KR100187605B1 - Maximum power management method and device or-line fitted by load power - Google Patents

Abstract

According to the present invention, when a power management center of a power supplier and a maximum power management device of a customer are normally connected online through communication, when a need arises to adjust the maximum power of a customer due to the need of a power supply, such as in the case of a summer power peak, A maximum power management method and a management apparatus for controlling a maximum power used by a customer according to a target power for each customer transmitted from a power management center of a supplier, comprising: a power centralized management unit installed at a branch or branch of a power supplier; A dedicated communication network for online communication between the power concentration management unit and a customer; Supply-linked maximum power manager installed in the customer of the site; And a switched line or dedicated line modem for connecting the supply-demand type maximum power manager to the communication network. In the event of power supply failure, the power supply company directly manages the supply and demand of power by supplying power. It is an invention that can expand and spread the management equipment, thereby reducing enormous investment in power plant construction and power equipment expansion, and also prevent the environmental pollution caused by the combustion of power fuel derived from the production of electric power. .

Description

Power supply online interlocking maximum power management method and management device

The present invention relates to a maximum power management method and a management device that operates in conjunction with the power supply and demand situation of the power supplier on-line, in detail, the power management center of the power supplier and the maximum power management device of the customer by communication online When connected, but when the need to adjust the maximum power of the customer due to the need of the power supply, such as in the summer power peak, the maximum power of the customer is controlled according to the target power for each customer transmitted from the power management center of the power supplier It relates to a maximum power management method and its management apparatus.

Electric power business is a main business of a country, and as a result, both production and consumption take place at the same time. Therefore, the power supplier should secure supply reserves in accordance with the consumption level of consumers and the behavior of electricity use. Therefore, the maximum of a certain day of the particular season (summer), in which the maximum peak occurs during the four seasons of the year (in Korea, the peak peak of the year occurs at 2: 00 ~ 3: 00 PM on the third Wednesday of August). Power supply facilities of power generation facilities should be equipped so that power can be supplied at all times even when electric power demand.

Recently, as the standard of living is improved and the industry is developed, the consumption of power energy has exploded, and the cooling load increases every year, which greatly threatens the electricity supply and demand every summer (July and August). The increase in power demand is due to the rapid increase in cooling load, which far exceeds the expected increase in statistical power demand.

Therefore, the power supplier has continued to expand the power plant every year with a huge investment to supply the shortage of maximum power, but such power supply has not been able to meet the explosive demand of power recently. Moreover, the enormous burden of construction cost in the long-term power supply and demand and securing the construction site of the power plant due to the NIMBY phenomenon of local residents make it difficult to construct new power plants. It is true.

However, the recent increase in power demand shows that the increase rate of the maximum power is higher than the increase rate of the average power, which not only demands an increase in the investment cost of the power equipment, but also lowers the utilization rate and the load rate of the power equipment. The investment efficiency is greatly reduced. This phenomenon is to force the power supplier to over-construct the power plant, but this is because there is a limit for the above reasons. Therefore, there is an urgent need to prepare power supply and demand measures not only in terms of power supply but also in terms of load management that consumes power.

As a result, power providers are implementing various demand management measures that induce consumers to save power, such as implementing a load management fee system (baseline 12-month linkage system), but in reality, effective demand management will reduce or suppress the maximum demand power. The lack of means is the current situation.

For this reason, the need for a control device for direct load management has emerged, and a maximum power management device of Patent Application No. 96-899 filed on January 3, 1996 has been proposed and used.

As shown in FIG. 1, the maximum power management device includes: a CCD camera 20 for capturing a moving image (movement of a watch scale) of a typical maximum demand power meter 10; An illumination unit 30 that provides appropriate illumination to the maximum demand electricity meter 10; A synchronous connection device 40 for detecting a reset time of the 15 minute maximum demand clock 11 and the amount of power used; A maximum power management main unit 51 for controlling the maximum power of the customer to be maintained at a predetermined target power; A printer 60 for outputting an amount of power used at a predetermined time; Relays that drive magnetic switches 82 ₁ , ..., 82 _N that sequentially shut off external controlled loads 90 ₁ , 90 ₂ , ... 90 _N when the maximum amount of power exceeds the target power. Relay box 80 composed of; And an alarm output device 70, wherein the synchronous connection device 40 further includes a frame grabber unit 41 for converting an analog video signal into digital data; An image processing CPU unit 42 for signal processing the digital data to calculate the reset time and the amount of power used for the 15 minute maximum demand clock; And an output unit 43 for generating pulses proportional to the operation value.

In addition, the conventional maximum power management device configured as described above is built as a power management system to manage the maximum power of the customer as shown in Figure 2, the control method is made as follows.

First, the CCD camera 20 captures the analog image signal which captures the movement of the indicator of the 15 minute maximum demand clock 11 and the 15 minute maximum demand power value and the movement or rotation of the red or black mark of the rotating disc 12. When inputted to the frame grabber part 41, the frame grabber part 41 converts the above signal into digital image data and transmits it to the image processing CPU part 42. The image processing CPU unit 42 processes the video data to calculate the reset time and the amount of power used for the 15-minute maximum demand clock, and transmits the calculated value to the output unit 43. The output unit 43 receiving the operation value outputs a pulse generated in every 15-minute time-out reset and a pulse proportional to the amount of power used to the maximum power management main unit 51 at a short distance or a remote location. The maximum power management main unit 51 receives the pulses, calculates a predicted power value, and sends a control signal to a specific relay in the relay box 80 when the predicted power value exceeds a predetermined target power. 82 to open the specific switch (82 ₁ , ... 82 _N ) to cut off the power used by the specific load (90 ₁ , ... 90 _N ) and to control the alarm output device 70 The alarm generator 71 is driven.

When the maximum power continues to grow using the power off first by increasing the number of relays in the relay box 80 to block in order of preference supplied to the load (90 _1, ... 90 _N) outside the magnetic switch (82 ₁ , ..., 82 _N ) to further cut off, and if the maximum power used decreases, turn off the relay to supply power to the load (90 ₁ , ... 90 _N ) again. It is possible to use the maximum power within the range of power to improve the load ratio and increase the operation rate of the power equipment, and the use of the maximum power is suppressed, so that the power supply company can reduce the investment of the power generation equipment.

However, in the conventional synchronous maximum length power management device and its management method which are configured and operated as described above, the target is instantaneously managed by the customer installed independently and the target power is independently managed by the power supply company regardless of the power supply company. There was a problem in that it is not possible to efficiently control the time of the maximum power generation fluctuating from time to time because it is impossible to change the period that requires management by power. Not only does this occur not only when the power consumption by individual customer is maximized on a day other than a specific day in the summer, but also when the industrial plant is a large-scale consumer, the power usage frequently occurs during the year. This is especially a problem.

This situation is not directly helpful to the power supply and demand management method to control the maximum power within the target power, but rather according to the 12-month interlocking system of the base rate where the power usage fee is determined based on the maximum power within the target power period. Only the low price, which negatively affects the electricity supplier's maximum power management policy, is a major obstacle to achieving the interests of a country that wants to suppress the overinvestment of power generation facilities by curbing the use of maximum power.

In order to solve the above problems, a direct load controller has been proposed that provides a command to cut off the end cooling loads of a remote customer directly through a communication line in accordance with the power supplier's request. By blocking the customer's cooling load for a long time for several to several ten minutes, the customer's repulsion is severely induced and thus the device is not extended. Therefore, the peak power management for a specific period of time is limited to limit the customer's maximum power consumption to the target value. There was still an inherent problem.

Therefore, the present invention was created to solve the above problems, and the target value of the maximum power management of the consumer is to be controlled remotely by the power concentration management means connected to the maximum power management means of the customer online. It is an object of the present invention to provide a power supply online interlocked maximum power management method that allows the power supplier to remotely manage the maximum power used by the customer during the supply-demanded operation period, another object of the present invention, the customer and the power supplier Power supply that can meet the demand of the power supply online interlocked maximum power management method and the direct management of the urgent maximum power consumption of the power supplier that meets the charging method according to the maximum power consumption within the specified demand time of the power supplier. It is to provide a supply-demand online linked maximum power management method, the present invention Another objective is to identify the suyongga a multi-level to provide a power supply line linked up to power management method for performing the steps of the direct management of the maximum power according to priority, depending on the trend of the maximum power usage.

In addition, an object of the present invention is to allow the target value of the maximum power of the consumer to be controlled remotely by the power central management means linked to the maximum power management means of the customer so that the maximum use of the customer during the supply-demand operation of the power supplier It is to provide a power supply online interlocked maximum power management device that allows the power supplier to remotely manage the power directly, another object of the present invention, the maximum power within the specified demand time of the power supplier, the contract between the customer and the power supplier It is to provide a power supply and demand online interlockable maximum power management device that meets the charging method according to the usage amount and the power supply and demand online interlockable maximum power management device that can promptly respond to the urgent need for direct management of the maximum power consumption of the power supplier. Another object of the invention is that, when the emergency maximum power remote control time is over It is to provide a power supply on-line linked maximum power management device that allows the user to efficiently manage the maximum power independently, another object of the present invention, the existing maximum power management to independently manage the maximum power of the customer An object of the present invention is to provide a power supply online interlockable maximum power management device that can accommodate a device, and another object of the present invention is to store the target power according to the power usage of each consumer, and thereby to display the usage status At the same time, it is to provide a power supply on-line linked maximum power management device that enables the appropriate and efficient management of maximum power according to customer or usage.

In addition, an object of the present invention is to divide the maximum power of the customer by region to manage by region and to centralize it again to manage the target power of the maximum power used by region to enable efficient regional distribution of the total power used It is to provide a power supply online interlocked maximum power management device.

1 is an internal configuration block diagram of a conventional maximum power management device,

2 is a schematic installation diagram showing a conventional maximum power management device connected to control each power load,

Figure 3 is a block diagram of the overall configuration of an embodiment of a power supply on-line linked maximum power management device according to the present invention,

4 is a block diagram showing in more detail the power supply-linked maximum power manager of FIG.

FIG. 5 illustrates in more detail the switching unit of FIG. 4 enabling power control by a conventional maximum power management device.

6 is a detailed block diagram of the power concentration management unit of FIG.

7 is a detailed block diagram of the communication concentrator of FIG.

(A) of FIG. 8 shows an example of an operation period and an operation mode in which the supply-demand interlock type maximum power manager is designated by the power concentration management unit.

(b) is a diagram of how the supply-demand interlocked maximum power manager processes the command when receiving a remote control command from the power centralized management unit.

FIG. 9 is a flowchart illustrating a method of managing maximum power in a power management mode in which a supply-demanded maximum power manager is linked.

* Explanation of symbols for main parts of the drawings

RY: relay 1: power transmission line

2: transformer box for the instrument 3: remote communication line (power power line)

4: control operation line 10: normal maximum demand power meter

11: Maximum demand indicator 11 ': Monthly maximum demand indicator

11: 15 minutes maximum demand indicator 11 ': 15 minutes maximum demand indicator indication scale

12: rotating disc 12 ': display mark on the rotating disc

20: CCD camera 30: lighting unit

40: synchronous connection device 41: frame grabber

42: image processing CPU unit 43: output unit

44: monitor 50: conventional maximum power management equipment

51: maximum power management device 60: printer

70: alarm output device 71: alarm generator

80: relay box 82: magnetic switch box

82 ₁ , ..., 82 _N : Magnetic switch 90 ₁ , ... 90 _N : Controlled power load

100: central power management unit 110: power concentration management unit

111: server computer 112 ₁ , 112 ₂ , ...: client computer

113 ₁ , 113 ₂ , ...: Printer 114: Power Management Status Board

115: situation board driving unit 119: local area network

120: communication concentrator 121: central processing unit

122 ₁ , 122 ₂ , ...: multi-channel serial input / output

123 ₁ , 123 ₂ , ...: switched or dedicated line modem

124: communication connection 190: dedicated communication network

200 ₁ , ... 200 _N : Power consumer 204: Remote control terminal

205: switched or dedicated line modem 206: magnetic switch box

206 ₁ , ..., 206 _N : Magnetic switch 209 ₁ , ... 209 _N : Power load

210: supply and demand interlock type maximum power manager 211: synchronous connection

212: main control unit 213: input unit

214: switching unit 214 ₁ , 214 ₂ , ... 214 _M : switch

291: Maximum capacity electricity meter for power supplier transactions

294: relay box 295: management computer

296: printer 299: conventional maximum power management device

In accordance with the present invention for achieving the above object, the power supply online linked-type maximum power management method is a communication network connected online with on-line data on the operation status of power usage status and power usage management means of the customer. Transmitting to the power concentration management means of the power supplier through; Monitoring and predicting an overall maximum power supply and demand situation using data transmitted from each customer; Determining whether it is necessary to adjust the maximum power of a particular consumer; If it is determined that it is necessary to adjust the maximum power of a specific customer, transmitting a remote control command, a target power, and an operation time for the customer determined in the determining step through a communication network connected online; The customer maximum power management means for storing the transmitted target power and the operating time, etc. and responding to the command; And controlling the maximum power according to the set contents, wherein the responding to the command in the power supply online linked maximum power management method according to the present invention comprises: receiving the command data; Maintaining a target power for a predetermined demand time in progress in synchronization with the maximum demand electricity meter for the electricity supplier transaction; And replacing the target power with the received value when the specified time limit is completed. The remote control command may be performed in the power supply online linked maximum power management method according to the present invention. The step of transmitting, in addition to the remote control command, etc., further transmits a new designated demand time limit, and the step of responding to the command replaces the current target power value immediately after receiving the command data and initializes the specified demand time limit in progress. step; And a step of advancing a new specified demand time limit, wherein the new specified demand time limit is shorter than the ongoing specified demand time limit, which has another feature, according to the present invention. Determining whether or not the adjustment of the maximum power of the, step of determining whether to adjust the maximum power to the customer corresponding to the priority according to the priority of the customer divided into a plurality of steps; There is a characteristic.

In addition, the power supply online interlocking type maximum power management apparatus according to the present invention, communication means for transmitting and receiving data through a communication network, input means and control command to set the power management modes linked to the independent power management mode And the target power is received through the communication means, and the power control of the external power load device is performed according to the set target power, and at the same time, the measured power use status and operation status are transmitted through the communication means, and whether a predetermined time has elapsed. Supply-demand interlocked maximum power management means including main control means for monitoring; At the same time, the maximum power of a predetermined area including a communication intensive means capable of connecting and communicating with the communication means of the plurality of supply and demand interlocked maximum power management means and remotely monitor the target power of the supply and demand interlocked maximum power management means Power intensive management means for commanding; And a communication network to which the communication means and the communication intensive means are connected to enable data exchange. The main control means of the power supply and demand on-line linked maximum power management device according to the present invention is interlocked. When the power management mode is set, when the remote control command data is received through the communication means, the target demand time is maintained after maintaining the currently set target power for the specified demand time limit in synchronization with the maximum demand electricity meter for the power supplier transaction. It is characterized by controlling the maximum power by exactly changing the new target power value received at the same time as the deadline, and matching the specified demand time limit of the maximum power electricity meter for trading. At the same time, initialize the specified demand time limit in progress and In order to control the maximum power irrespective of the specified demand time limit of the maximum amount of electricity meter for trading, the new specified demand time limit is another feature that is shorter than the specified demand time limit in progress, power supply online interlocking type according to the present invention The main control means of the maximum power management device is to control the maximum power by restoring the customer prior to receiving the remote control command to the target power and the specified demand time when the remote control operation time by the remote control operation command ends. Among the power supply and demand online interlocked maximum power management device according to the present invention, the supply-demanded maximum power management means, the load control output signal and the main control means of the existing maximum power management device that is already installed in the customer The supply-demand interlocking type is selectively controlled by the control of the main control means. Switching means for connecting to the control signal output terminal of the large power management means; further characterized in that it comprises a, the power intensive management means of the power supply online linked maximum power management device according to the present invention, A server computer that is in charge of processing power usage, target power for management, and associated database; A client computer that displays the power management status of the customer and prints it as needed; Power management status board showing key data necessary for maximum power management at a glance; Situation board driving means for driving the power management situation board; And a local communication network for exchanging data between the communication intensive means, the server computer, the client computer, and the situational board driving means.

In addition, the power supply online interlocking maximum power management device according to the present invention, the communication means for transmitting and receiving data through the communication network, the input means for setting the power management mode and the like interlocked with the independent power management mode, and Receives a control command and target power through the communication means, performs power control of the external power load device according to the set target power, and simultaneously transmits the measured power usage and operation status through the communication means, and passes the predetermined time. Power supply and demand online interlocked maximum power management means including main control means for monitoring whether or not; And monitoring the maximum power of the set interlocked maximum power management means, comprising a communication concentrated means capable of communicating with the communication means of the plurality of interlocked maximum power management means in a certain area at the same time. Power intensive management means for remotely instructing target power; Including a central communication means connected to the communication concentration means of the plurality of power concentration management means connected to the dedicated line and connected with the power concentration management means online to report the power supply situation by region and the regional targets to the power concentration management means Central power management means for directing power; And a communication network to which the communication means and the communication intensive means are connected to each other to enable data exchange.

In the power-supply online linked-type maximum power management method and the power-supply online linked-type maximum power management device that implements the above method, first, the power consumer is in the power management mode linked with the independent power management mode through the input means. Select the operation mode to operate the power supply interlocking type maximum power management means, and if operating in an independent power management mode, the customer to manage the maximum power independently regardless of the power supplier as in the conventional maximum power management equipment do. Even if the above-mentioned interlocked maximum power management means is selected and operated as an interlocked power management mode, when there is no remote control command of the power supplier, it operates in the same manner as the independent power management mode. The operation status of the supply-demanded maximum power management means is transmitted to the power concentration management means through the communication means and the communication network.

When the supply-demanded maximum power management means is operating in the interlocked power management mode as described above, when remote control command data is received from the power intensive management means through the communication intensive means and the communication network, The power management means adjusts the maximum power to the demand power to be managed by the target power value received with the command data immediately or at the time when the specified demand time limit in progress is completed, thereby shortening the power supplied to the power load of the customer. By shutting off or turning on time, the power is properly operated within the target power set by the new power supplier.

If there is no remote control command, the supply and demand interlock type maximum power management means manages the maximum power of the customer by using a control signal by the existing maximum power management device, and if there is a remote control command, the contact point of the switching means is changed. It is also possible to manage the power load under the new target power as the control signal by the main control means instead of the control signal input from the existing maximum power management device.

Hereinafter, the configuration and operation of the power supply-demand online linked type maximum power management method according to the present invention and an embodiment implementing the method will be described in detail with reference to the accompanying drawings.

3 is a block diagram showing the overall configuration of an embodiment of a power supply and demand online linked power management device according to the present invention, the power supply and demand online linked power management device, the power installed in the branch or branch of the power supplier (Korea Electric Power) Centralized management unit 110; A dedicated communication network 190 for online communication between the power concentration management unit 110 and the customer (200 ₁ , ... 200 _N ); Supply-demand interlock type maximum power manager 210 is installed in the site customer (200 ₁ , ... 200 _N ); And a switched line or dedicated line modem 205 for connecting the supply-demand type maximum power manager 210 to the communication network 190. The power supply control is performed by the supply-demand type maximum power manager 210. A magnetic switch box 206 composed of a relay RY or a remote control terminal 204 for enabling the magnetic switch, and magnetic switches for interrupting or supplying electric power by the relay RY or the remote control terminal 204; Also shown are power loads 209 ₁ ,... 209 _N , in which power is cut off or turned on by opening or shorting of the magnetic switch.

FIG. 4 is a block diagram showing in more detail the supply-demand type maximum power manager 210 installed in the customers 200 ₁ ,... 200 _{N of} FIG. 3. A synchronous connection unit 211 that reads the reset point of the specified demand time limit (currently set to 15 minutes) and the amount of used power of the electricity supplier transaction maximum demand electricity meter 291, and outputs it in pulses; A main control unit 212 for calculating the amount of power used from the pulse signal, monitoring the passage of a specific time, and generating a control signal for cutting off or supplying power to the load as necessary; An input unit 213 for allowing a user to select a driving mode; And a switching unit 214 to which the existing independent maximum power control device 299 is connected to control the power load. In FIG. 4, in addition to the above components, power is cut off through a relay RY and a remote communication line 3 (power supply line or serial communication line, etc.) opened or shorted by a control signal of the supply-demand type maximum power manager 210. Alternatively, the remote control terminal 204 which receives the control data for the input, and the magnetic switches 206 ₁ ,..., 206 opened or shorted according to the output signals of the relay RY and the remote control terminal 204. _N ), a customer self-managing computer 295 capable of transmitting and receiving data with the main controller 212 and performing necessary operations and displays as necessary, and a printer 296 capable of outputting necessary data are also shown. It is.

FIG. 5 illustrates the above-described switching unit 214 to enable power control of the existing maximum power management device in more detail. The switching unit 214 controls the control signal of the existing maximum power management device 299. It is possible not only to connect to the control output terminals O ₁ , O ₂ ,... O _M of the supply-demand type maximum power manager 210, but also by the control of the main controller 212. It consists of a set of switches 214 ₁ , 214 ₂ , ... 214 _{M that} can connect the power control signal to the output stages O ₁ , O ₂ ,... O _M , respectively.

FIG. 6 is a detailed block diagram of the power concentration management unit 110 of FIG. 3. The power concentration management unit 110 is a server that is responsible for operations related to a power usage situation and target power management of a customer and is responsible for processing related databases. Computer 111; A communication concentrator 120 for processing one-to-one communication with a customer-supplied interlock type maximum power manager 210 to transfer data to the server computer 111; Displayed on the CRT suyongga power management status in a graphical and printing client computer (112 _1, 112 _2, ...) and to the printer (113 _1, 113 _2, ...); A power management status panel (Mosaic Graphic Panel) 114 which clearly shows important power management data (a customer target power, total used power, and a customer operation status) at a glance; A situation plate driver 115 for driving the situation plate 114; And a local area network (LAN) 119 connecting the communication centralizer 120, the server computer 111, the client computers 112 ₁ , 112 ₂ ,.

FIG. 7 is a detailed block diagram of the communication concentrator 120 of FIG. 6, wherein the communication concentrator 120 is a switch line or dedicated line modem 123 ₁ , 123 ₂ , which is mounted more than the maximum number of power managers. ...)field; A multi-channel serial input / output unit 122 ₁ , 122 ₂ ,..., Which allocates a certain number of the modems 123 ₁ , 123 ₂ ,... A communication connection unit 124 connected to the local area communication network 119 to perform data exchange; And data transmitted from the multi-channel serial input / output unit 122 ₁ , 122 ₂ ,..., To the server computer 111 through the communication connection unit 124 and input through the communication connection unit 124. And a central processing unit 121 which selects and transmits the multi-channel serial input / output unit 122 ₁ , 122 ₂ ,... That manages a modem corresponding to a destination. ) Is ported and operated with dedicated multi-tasking operation software that processes multiple input and output data in real time.

FIG. 8A illustrates an example of an operation period and an operation mode designated by the power supply / operation type maximum power manager 210 from the power concentration management unit 110, and (b) shows a remote control command. It is a schematic of how to respond when received.

FIG. 9 is a flowchart illustrating a method of managing the maximum power in the power management mode in which the supply-demand interlock type maximum power manager 210 is linked. Hereinafter, the present invention will be described with reference to FIGS. 3 to 9. The operation of one embodiment will be described in detail.

First, a customer using the supply-demand type maximum power manager 210 contracts the supply-demand interlocking target power and the independent driving target power with the power supplier in advance. At this time, it is possible to contract the supply-demand operation time, and if necessary, not only the designated operation period but also the variable operation period. The contracted supply / demand target power is decided to be determined within a certain allowable range compared to the target power set by the customer. Of course, if the power used exceeds the set target power, the priority to cut off the power load and the cut-off time by load should be determined by considering the effect of the customer on productivity.

After the target power is set as described above (S10), through the input unit 213 of FIG. 4, the self-set target power value is input and the synchronous connection unit 211 of the supply-demand type maximum power manager 210 is a power supply company. By recognizing the movement of the indicator of the maximum demand electricity meter 291 for trading (S11), the main control unit 212 can operate power control of the existing maximum power management device 299. If it is determined by the data directly input from the customer (S12) and the existing maximum power management device (299) is not used, the input event is processed to process the input event (S15). When the maximum power management device 299 is set to be used, the main control unit 212 maintains a state of waiting for a command transmitted from the power concentration management unit 110 through the communication network 190 without any operation (S13). )

When the 'reporting time (1 minute) elapsed' event occurs in the input event standby state (S15) (S20) through the modem 205 and the communication network 190 to the power centralized management unit 110 online to the customer power information, etc. Transmit (S21) and enter the input event standby state (S15) again. In the standby state (S15), when the reset signal received by the predetermined request from the synchronization connection unit 211 (S30), the main control unit 212 calculates the input power consumption and at the same time the amount of power received so far The predicted power value is calculated from the trend (S31) and the magnitude of the predicted power value and the set target power value are compared. (S32) If the predicted power value exceeds the target power value, it is input from the customer. Select a specific power load among the power loads (209 ₁ , ... 209 _N ) according to the priority, and directly control the corresponding relay (RY) to select the corresponding magnetic switch (206 ₁ , ..., 206 _N ). Open or send power cutoff control data to the remote control terminal 204 via the telecommunication line 3 so that the remote control terminal 204 can open the corresponding magnetic switch 206 ₁ ,..., 206 _N. the power load to block the power supplied to the (209 _1, ... 209 _N) If it is (S33) predicted power values do not exceed the target power value to make a display of "receiving the remote control command '. (S34)

If the indication of 'remote control command reception' is displayed, the display is canceled (S35), the target power is newly set (S42), the driving time end timer is driven (S43), and the current maximum power management device (299) It is determined whether the power management is in operation (S44) and accordingly controls the switching unit 214 to switch the control signal (S45) and then proceeds to the input event standby state (S15). This flow is operated in a normal response to the remote control command of the power concentration management unit 110 will be described in more detail below.

When receiving the remote control command from the power concentration management unit 110 through the communication network 190 in the standby state (S15) (S40) by reading a new target power value and operation period and time transmitted with the remote control command After the operation time table is created (S41), the set response method is checked. (S46) When the response method is confirmed as the instantaneous response, the main control unit 212 instructs the synchronous connection unit 211 to specify the current specified demand time limit. At the end of the process, a new designated demand time limit is independently processed regardless of the indicator specified by the maximum demand electricity meter 291 for the electricity supplier transaction, and accordingly, a signal corresponding to the used power is output (S47). The new specified demand time limit may be set in advance by the power supplier in advance with the power supplier, but may be preferably transmitted at a specific value according to the needs of the power supplier. And supply-linked maximum power manager is to be used to receive this value. In this way, the designated demand time limit is set remotely, and the new specified demand time limit is shorter than the existing specified demand time limit according to an urgent situation (assuming 10 minutes in FIG. 8B). It is possible to manage the maximum power more efficiently if it is transmitted from the power supplier to the supply and demand interlock type maximum power manager. (The shorter the required time limit and the lower the target power as the specified demand time is shortened. Power management becomes more granular and stringent, making maximum power management even more certain.)

After the step S47 is completed, the target power value used for the control of the maximum power power is reset to a new value that has been transmitted (S42), and the driving time end timer according to the operation timetable is driven (S43). It is determined whether the power management by the management device 299 is in operation (S44) and if so, by controlling the switching unit 214 control output stage (O ₁ , O ₂ ,. .O _M ) is transferred from the control signal of the existing maximum power management device (299) to the control signal of the main control unit (212) (S45) and proceeds to the input event standby state (S15), and the existing maximum power management device If the power management by (299) is not in operation immediately proceeds to the input event standby state (S15).

On the other hand, when receiving the remote control command from the power concentration management unit 110 in the command standby state (S13) the same as the flow (S41, S46, ...) according to the remote control command reception (S40) described above The operation is made.

If it is confirmed that the normal response is set in the checking step (S46), the main control unit 212 performs only the 'remote control command reception' display (S48) and enters the standby state (S15). As described above, the operation according to the normal response method is confirmed at the reset time point S30 designated by the predetermined request (S34), and the operation according thereto is performed.

(B) of FIG. 8 shows the two response methods in more detail. (B) of FIG. 8 shows a case where the remote control command is received 5 minutes after the end of the first designated demand time limit when the designated demand time limit is set to 15 minutes. As shown in the instantaneous response mode of FIG. 8 (b), upon receipt of a remote control command, an independent designated demand time limit which is not synchronized with the maximum demand electricity meter 291 for a utility supply transaction (the independent specified demand time limit is 15 A value of less than a minute-in FIG. 8 (b) is assumed to be 10 minutes in advance or remotely. The power consumption is then input to the main controller 212. In case of the demand time limit, it ends after 30 minutes, but the independent designated demand time period ends after the new designated demand time.) In contrast, in the normal response mode, only the new target power value is changed and the specified demand time limit is still synchronized. The power consumption value is calculated accordingly.

The instantaneous response and the normal response may be determined by the customer, but may be remotely determined by the power concentration management unit 110.

When the event of terminating the remote control operation time end timer occurs in the input event standby state (S15) (S60), the value of the target power is set according to the original target power value (independent target power value) before the remote control command and the command response method. After restoring the specified demand time to its original value (S61), it is determined whether there is time left to operate by the remote control target from the operation timetable created at the time of receiving the remote control command (S62). The time required until the time is calculated to drive the operation time start timer (S63) and proceeds to the input event standby state (S15). If there is no time left to operate by remote control, it is determined whether the power management by the existing maximum power management device 299 should be operated (S64), and if so, the control unit 214 controls the control signal output stage (O). ₁ , O ₂ , ... O _M ) is retransmitted to the control signal of the existing maximum power management device (299) (S65) and proceeds to the input event standby state (S15) and the existing maximum power management device (299) If it is not necessary to operate by) immediately proceeds to the input event standby state (S15).

When the end event of the operation time start timer occurs in the input event standby state (S15) (S50), the main controller 212 replaces the current target power value with the target power value in the operation time table (S42). Proceed to (S43, S44 ...).

On the other hand, in the electric power concentration management unit 110 communication concentrator 120 is a multi-channel serial input-output (122 _1, 122 _2, ...) a plurality of switched line or leased line modem (123 _1, 123 _2, to control. Power management data transmitted through the ..) input to the server computer 111 to the trend and prediction of the power use, and in the case of the power data of the main consumer to transmit the situation board driver 115 to the power management situation board (114). Under the above-described monitoring, if the current demand situation is continued, the server computer 111 causes the power supply and supply abnormality to occur after a certain time, and promptly displays it on the status board 114 and, if necessary, the schedule ranking under the input of an administrator. By designating the power receiver by the remote control command and the required operating time and the target power, etc. are transmitted to the communication concentrator 120. The communication concentrator 120 transmits the received command data to the supply-demanded maximum power manager 210 of each designated recipient, and the supply-demanded-type maximum power manager 210 receiving the remote control command is the ninth described above. According to the step of FIG. 1, the power load is controlled under the newly set target power.

Unlike the immediate execution of the above-described remote control command, the interlocking type maximum power manager 210 determines whether to execute the command after receiving the command, and if the command can be executed, the response message power. It may further include the step of sending to the centralized management unit 110, the server computer 111 of the power centralized management unit 110 at this time does not transmit the remote control command and the operating time and the target power at the same time only the remote control command If there is a response from the power supply interlocking type maximum power manager 210 after waiting for transmission, a method of transmitting a remote control operation time and target power by time and the like by the new target power may be selected.

The above-described power supply-demanded online interlocked maximum power management device is provided with a plurality of power concentration management unit 110 to limit the power concentration management unit 110 to a specific region and to centrally manage power consumption of other regions. Install a central power management unit 100 to manage the overall power central management unit 110, they are connected to each other online to the communication network 190 or a dedicated line between the central power management unit 100 and the power central management unit 110. By being connected online, the central power management unit 100 instructs each power concentration management unit 110 a target value of the maximum power for each region, and each power concentration management unit 110 as described above in the target power for each region as described above. It may be implemented as a layer-specific maximum power management device for remotely controlling the maximum power of the.

Power supply online linked-type maximum power management method and its management apparatus according to the present invention configured and acts as described above, remotely up to the power supply company to be useful for the power supply situation of large power loads that can temporarily cut off power and high-voltage consumers By directly managing the electricity used, not only can the nation's power supply and demand be operated as a whole and efficiently, but also in the event of a power supply failure, the power supply company can directly manage the power supply and supply. It is a very useful invention that can be expanded and distributed, thus reducing enormous investment in power plant construction and power equipment expansion, and also preventing environmental pollution caused by combustion of power fuel derived from power generation.

Claims (11)

Transmitting data on operation conditions such as power usage status and power usage management means of the customer to the power concentration management means of the power supplier through an on-line communication network; Monitoring and predicting an overall maximum power supply and demand situation using data transmitted from each customer; Determining whether it is necessary to adjust the maximum power of a particular consumer; If it is determined that it is necessary to adjust the maximum power of a specific customer, transmitting a remote control command, a target power, and an operation time for the customer determined in the determining step through a communication network connected online; The consumer's maximum power management means storing the transmitted target power and responding to the remote control command; And controlling the maximum power according to the set contents. The method of claim 1, wherein the step of responding to the command comprises: receiving the command data and maintaining a currently set target power for a predetermined demand time limit in progress in synchronization with a maximum demand electricity meter for a power supplier transaction; And replacing the target power with the received value when the specified time limit is completed. The method of claim 1, wherein the transmitting of the remote control command or the like further transmits a new designated demand time limit in addition to the remote control command, the target power, and the operation time, and responding to the command comprises: immediately receiving the command data. Initializing the specified demand time limit while replacing the current target power value; And advancing the received new designated demand time limit, wherein the new designated demand time limit is shorter than the on-going specified demand time limit. The method according to claim 1, 2 or 3, wherein the monitoring and predicting of the maximum power supply and demand situation is performed by checking the trend of the maximum power used by the consumer at least every 30 seconds to thereby identify the sudden increase in the power usage of the consumer. And the step of determining whether to adjust the maximum power comprises determining whether to adjust the maximum power to the customer corresponding to the priority according to the priority of the customer divided into a plurality of steps. Power supply on-line linked maximum power management method characterized in that it comprises a. Communication means for transmitting and receiving data through a communication network; Input means for setting a power management mode and the like interoperating with the independent power management mode; And receiving the remote control command and the target power through the communication means, performing power control of the external power load device according to the set target power, and simultaneously transmitting the measured power usage and operation conditions through the communication means. Main control means for monitoring the progress of the supply-demand interlocked maximum power management means comprising a; At the same time, the maximum power of a certain area, comprising a communication intensive means capable of connecting and communicating with the communication means of the plurality of supply-demanded maximum power management means, and monitors the target power of the supply-demanded maximum power management means Power intensive management means for remotely instructing; And a communication network to which the communication means and the communication intensive means are connected to enable data exchange. The target set according to claim 5, wherein, when the main control means is set to an interlocked power management mode, when the remote control command data is received through the communication means, the target currently set during the designated demand time period in synchronization with the maximum demand electricity meter for the power supplier transaction. After maintaining the power, the specified demand time limit is closed, and at the same time, the new power supply value is changed to a new target power value, and the power supply online interlocking type is controlled according to the specified demand time limit of the maximum electricity meter for trading. Maximum power management device. 6. The method of claim 5, wherein when the main control means is set to an interlocked power management mode, upon receiving the remote control command data through the communication means, the current target power value is immediately replaced and at the same time the specified demand time limit is initialized. Proceed the specified demand time limit to control the maximum power irrespective of the specified demand time limit of the maximum demand electricity meter for trading, wherein the new specified demand time limit is shorter than the specified demand time in progress Device. The main control means according to claim 6 or 7, wherein, when the remote control operation time by the remote control operation command ends, the main power unit restores the maximum power by restoring the target power before receiving the remote control command to its own target power and the specified demand time limit. Power supply on-line linked maximum power management device characterized in that the control. The power supply interlocking type maximum power management means according to claim 5, 6 or 7, wherein the load control output signal of the existing maximum power management device pre-installed in the consumer and the load control signal of the main control means. And a switching means for selectively connecting to the control signal output terminal of the power supply-linked maximum power management means by the control of the main control means. 8. The system of claim 5, 6 or 7, wherein the power intensive management means comprises: a server computer which is in charge of processing a power usage situation of a customer, a target power for managing and a related database; A client computer that displays the power management status of the customer and prints it as needed; Power management status board showing key data necessary for maximum power management at a glance; Situation board driving means for driving the power management situation board; And a local communication network for exchanging data between the communication intensive means, the server computer, the client computer, and the status board driving means. Communication means for transmitting and receiving data through the communication network, input means for setting the power management mode linked to the independent power management mode, and the like, and control commands and target power are received through the communication means to the set target power. In accordance with the power control of the external power load device and at the same time transmits the measured power use and operation status through the communication means, including the main control means for monitoring the progress of a certain time, the supply-demand interlocking type maximum power management Way; At the same time, the maximum power of the fixed supply and demand interlocked type maximum power management means configured to monitor the maximum power of the predetermined fixed area, including a communication concentrated means capable of communication by connecting to the communication means of the plurality of supply and demand interlocked maximum power management means of a certain area. Power intensive management means for remotely instructing target power; Including the central communication means connected to the communication intensive means of the plurality of power intensive management means connected to the area, and connected to the power management means for each region online to report the power supply situation by region and the regional targets to the power intensive management means Central power management means for directing power; And a communication network to which the communication means and the communication intensive means are connected to enable data exchange.