variable, the power consumption of each indoor unit 141b is set to be proportional to the capacity of each indoor unit 141b. The power divider 180 may calculate instantaneous power, monthly power, cumulative power, and the like based on the amount of power consumed. The power divider 180 may measure and display the amount of power accumulated in a predetermined time, and when the amount of power accumulated in the predetermined time is initialized, the amount of power consumed since the initialization time may be accumulated and displayed.

The power consumption of each indoor unit 141b calculated by the power distributor 180 is stored in the demand database 130 through the communication module 112. The demand control unit 110 sets a low priority of the indoor unit having a small amount of power consumption based on the power consumption of each indoor unit stored in the demand database 130.

FIG. 3 is a block diagram illustrating an internal configuration of a demand controller of the demand controller 100 shown in FIG. 1. Referring to FIG. 3, the demand control unit 110 may include a priority setting unit 111 for setting priorities of the plurality of air conditioners 141 and a communication module for performing data communication with the power distributor 180. 112 and an operation control unit 113 for controlling the operation of the air conditioner (141).

When it is determined that the amount of predicted power exceeds the set power amount, the operation controller 113 performs control to decrease the operation rate of each indoor unit 141b based on the priority of each indoor unit 141b. Here, the operation rate means a rate at which one indoor unit exhibits its capability within its own capacity, and the case where a maximum capacity is demonstrated can be defined as 100%.

The communication module 112 performs data communication with the power splitter 180 and transmits information on the current power consumption of each indoor unit 141b transmitted from the power splitter 180 to the demand database 130.

The priority setting unit 111 may set a priority to each of the plurality of air conditioners 141 by inputting a user's operation signal through the input unit 120 or automatically. However, since the indoor operating environments are different for each area in which the indoor units 141b of the air conditioners 141 are installed, it is preferable to set the priority order based on the operating environments. The priority setting unit 111 sets the priority based on the power consumption of each indoor unit 141b. Among the indicators showing various operating environments in the area where the indoor units 141b are installed, the power consumption of each indoor unit 141b refers to the load of each air conditioner 141, and the priority may be set based on the load. have. The priority setting unit 111 sets a low priority to the indoor unit 141b having a small amount of power consumption based on the power consumption of each indoor unit 141b stored in the demand database 130. In detail, when the power consumption of each indoor unit 141b is large, it is determined that the load of the indoor unit 141b is large, and when the demand control is large, when the demand control is performed, the priority is set to high so that the demand control of the indoor unit 141b is performed. Set to subordinate at target. Since the current comfort level is low in an area where the indoor unit 141b is heavily loaded, when the indoor unit 141b of the area is turned off (0ff) or the operation rate is lowered during demand control, the comfort of the area is further lowered. This is because complaints about user comfort will rise. On the other hand, since the current degree of comfort is high in the area where the load of the indoor unit 141b is small, even if the indoor unit 141b in the area is demand-controlled to turn off the indoor unit 141b (0ff) The dissatisfaction with the comfort of the user in the area will not be great. Accordingly, when it is determined that the predicted power amount exceeds the set power amount, the operation control unit 113 first decreases the operation rate from the indoor unit 141b having a lower priority.

Meanwhile, the priority setting unit 111 may set the priority based on the rate of change of the power consumption of each indoor unit 141b per predetermined time. That is, among the indicators showing various operating environments in the area where each indoor unit 141b is installed, the rate of change of the power consumption of each indoor unit 141b per predetermined time may mean a load of each indoor unit 141b, Is to set priorities. Specifically, the demand database 130 stores the rate of change of the power consumption of each indoor unit 141b calculated by the power distributor 180 per hour. The priority setting unit 111 sets a low priority to the indoor unit 141b having a small rate of change per predetermined time based on the rate of change of power consumption of each indoor unit 141b stored in the demand database 130. For example, when the rate of change of the power consumption of the indoor unit 141b per predetermined time is large, it is determined that the load of the indoor unit 141b is large, and when the demand control is performed when the load is large, a higher priority is given. It can also be set as a priority in the target of demand control.

FIG. 4 is a flowchart illustrating a process of the demand control apparatus 100 shown in FIG. 1 performing demand control based on a priority. Referring to FIG. 4, first, the predicted power amount sensing unit 170 receives data about a power amount measured for a predetermined time from the electricity meter 171, and predicts the power amount after a predetermined time (S100). It is determined whether the demand power amount is exceeded (S200). When it is determined that the estimated power amount exceeds the set power amount, the power divider 180 calculates the power consumption of each indoor unit 141b and transmits it to the demand database 130, and the demand database 130 from the power divider 180. The amount of power consumption of each indoor unit 141b received is stored (step S300). Here, the power consumption of each indoor unit 141b means the load of each indoor unit 141b. The priority setting unit 111 sets a low priority to the indoor unit 141b having a small amount of power consumption based on the power consumption of each indoor unit 141b which is a load of each indoor unit 141b (step S400). For example, when the power consumption of each indoor unit 141b is large, it is determined that the load of the indoor unit 141b is large, and when the demand control is large, when the demand control is performed, the priority is set to a high demand control. Set the subordinated priority on the target. On the other hand, since the current comfort level is high in a region where the load of the indoor unit 141b is small, even when the indoor unit 141b of the region is demand-controlled to turn off the indoor unit 141b (0ff) or lower the driving ratio, Dissatisfaction with the user's comfort in the area will not be so large, so set the priority lower. If the priority is set, the operation controller 113 first suppresses the operation rate from the indoor unit 141b having a low priority (step S500).

5 is a block diagram showing the configuration of an air conditioner 141 according to another embodiment of the present invention. Referring to FIG. 5, each air conditioner 141 may include at least one outdoor unit 141a for controlling the indoor units 141b. The demand controller 110 may divide the indoor units 141b into a plurality of groups G1, G2, and G3. In FIG. 5, the indoor units 141b connected to the same outdoor unit 141a are grouped into the same group. However, the indoor units 141b connected to the different outdoor units 141a may be combined to set the same group. The user divides the plurality of indoor units 141b into the plurality of groups G1, G2, and G3 through the input unit 120 so as to divide the plurality of indoor units 141b into the plurality of groups G1, G2, and G3 as needed. Inputting an operation signal to be divided into two, and the demand controller 110 divides the plurality of indoor units 141b into a plurality of groups G1, G2, and G3 based on the operation signal.

The demand control unit 110 sets priorities to the groups G1, G2, and G3 based on power consumption of the groups G1, G2, and G3, and based on the priorities, each group G1, G2, G3) can be controlled. In detail, the priority setting unit 111 sets priorities to the groups G1, G2, and G3 based on the power consumption amounts of the groups G1, G2, and G3. Here, the power consumption of each group G1, G2, and G3 may be defined as the sum of the power consumption of the indoor unit 141b belonging to each group G1, G2, and G3. The demand database 130 stores the sum of power consumption of the indoor units 141b belonging to each group G1, G2, and G3, and the demand control unit 110 includes the indoor units 141b belonging to each group G1, G2, and G3. Set a low priority to a group having a small sum of power consumptions and a high priority to a group having a large sum of power consumptions.

As described above, since the power consumption of each indoor unit 141b refers to the load of each indoor unit 141b, the sum of the power consumption of the indoor units 141b belonging to each group G1, G2, and G3 is equal to each group G1. , G2, G3) may mean a load. Therefore, the power consumption of each indoor unit 141b is calculated, and the power consumption is integrated for each group G1, G2, and G3. The group with the largest integrated value is determined to be the group with the highest load, and the highest priority is set. Here, priority may also be set to the indoor units 141b belonging to each of the groups G1, G2, and G3, and the priority may be set based on the power consumption of each indoor unit 141b as described above. Can be set. Here, the load of each group G1, G2, G3 is not limited to the sum of power consumption of the indoor unit 141b belonging to each group G1, G2, G3, but belongs to each group G1, G2, G3. The sum of power consumption of the indoor unit 141b may be set in various ways such as a change rate per predetermined time.

When the priority is set, the demand control unit 110 based on the priority of each group G1, G2, G3 and the priority of each indoor unit 141b belonging to each group G1, G2, G3, each group Each indoor unit 141b belonging to (G1, G2, G3) and each group (G1, G2, G3) is controlled. In detail, when it is determined that the estimated power amount exceeds the set power amount, the operation controller 113 controls the plurality of groups G1, G2, and G3 based on the priority of each group G1, G2, and G3. . In this case, the operation rate of the indoor unit 141b belonging to the low priority group G1, G2, G3 is first reduced. That is, if a group to be demanded is determined by priority, demand control is performed from the group to be demand control, and the priority is set for each indoor unit 141b belonging to the group to be demand control. Reflecting the control of each indoor unit (141b). Even in this case, the operation rate of the indoor unit 141b having the lower priority among the indoor units 141b belonging to each of the groups G1, G2, and G3 is first reduced as described above.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

The present invention can quickly create an air conditioning environment desired by a user within a range in which the comfort of the user is not impaired, and can be used in a demand control device of an electric equipment system.

1 is a block diagram showing a configuration of an electrical equipment system including a demand control device according to an embodiment of the present invention.

2 is a block diagram showing the configuration of the air conditioner shown in FIG.

FIG. 3 is a block diagram illustrating an internal configuration of a demand controller of the demand controller shown in FIG. 1.

FIG. 4 is a flowchart illustrating a process in which the demand control apparatus illustrated in FIG. 1 performs demand control based on priority.

5 is a block diagram showing the configuration of an air conditioner according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

100: Demand controller 110: Demand controller

111: priority setting unit 112: control level setting unit

113: Operation control section 120: Input section

130: demand database 141: air conditioner

141a: outdoor unit 141b: indoor unit

141c: indoor temperature detection unit 142: ventilation device

143: illuminating device 150:

161, 162, 163: first, second and third local control devices

164: network 170: predicted power amount sensing unit

171: power meter 180: power divider

190: electrical system

Claims (12)

Electrical devices including a plurality of air conditioners including a plurality of indoor units and an outdoor unit for supplying refrigerant to the indoor units; A predicted power amount sensing unit which receives data on the amount of power measured for a predetermined time from the electrical devices and detects the estimated power amount of the electrical devices; And a demand controller for controlling an operation state of the electric devices when the predicted electric energy amount detected by the predicted electric energy quantity sensing unit exceeds a set electric energy, The demand control unit of the electric machine system to determine the load of each indoor unit, to set a low priority to the indoor unit with a small load, and to control the air conditioners by adjusting the operation rate of the indoor unit having a lower priority first Demand Control. The method according to claim 1, And a power divider configured to calculate and display the amount of power consumed by each indoor unit based on the indoor unit information of each indoor unit. And a power consumption amount of each air conditioner is a power consumption amount of each indoor unit calculated by the power splitter. The method of claim 2, Further comprising a demand database for storing the power consumption of each indoor unit calculated by the power divider, And the demand control unit sets a low priority to an indoor unit having a small amount of power consumption based on the power consumption amount of each indoor unit stored in the demand database. The method of claim 2, Further comprising a demand database for storing the rate of change of the power consumption of each indoor unit calculated by the power divider per predetermined time, And the demand control unit sets a low priority to an indoor unit having a small change rate per predetermined time of the power consumption amount based on a change rate per predetermined time of the power consumption amount of each indoor unit stored in the demand database. The method of claim 2, The indoor unit information of each indoor unit includes the capacity of each indoor unit, And a power consumption amount of each indoor unit is proportional to the capacity of each indoor unit. The method according to any one of claims 1 to 5, And the demand control unit first reduces the operation rate of the indoor unit having a lower priority if it is determined that the estimated power amount exceeds the set power amount. Electrical devices including a plurality of air conditioners including a plurality of indoor units and an outdoor unit for supplying refrigerant to the indoor units; A predicted power amount sensing unit for sensing a predicted power amount of the electric devices; And a demand controller for controlling an operation state of the electric devices when the predicted electric energy amount detected by the predicted electric energy quantity sensing unit exceeds a set electric energy, The demand controller divides the indoor units into a plurality of groups, sets a priority to each group based on the power consumption of each group, controls the respective groups based on the priority, The demand control unit is configured to determine the load of each of the groups, to set a low priority to a group with a small load, and to adjust the operation rate of the low priority group preferentially. The method of claim 7, And a power divider configured to calculate and display the amount of power consumed by each indoor unit based on the indoor unit information of each indoor unit. And a power consumption amount of each group is a sum of power consumption amounts of indoor units belonging to each group. The method of claim 8, Further comprising a demand database for storing the sum of the power consumption of the indoor units belonging to each group in the power splitter, And the demand control unit sets a low priority to a group having a small sum of power consumption amounts of indoor units belonging to each of the groups. The method according to any one of claims 7 to 9, And the demand control unit first reduces an operation rate of an indoor unit belonging to a low priority group when it is determined that the estimated power amount exceeds the set power amount. The method of claim 10, The demand control unit sets the priority of each indoor unit based on the power consumption of each indoor unit, And a control apparatus for an electric machine system that controls each group and each indoor unit belonging to each group based on the priority of each group and the priority of each indoor unit belonging to each group. The method of claim 11, And the demand control unit first reduces an operation rate of an indoor unit having a lower priority among the indoor units belonging to each group when it is determined that the estimated power amount exceeds the set power amount.

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