KR100504558B1 - apparatus and method for controlling load in power management system - Google Patents

Abstract

The present invention is a load control device and method of a power management system that induces distributed power usage by remotely controlling a home or commercial power equipment according to a separate agreement between an electric user and a host organization at a peak load of a power generated according to a predetermined time or season. In order to provide a, a load control device for controlling a corresponding power device by receiving a control command includes a pager receiving unit for receiving and decoding a control command received through a wireless calling method from a wireless base station, and received and decoded at the pager receiving unit. A handy loader communication unit for comparing a control command with a pre-stored unique ID and determining a control command according to the corresponding power device, and after determining whether the control command is made by the handy loader communication unit, setting the temperature according to the control command and A power control unit performing control of an operation mode and the power control It includes a display unit for displaying the control information and status information of the power device to be performed through, and the microcomputer to control the operation of the pager receiver, handy loader communication unit, power control unit, display unit, load control according to power management is possible As a result, the remote control system can be activated and systematically managed.

Description

Apparatus and method for controlling load in power management system

The present invention relates to a power management system, and more particularly, to a load control device and method of a power management system for controlling the domestic demand power by remote control using a separate load control device.

The consumption of electricity is increasing significantly every year as the national income increases, and in particular, the supply and demand of electric power is not stable due to cooling loads in summer, and systematic power demand management measures are emerging.

One of the methods is the direct load control method. The direct load control method concludes an agreement between the utility company and the user in advance in order to efficiently suppress the peak load of the utility company system, When a load occurs, the utility company restricts the user's power usage equipment by the contracted time and number of times.

In addition, the utility company provides the users with benefits such as contract compensation, so-called interdependent and complementary load management system.

Based on this background, the domestic supply and demand interlocking direct load control system is introduced, and the utilization of the remote control air conditioner currently being implemented by KEPCO, a power company, is an example of direct load control.

The remote control air conditioner system manufactures a separate remote control air conditioner in a manufacturing plant, which controls the air conditioner by transmitting a control signal to a receiver by a host (eg, a power company) by embedding a receiver in the air conditioner.

In operation, first, when the command is given by the host organization, the receiver transmits and receives a receiver embedded in the air conditioner, and the receiver transmits the received data to the main board of the remote control air conditioner.

Subsequently, when the off control command signal is received, the main board stops the air conditioner operation and displays a remote control display so that the user can recognize the signal until the off control command signal ends.

As described above, the conventional power management system for controlling home demand power is to separately attach a receiver to a home power device from a production line, and to supply it to a user who desires it.

Therefore, it is impossible to control the power management system for the household power equipment manufactured without the receiver attached separately and the user who purchases and uses the same.

This is a big problem in managing the systemic power demand to stabilize the power supply and demand, because the accurate calculation of energy consumption used by 13 million households is not made.

In other words, in order to introduce an efficient power management system, it is necessary to replace all the power devices in all homes with household power devices capable of managing power, which is a great economic burden at home. The replacement time will be very long.

In addition, since all production lines must be changed and added to production lines that can manage power at present, it will be very costly for manufacturing plants.

Therefore, the present invention has been made to solve the above problems, the amount of power used by remotely controlling a home or commercial power equipment according to a separate agreement between the electric user and the host organization at the peak load of the amount of power generated according to a predetermined time or season It is an object of the present invention to provide an apparatus and method for controlling a load of a power management system to induce distributed distribution.

Another object of the present invention is to provide an apparatus and a method for controlling a load of a power management system that enables remote control of a host organization without changing a power device and a production line that are not remotely controlled by an existing user.

Still another object of the present invention is to efficiently perform power management by managing power demand systematically in a host device for power devices in all homes.

Another object of the present invention is to wirelessly control a power device.

Features of the load control device of the power management system according to the remote control of the present invention for achieving the above object is a server for a power supply for generating a load control command, and transmits the load control command in a pager (wirer) method In the power management system according to the remote control comprising a plurality of wireless base station and a load control device for receiving the transmitted control command and control the power device, the load control device is a wireless call method in the wireless base station; A pager receiving unit for receiving and decrypting a control command received through the control unit, a handy loader communication unit for comparing a control command received and decoded by the pager receiving unit with a pre-stored unique ID to determine whether or not a control command according to a corresponding power device is used; After determining whether the control command is made by the handy loader communication unit, A power control unit for controlling temperature setting and operation mode, a display unit for displaying control information and status information of a power device performed through the power control unit, and operation of the pager receiver, handy loader communication unit, power control unit, and display unit. It is configured to include a microcomputer to control.

At this time, the handy loader communication unit is set to give a unique ID of the load control device to control only the load control device to be controlled by the host, and has an overcurrent protection function.

The power device may be configured of at least one of an air conditioner and an air conditioner as a cooling device, and a heater and a heater as a heating device.

A feature of the load control method of the power management system according to the present invention for achieving the above object is a first comparison step of comparing the current power rate and the power reserve rate currently being provided from the host in real time with the server, and As a result of the comparison, when the total power ratio is greater than the power reserve ratio, the first transmission step of generating control command data and transmitting the control command data to a specific wireless base station through the communication network; And a second transmission step of wirelessly transmitting at a predetermined interval for each user if the load control command is individual, and comparing the unique ID of the previously stored power device with the ID according to the transmitted control command by decoding the received control command. If the second comparison step and the comparison result ID is the same, the current state of the power device A storing step of storing and displaying the information and the state of the power device according to the control command, and transmitting the control command to the control unit of the corresponding power device, and the control unit of the power device controls the control according to the transferred control command. It comprises a step.

In this case, the generation of the control command may include defining any one of the regional load control for controlling the load for each region, the individual load control for controlling the load for each individual, and setting the temperature again if the regional / individual load control is defined. There is another feature, including the step of defining any one of a temperature setting control to control and an operation mode control to control the operation state.

The display in the transfer step includes the start time and end time of the received load control command, the type of control command (temperature setting control, operation state control), the designated temperature specified in the temperature setting control, and the operation. In the case of the state control, it is preferable to display at least one of stopping the operation of the outdoor unit or shutting down the air conditioner power supply.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

A preferred embodiment of the load control device and method of the power management system according to the remote control of the present invention will be described with reference to the accompanying drawings.

1 is a schematic view showing a power management system according to the present invention, Figure 2 is a view showing a power management system according to the present invention in detail.

1 and 2, the server 100 for power supply to generate a load control command by comparing the power reserve rate and the total power rate in use, and the control command received in the server 100 is installed in a predetermined area unit Composed of a plurality of wireless base station 200 to transmit by a pager method, and a plurality of users 300 using the home power device 500 as input to the control command transmitted from the wireless base station 200 do.

In this case, the user 300 further includes a load control device 400 for receiving a control command transmitted from the wireless base station 200 and controlling the corresponding power device 500.

As such, the control command transmitted from the power supply server 100 is transmitted to the wireless base station 200 for each region through the communication network, and the wireless base station 200 wirelessly calls the received control command to the individuals in the corresponding area. pager). The control command transmitted wirelessly is received and processed by the load control device 400 separately configured in the power device to control the corresponding power device 500 in the home.

3 is a block diagram showing in detail the load control device of the power management system according to the present invention.

As shown in FIG. 3, a pager receiver 410 that receives and decodes a control command received through a wireless call method from the wireless base station 200, and a unique stored pre-stored control command received and decoded by the pager receiver 410. Handy loader communication unit 430 for determining whether or not the control command according to the power device 500 compared to the ID, and after the control command by the handy loader communication unit 430 determines whether to control the power device 500 Corresponding to the power control unit 450 to control the temperature setting and operation mode, the display unit 440 for displaying the control information and status information of the power device 500 performed through the power control unit 450, It is composed of a microcomputer 420 to control the entire system.

In this case, the handy loader communication unit has a function of setting a unique ID of the load control device so as to control only a load control device that the control authority wants to control, and also has an overcurrent protection function.

In addition, the power device 500 is preferably an air conditioner and an air conditioner, which is a cooling device, a hot air heater, a heater, or the like that is a heating device. Here, the control command output from the power control unit 450 of the load control device 400 is configured to be transmitted to the main board (not shown) of the power device 500. To this end, the load control device 400 and the power device 500 may be configured to connect through a data signal line such as an RS-232C communication cable.

The load control method of the power management system according to the present invention configured as described above will be described in detail with reference to the accompanying drawings.

4A and 4B are flowcharts illustrating a load control method of the power management system according to the present invention.

4A and 4B, first, the power supply server 100 receives power status information such as total power rate and power reserve rate information currently being used in real time from the host organization (S10).

Then, the server 100 determines whether to perform a load control scenario by comparing the power reserve ratio information input in real time with the total power ratio currently being used (S20).

That is, the load control is performed when the total power rate currently being used is greater than the reserve rate.

If load control is performed as a result of the determination, first, the server 100 generates control command data according to the load control execution scenario (S30).

That is, the generation of the control command data defines any one of the regional load control for controlling the load for each region and the individual load control for controlling the load for each individual. The regional / individual load control may define any one of a temperature setting control for controlling a set temperature again and an operation mode control for controlling an operating state.

The load control for each region is a method of performing a control command only to the power device 500 of the user 300 located in a specific region, and not performing a control command to other regions.

The individual load control is a method of performing a control command to the power device 500 by selecting the power device 500 of the user 300 located in all regions to cross each user 300.

When described in detail through the preferred embodiment as follows.

First, it is desirable to divide Seoul, Gyeonggi, Gangwon, Chungcheong, Gyeongsang, Jeolla, and Jeju by region, and classify them into military units.

In other words, the Seoul area is divided into Seocho-gun, Yangjae-gun, Banpo-gun, Songpa-gun, Gangdong-gun, Seongdong-gun, Guri-gun, Weightong, Seongbuk-gun, Sinchon-gun, Jongno-gun, Changdong-gun, Dongdaemun-gun, Nowon-gun, Yeongdeungpo-gun, and Mapo. It is classified into a number of groups such as Gun, Guro, and Gangseo. Thus, each region is classified into a number of military units.

If it is determined that load control is required in the Seoul area, the server 100 specifies whether to use a regional load control method or an individual load control method.

When the load control method for each region is designated, it is preferable to use the case where the load control time is short by transmitting a load control command to a specific region through a corresponding base station for a predetermined time.

That is, during the time intervals such as 10 minutes, 30 minutes, and 1 hour, the load control command is first transmitted only to Seocho-gun, Banpo-gun, Seongdong-gun, Heavy, Yeongdeungpo-gun, and Guro-gun, and after a predetermined time, Yangjae-gun Send load control command only to Songpa-gun, Gangdong-gun, Guri-gun, Seongbuk-gun, and Jongno-gun. After a predetermined time, the load control command is transmitted only to Sinchon-gun, Changdong-gun, Dongdaemun-gun, Nowon-gun, Mapo-gun, and Gangseo-gun.

When the individual load control method is designated, all base stations are sequentially selected and load control is performed by dividing the individual user 300 subordinate to each base station by a predetermined time unit and transmitting a load control signal. It is preferable to use when time is long.

As described above, the load control method for each region transmits a load control signal on a local basis, and the load control method for each individual transmits a load control signal on an individual basis.

At this time, when the server 100 effectively suppresses the same peak load, the user 300 transmits a control command in the load control method for each region, compared to the control command in the individual load control method. The control command has to be transmitted for a long time. On the contrary, the load control method for each region has less advantages than the load control method for each individual.

In this way, the server 100 selects an appropriate load control method according to the time for performing the load control, and specifies whether to perform temperature setting control or operation state control again.

The temperature setting control is a command for maintaining the temperature of the selected power device 500 at a defined predetermined temperature, and the operation mode control is a command for stopping the operation of the selected power device 500.

As such, when generation of the control command is completed, the control command is transmitted to the wireless base station 200 through the communication network (S40).

In this case, when the control command to be transmitted to the wireless base station 200 is load control for each region, the control command is transmitted only to a specific wireless base station 200 (S50), and the control command is wirelessly transmitted to the user 300 in the corresponding area ( S60).

In addition, if the control command to be transmitted to the wireless base station 200 is load control for each individual transmits the control command to all wireless base station 200 (S70), and wirelessly transmits the control command to all users 300 at a predetermined interval. (S80).

As such, the server 100 selectively transmits a control command among a plurality of wireless base stations 200 according to the load control for each region and individual, and again, the wireless base station 200 wirelessly uses a pager method. The control command is transmitted to the user 300.

In this case, the user 300 separately attaches the load control device 400 to the domestic power device 500 to receive and process a control command transmitted wirelessly.

Therefore, the load control device 400 receives a control command received from the wireless base station 200 through a radio call method through a pager receiver 410 and decodes the received control command (S90).

If the unique ID of the power device stored in the handy loader communication unit 430 and the ID according to the decoded control command are not matched, the received control command is ignored. Save the state (S100).

In addition, the microcomputer 420 displays the information according to the control command and the state of the power device 500 on the display unit 440 (S110).

That is, the content displayed on the display unit 440 includes the start time and end time of the received load control command, the type of control command (temperature setting control, operation state control), and the designation designated in the case of the temperature setting control. In the case of the operation state control, it is preferable to indicate the temperature and the stop state of the outdoor unit operation or the interruption state of the air conditioner power supply.

Subsequently, the power device 500 selected according to the received control command is controlled by the power control unit 450.

That is, it is determined whether the transmitted control command is the temperature setting control or the operation mode control (S120).

When the determination result shows that the temperature setting control adjusts the temperature of the selected power device 500 to the set temperature (S130), and if the driving mode control, the power of the selected power device 500 is turned off (S140).

Looking at the operation of the air conditioner with the power device 500 as a preferred embodiment, when the received control command is set to a temperature setting control set to 20 ℃, temporarily stores the temperature of the current air conditioner and the temperature of the air conditioner to 20 ℃ Adjust

In addition, when the received control command receives the operation mode control, temporarily stores the temperature and the reservation time of the current air conditioner and stops the operation of the outdoor air conditioner.

The microcomputer 420 displays the remote control state on the display unit 440 so that the user 300 can recognize the control command transmitted from the wireless base station (S150).

In addition, the load control device 400 and the main board of the power device transmit and receive each other to check the normal operation, and if there is no response for more than 5 minutes to return the operation of the air conditioner to the normal state.

The power device 500 is repeatedly performed during the control time according to the control command received as described above, and after the control time passes, the power device 500 returns to the initial state of the temporarily stored power device even if the control command is over (S160). ).

The load control device and method of the power management system according to the present invention as described above has the following effects.

First, by attaching a separate external load control device to a user who has previously installed a power device that does not have a load control system, it is possible to control the load according to power management, thereby enabling the remote control system and systematic management There is.

Second, according to a separate contract between the power user and the host organization at the peak load of the amount of power generated according to a predetermined time or season, it is possible to more effectively remotely control the home or commercial power equipment to induce distributed power usage.

Third, it is possible to easily configure the remote control system of the host organization without changing the power equipment and the production line that cannot be remotely controlled by the existing user.

Fourth, power management in all homes can be efficiently carried out by managing power demand systematically by the host organization.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

1 is a schematic diagram showing a power management system according to the present invention

2 is a view showing in detail the power management system according to the present invention

3 is a configuration diagram showing in detail a load control device in a power management system according to the present invention;

4A and 4B are flowcharts illustrating a load control method of a power management system according to the present invention.

* Explanation of symbols for main parts of the drawings

100: server 200: wireless base station

300: user 400: load control device

410: pager receiving unit 420: microcomputer

430: handy loader communication unit 440: display unit

450: power control unit 500: power equipment

Claims (4)

A server for a power supply generating a load control command, a plurality of wireless base stations for transmitting the load control command in a pager manner, and a load control device for receiving the transmitted control command and controlling the corresponding power device. In the power control system according to the remote control configured, the load control device is A pager receiving unit for receiving and decoding a control command received through a wireless calling method in the wireless base station; A handy loader communication unit for comparing the control command received and decoded by the pager receiver with a pre-stored unique ID to determine whether the control command according to the corresponding power device is present; A power controller configured to perform temperature control and operation mode control on the corresponding power device in response to the control command after determining whether the control command is performed by the handy loader communication unit; A display unit displaying control information and status information of the power device performed by the power control unit; And a microcomputer for controlling operations of the pager receiver, the handy loader communication unit, the power control unit, and the display unit. The server comprises a first comparing step of comparing the current power reserve and the current power reserve provided from the host in real time, A first transmission step of generating control command data and transmitting the control command data to a specific wireless base station through a communication network if the total power rate is greater than the power reserve rate as a result of the comparison; The wireless base station transmits wirelessly to a corresponding user by region if the received control command is a load control command for each region, and wirelessly transmits at a predetermined interval for each user if the individual load control command is performed; A second comparing step of decoding the received control command and comparing a unique ID of a previously stored power device with an ID according to the transmitted control command; A transmission step of storing a current state of a corresponding power device, displaying information according to the control command and a state of the power device when the comparison result IDs match, and transferring the control command to a control unit of the corresponding power device; The control unit of the power device comprises a control step of controlling according to the transmitted control command, characterized in that the load control method of the power management system. The method of claim 2, wherein the generation of the control command Defining any one of regional load control to control loads by region and individual load control to control loads by individual; And defining any one of a temperature setting control for controlling a set temperature again and an operation mode control for controlling an operating state when the load control for each region / individual is defined. The method of claim 2, wherein the indication in the delivery step is Start time and end time of the received load control command, type of control command (temperature setting control, operation state control), designated temperature specified in the temperature setting control, and stop of outdoor unit operation in case of the operation state control. Or at least one of a cut-off state of the air conditioner power supply.