JP6457635B2 - LFC management apparatus, LFC system, method and program - Google Patents

Description

  Embodiments described herein relate generally to an LFC management apparatus, an LFC system, a method, and a program.

Smart grids that intelligently manage electrical energy while introducing renewable energy such as solar and wind power to combat global warming are expected to be promoted in the future.
However, there is a concern about the lack of system frequency adjustment capability, that is, LFC adjustment capability, as a problem when renewable energy is introduced in large quantities due to unstable output. This is because when the ratio of renewable energy to the power source increases, the ratio of power sources with LFC adjustment power such as thermal power generation and hydroelectric power generation decreases relatively, and the ratio of renewable energy can be increased to a certain extent. Because it disappears.

  As means for solving this problem, for example, it has been proposed to introduce a storage battery to cause the storage battery to absorb the output fluctuation of the renewable energy or to absorb the imbalance between the demand and supply of the system.

JP 2012-016077 A JP 2009-213240 A JP 2001-037085 A

By the way, the introduction of renewable energy to build a smart grid has been actively studied in recent years and is expected to increase in the future.
However, when building a power system by introducing new renewable energy, or when introducing renewable energy to some power systems and maintaining the frequency of some of those systems separately from this system, etc. However, it is necessary to construct an LFC system having a function of maintaining the frequency of the system (LFC function), which may increase the construction cost and the maintenance cost.
The present invention has been made in view of the above, and an object of the present invention is to provide an LFC management device, an LFC system, a method, and a program capable of providing an LFC function to a plurality of power systems (systems). It is said.

The LFC management device manages LFC control for each of a plurality of power systems having at least one of a generator and a storage battery system.
At this time, input data, system characteristic data, control data, and output data corresponding to each of the plurality of power systems are stored in the data recording unit in an updatable manner.
As a result, the plurality of input units receive measurement data from each of the plurality of power systems based on the input data for each system.
The plurality of calculation units calculate supply and demand imbalance amounts based on system characteristic data and measurement data for each system.
The plurality of distribution units, the ratio of the margin amount to the output upper and lower limit values of the generator constituting the plurality of power systems, or the ratio of the margin amount to the discharge power upper limit value / charge power upper limit value of the storage battery system, and Based on the control data for each power system, the measurement data, and the supply and demand imbalance amount, distribution of the supply and demand imbalance amount to at least one of the generator and the storage battery system is calculated.
The plurality of output units output data for controlling the generator or the storage battery system based on the output data for each system and the allocated supply-demand imbalance amount.

FIG. 1 is a schematic configuration block diagram of a multi-system LFC system according to the first embodiment. FIG. 2 is a functional block diagram of the multi-system LFC system. FIG. 3 is a functional block diagram (before addition) showing the configuration of the multi-system LFC system of the second embodiment. FIG. 4 is a functional block diagram (after addition) showing the configuration of the multi-system LFC system of the second embodiment. FIG. 5 is a functional block diagram showing the configuration of the multi-system LFC system according to the third embodiment of the present invention. FIG. 6 is a schematic configuration block diagram of the multi-system LFC system of the fourth embodiment. FIG. 7 is a process flowchart of the fourth embodiment. FIG. 8 is an explanatory diagram of a data recording example of the setting data recording unit of the fifth embodiment.

Embodiments of the present invention will be specifically described below with reference to the drawings.
[1] First Embodiment FIG. 1 is a schematic configuration block diagram of a multi-system LFC system according to a first embodiment.
The LFC system 100 for a plurality of systems according to the first embodiment can be broadly divided into a plurality of power systems (systems) 101-1 to 101-x having a storage battery system, a LFC management device 102 for a plurality of systems, and a power system 101. -1 to 101-x and the LFC management apparatus 102 are connected to each other so that they can communicate with each other.
Here, since the power systems 101-1 to 101-x have the same configuration, the power system 101-1 will be described as an example.

FIG. 2 is a functional block diagram of the multi-system LFC system.
The LFC management apparatus 102 includes input units 121-1 to 121-x that receive measurement data from the power systems 101-1 to 101-x, and a calculation unit 122-1 that calculates a supply and demand imbalance amount based on the measurement data. To 122-x and distribution units 123-1 to 123- that calculate supply and demand imbalance amounts to be distributed to one or more generators and one or more storage batteries constituting power systems 101-1 to 101-x An output unit that outputs data for controlling one or more generators and one or more storage batteries constituting the power systems 101-1 to 101-x based on x and the allocated supply-demand imbalance amount 124-1 to 124-x, input data 131-1 to 131-x, system characteristic data 132-1 to 132-x, control data 133-1 to 133-x, and output data 134-1 to 1 Advance and stored data recording unit 125 the 4-x, and a.

  In this case, the input data 131-1 to 131-x, the system characteristic data 132-1 to 132-x, the control data 133-1 to 133-x, and the output data 134-1 to 134-x are data. It is assumed that the recording unit 125 is set before starting LFC for each of the power systems 101-1 to 101-x (systems) by an external device (not shown).

Next, the operation of the first embodiment will be described.
First, in the input units 121-1, 121-2,..., 121-x, frequency data 113-1 corresponding to measured values of frequencies from the measurement points set in advance in the power systems 101-1 to 101-x, respectively. , 113-2,..., 113-x, interconnection current data 114-11 to 114-1k, 114-21 to 114-2k,..., 114-x1 to 114-xk, power generation corresponding to the measured values of the power flow Generator output data 115-11 to 115-1m, 115-21 to 115-2m, ..., 115-x1 to 115-xm corresponding to the measured values of the machine output, the storage battery output of the storage battery constituting the storage battery system Storage battery output data 116-11 to 116-1n, 116-21 to 116-2n,..., 116-x1 to 116-xn corresponding to the measurement values are input as uplink data.

  The measured values of the measurement points of the power systems 101-1 to 101-x are generally measured by the communication networks 103-1 to 103-103 by a communication device represented by a remote monitoring control device (TC) or a cyclic digital information transmission device (CDT). , 121 -x when the input units 121-1, 121-2,..., 121 -x input from the communication device, are input data 131-1, 131-2. ,... 131-x can be used to identify each measured value. That is, in the input data 131-1, 131-2, ..., 131-x, which data among communication data sent from any of the transmission sources corresponds to each uplink data. Contains data to show.

The calculation units 122-1 to 122-x are respectively the frequency data 113-1, 113-1,..., 113- of the uplink information input by the input units 121-1, 121-2,. The supply and demand imbalance amount is calculated based on at least one of x or interconnected power flow data 114-11 to 114-1k, 114-21 to 114-2k, ..., 114-x1 to 114-xk. .
For example, the calculation unit 122-1 calculates the supply and demand imbalance amount of the power grid 101-1 as K 1 · (frequency corresponding to the frequency data 113-1 -reference frequency) + K 2 · Σ (interconnection line power flow plan value 1 i -continuous). Calculation is performed based on the system flow data 114-1i) (i = 1 to k). This supply and demand imbalance amount is called regional requirement amount in Japan, and is called Area Control Error (however, the sign is opposite to the regional requirement amount) in the United States.

Here, when calculating the supply and demand imbalance amount, there may be a case where there is no interconnection line, a case where no interconnection line is considered, or a case where frequency is not taken into consideration, depending on the system (power system). It doesn't matter.
The constant K1 and the constant K2 in the above-described formula for calculating the supply and demand imbalance amount are constants that depend on the grid (power grid). For example, taking the case of the power system 101-1 as an example, it is stored as system characteristic data 132-1. For this reason, the calculation unit 122-1 obtains the constant K1 and the constant K2 of the power system 101-1 with reference to the system characteristic data 132-1 when calculating the supply and demand imbalance amount.
Similarly, the calculation units 122-2,..., And the calculation unit 122-x refer to the system characteristic data 132-1,.
In the above description, the case where the number of interconnecting power flows of the power systems 101-1 to 101-x is all k has been described, but for each system, that is, for each of the power systems 101-1 to 101-x, The number may be different.

  The distribution units 123-1 to 123-x are the supply / demand imbalance amounts calculated by the corresponding calculation units 122-1 to 122-x and the generators input via the corresponding input units 121-1 to 121-x. Output data 115-11 to 115-1m, 115-21 to 115-2m, ..., 115x1 to 115xm, or storage battery output data 116-11 to 116-1n, 116-21 to 115-2n, ..., 115x1 to 115xn Generator control amount data 117-11 to 117-1m, 117-21 to 117-2m, ..., 117-x1 to 117-xm, or storage battery control amount data 118- based on at least one of them. At least one is calculated among 11-118-1n, 118-21-118-2n, ..., 118-x1-118-xn.

In this case, various methods are conceivable as the calculation (calculation) method of the distribution units 123-1 to 123-x, but any of the conceivable methods can be adopted.
As a typical method, there is a method of proportionally allocating in accordance with the output upper / lower limit value of each generator or storage battery or the surplus amount to the discharge power upper limit value / charge power upper limit value. More specifically, when the supply and demand imbalance amount indicates a power shortage, the margin from each generator output to the output upper limit value or from each storage battery output to the discharge power upper limit value is calculated and proportional to the margin amount. A method of allocation is possible.
In these cases, in order to realize appropriate control, the control amount may be corrected by multiplying the control amount of each generator and / or storage battery by a gain constant as necessary.
The generators and storage battery upper and lower limit values, gain constants, and the like used when the distribution units 123-1 to 123-x calculate the control amount are stored as control data 133-1 to 133-x.
For this reason, when the distribution units 123-1 to 123-x calculate the control amount, the upper and lower limit values of the generator and the storage battery, the gain constant, and the like are referred to the control data 133-1,. To get to.
Here, the number of generators and storage batteries of the power systems 101-1 to 101-x has been described as the same number for each of the m systems and the n systems and the power systems 101-1 to 101-x. It doesn't matter if they are different.

  The output units 124-1, 124-2, ..., 124-x are the generator control amount data 117-11 to 117-1m calculated and output by the distribution units 123-1, 123-2, ..., 123-x. , 17-21 to 117-2m, ..., 117-x1 to 117-xm, or storage battery control amount data 118-11 to 181-1n, 118-21 to 118-2n, ..., 118-x1 to 118-xn At least one of them is sent to the control points of the power systems 101-1 to 101-x as downlink information.

  By the way, the downlink information sent to the control points of the power systems 101-1 to 101-x is generally transmitted from the LFC management apparatus by a communication apparatus represented by a remote monitoring control apparatus (TC) or a cyclic digital information transmission apparatus (CDT). In order to be sent to the power plant or substation, the output units 124a, 124-2,..., 124-x refer to the output data 134-1, 134-2,. The data can be output to the corresponding communication device. That is, the output data 134-1, 134-2,..., 134-x includes data indicating which data in the communication data to be sent to each piece of downlink information.

Generally, input units 121-1, 121-2, ..., 121-x, calculation units 122-1, 122-2, ..., 122-x, distribution units 123-1, 123-2, ..., 123-x, output The units 124-1, 124-2b,..., 124-x are configured to periodically operate at regular time intervals (for example, several seconds).
In this way, the LFC management apparatus of the multi-system LFC system simultaneously maintains the frequencies of the power systems 101-1 to 101-x in parallel.

  As described above, according to the multi-system LFC system 100 of the first embodiment, there is no need to construct an LFC system for each of the power systems (systems) 101-1 to 101 -x, and the plurality of power systems 101. Since it is only necessary to provide one LFC management device 102 for multiple systems for -1 to 101-x (system), in addition to the merit that it can be built economically, centralized management can be performed, so the number of maintenance personnel is suppressed. As well as the advantage of being economically maintainable.

[2] Second Embodiment In the first embodiment, the case where a system (power system) is determined in advance has been described. However, in the second embodiment, a system (power system) is used in one LFC management device. This is an embodiment in which can be added.
FIG. 3 is a functional block diagram (before addition) showing the configuration of the multi-system LFC system of the second embodiment.
FIG. 4 is a functional block diagram (after addition) showing the configuration of the multi-system LFC system of the second embodiment.

  The multi-system LFC system 100A of the second embodiment has a configuration excluding a configuration corresponding to the power system 101-2 from the multi-system LFC system 1 of the first embodiment, a setting unit 141, a setting data recording unit 142, The data update unit 143 and the management unit 144 are added.

  The setting unit 141 is set as input data 131-1 to 131-x, system characteristic data 132-1 to 132-x, control data 133-1 to 133-x, and output data 134-1 to 134-x. Enter the setting data to do.

  The setting data recording unit 142 includes input data 131-1 to 131-x, system characteristic data 132-1 to 132-x, control data 133-1 to 133-x, and output data 134-1 to 134-x. Setting data for setting as is stored.

  The data update unit 143 is input by the setting unit 141 and based on the setting data stored in the setting data recording unit 142, the input data 131-2, the system characteristic data 132-2, the control data 133-2, and the output data Data update processing for adding the data 134-2 to the data recording unit 125 and storing it is performed.

  The management unit 144 includes input units 121-1, 121-3 (not shown), ..., 121-x, calculation units 122-1, 122-3 (not shown), ..., 122-x, a distribution unit 123. -1, 123-2,..., 123-x, and output units 124-1, 124-3 (not shown),.

  Here, a registration procedure when the power system 101-2 is newly controlled by the multi-system LFC management apparatus 102 configuring the multi-system LFC system 100A will be described.

  FIG. 3 shows a state in which the LFC management device 102 of the multi-system LFC system 100A controls the power system 101-1 and the power system 101-x.

  In the state of FIG. 3, the setting unit 141 externally inputs data 131-2, system characteristic data 132-2, control data 133-2, and output necessary for maintaining the frequency of the new power system 101-2. The setting of the data 134-2 is received and recorded in the setting data recording unit 142.

  As a result, the setting data recording unit 142 receives the input data 131-2, the system characteristic data 132-2, the control data 133-2, and the output of the power system 101-2 that is a new system input from the setting unit 141. Data for generating the data for use 134-2 is stored.

  When the management unit 144 receives an instruction from the outside to newly set the power system 101-2 as an LFC control target, the management unit 144 instructs the data update unit 143 to input data 131-2 of the power system 101-2 that is a new system. Instruct to create system characteristic data 132-2, control data 133-2, and output data 134-2.

  In addition, the management unit 144 generates an input unit 121-2, a calculation unit 122-2, a distribution unit 123-2, and an output unit 124-2 for the power system 101-2 that is a new system. However, at this time, the input unit 121-2, the calculation unit 122-2, the distribution unit 123-2, and the output unit 124-2 are not activated.

  The data update unit 143 creates input data 131-2, system characteristic data 132-2, control data 133-2, and output data 134-2 for the power system 101-2 as a new system from the management unit 144. When the instruction is received, the input data 131-2, the system characteristic data 132-2, the control data 133-2, and the output data 134-2 of the power system 101-2 are generated, and the contents are recorded as setting data. The contents are the same as the contents of the input data 131-2, the system characteristic data 132-2, the control data 133-2, and the output data 134-2 of the power system 101-2 recorded in the unit 142.

  Then, after the data updating unit 143 creates the contents of the input data 131-2, the system characteristic data 132-2, the control data 133-2, and the output data 134-2 of the power system 101-2, the management unit 144 activates the input unit 121-2, the calculation unit 122-2, the distribution unit 123-2, and the output unit 124-2 for the previously generated power system 101-2.

  As a result, the activated input unit 121-2, calculation unit 122-2, distribution unit 123-2, and output unit 124-2 operate periodically thereafter, and the multi-system LFC system 100A is shown in FIG. It becomes a state.

  Thereafter, in the LFC management apparatus 102 of the multi-system LFC system 100A, the input units 121-1 to 121-x, the calculation units 122-1 to 122-x, the distribution units 123-1 to 123- shown in FIG. x and the output units 124-1 to 124-x move periodically every predetermined time (for example, several seconds), and perform the same operation as the multi-system LFC system 100 of the first embodiment. It becomes.

[2.1] When changing LFC control conditions The above description is for a case where a power system 101-2 is newly added.

By the way, in an actual power system, for maintenance or system update, the generator or storage battery is replaced, added, temporarily removed, or a sensor for performing various measurements is replaced or added. Cases can arise.
Therefore, in the following, an operation when changing the LFC control condition of the already operating power system 101-1 will be described.

  Specifically, the frequency data 113-1 of the electric power system 101-1, the interconnection currents 114-11 to 114-1k, the generator output data 115-11 to 115-1m, or the storage battery output data 116-11 to 115- When there is an addition or change of a measurement point for acquiring 1n, or addition of a control point that is an output destination of generator control amount data 117-11 to 117-1m or storage battery control amount data 118-11 to 118-1n, The operation when there is a change will be described.

  In FIG. 3, the setting unit 141 includes input data 131-1, system characteristic data 132-1, and control data necessary for maintaining the frequency of the already registered power system 101-1. New setting data for changing the setting is input as 133-1 and output data 134-1. Here, for convenience of explanation, all of input data 131-1, system characteristic data 131-1, control data 133-1 and output data 134-1 are input, but only data that needs to be changed. You can enter.

  As a result, the setting data recording unit 142 receives the input data 131-1, the system characteristic data 132-1, the control data 133-1 and the output of the power system 101-1 to be newly set input from the setting unit 141. Data for generating the data 134-1 is stored.

  Upon receiving an instruction to update data corresponding to the power system 101-1, the management unit 144 updates the input data 131-1, the system characteristic data 132-1, the control data 133-1 and the output data 134-1. Prior to this, the input unit 121-1, the calculation unit 122-1, the distribution unit 123-1 and the output unit 124-1 are temporarily stopped so as not to perform a periodic operation (normal operation). Instructing the data updating unit 143 to create new input data 131-1, system characteristic data 132-1, control data 133-1 and output data 134-1 corresponding to the power system 101-1. To do.

  Subsequently, the data updating unit 143 creates new input data 131-1, power system characteristic data 132-1, control data 133-1 and output data 134-1 for the power system 101-1, from the management unit 144. When the instruction is received, the contents of the input data 131-1, the system characteristic data 132-1, the control data 133-1 and the output data 134-1 of the power system 101-1 are recorded in the setting data recording unit 142. The input data 131-1, the system characteristic data 132-1, the control data 133-1, and the output data 134-1 are updated to the same contents.

  Then, after the data update unit 143 creates the contents of the input data 131-1, the system characteristic data 132-1, the control data 133-1 and the output data 134-1 of the power system 101-1, the management unit 144 activates the input unit 121-1, the calculation unit 122-1, the distribution unit 123-1, and the output unit 124-1 for the power system 101-1 that has previously stopped.

  As a result, the input unit 121-1, the calculation unit 122-1, the distribution unit 123-1, and the output unit 124-1 activated with the updated content operate periodically thereafter, and are the same as in the first embodiment. Perform the action.

[2.2] When Stopping LFC Control Next, the operation when stopping LFC control in a specific system (power system) will be described.

  Specifically, in the multi-system LFC system 100A shown in FIG. 4, the LFC control of the power system 101-2 is stopped from the situation where the LFC control of the power systems 101-1 to 101-x is performed. Similar to the initial state of the multi-system LFC system 100A shown in FIG. 3, the operation until the LFC control is performed on the power systems 101-1 and 101-3 to 101-x will be described.

  In FIG. 4, the setting unit 141 includes input data 131-2, system characteristic data 132-2, and control data for the power system 101-2 necessary for maintaining the frequency of the already registered power system 101-2. Accept deletion as 133-2 and output data 134-2, and input a deletion instruction.

  Thereby, the setting data recording unit 142, based on the deletion instruction input from the setting unit 141, the input data 131-2, the system characteristic data 132-2, the control data 133-2, and the output for the power system 101-2. It is stored that the generation data of the data 134-2 has been deleted.

When the management unit 144 receives an instruction to exclude the power system 101-2 from the LFC control target, the input unit 121-2, the calculation unit 122-2, the distribution unit 123-2, and the output that have periodically moved to the time point The unit 124-2 is stopped and deleted.
Thereafter, the management unit 144 updates the input data 131-2, the system characteristic data 132-2, the control data 133-2, and the output data 134-2 of the power system 101-2 to the data update unit 143. Instruct to do.

  As a result, the data update unit 143 receives the input data 131-2, the system characteristic data 132-2, the control data 133-2, and the control data 133-2 recorded in the setting data recording unit 142 based on the instruction from the management unit 144. Although the contents of the output data 134-2 are to be updated, since the fact that these data have been deleted is recorded in the setting data recording unit 142, the input data 131-2, system The operation of deleting the characteristic data 132-2, the control data 133-2, and the output data 134-2 is performed.

  As a result, in the LFC management apparatus 102 of the multi-system LFC system 100A, the state shown in FIG. 3 is obtained, and the input units 121-1, 121-3 to 121-x, and the calculation units 122-1, 122-3 to 122- x, the distribution units 123-1, 123-3 to 123-x, and the output units 124-1, 124-3 to 124-x are configured to periodically move every predetermined time (for example, several seconds), The power systems 101-1 and 101-3 to 101-x perform the same operation as in the first embodiment.

[2.3] Effects of the Second Embodiment As described above, according to the second embodiment, a plurality of systems are subjected to LFC control, a new system is set as an LFC control target, or a system that is already an LFC control target. When there is an increase or decrease in generators or storage batteries, an increase or decrease in interconnection lines, or changes in system characteristics, it is possible to perform LFC control according to those changes, or exclude systems that are already subject to LFC control from LFC targets (Deleting) can be easily performed.

[3] Third Embodiment FIG. 5 is a functional block diagram showing the configuration of an LFC system for multiple systems according to a third embodiment of the present invention.

  The multi-system LFC system 100B of the third embodiment is different from the multi-system LFC system 100 of the first embodiment of FIG. 1 in that the input units 121-1 to 121-x constituting the LFC management apparatus 102. , Calculation unit 122-1 to 122-x, distribution unit 123-1 to 123-x, control status data recording unit 125-1 to 125-x for recording control status data of output units 124-1 to 124-x, Control status display units 135-1 to 135-x for displaying the control status on the display units 147-1 to 147-x based on the recording status of the control status data recording units 125-1 to 125-x, respectively. It is.

  In FIG. 5, the input units 121-1 to 121-x record the input uplink information in the control status data recording units 125-1 to 125-x, respectively. Similarly, the calculation units 122-1 to 122-x record the calculated supply and demand imbalance amounts in the control status data recording units 125-1 to 125-x, respectively. The distribution units 123-1 to 123-x record the calculated control amounts in the control status data recording units 125-1 to 125-x, respectively. The output units 124-1 to 124-x record the downlink information output by each of them in the control status data recording units 125-1 to 125-x.

  As a result, the control status display units 135-1 to 135-x display the control statuses on the display units 147-1 to 147-x based on the recording statuses of the control status data recording units 125-1 to 125-x, respectively. indicate.

  Therefore, according to the multi-system LFC system 100B of the third embodiment, for each of the power systems 101-1 to 101-x, while performing LFC control of a plurality of systems, that is, the power systems 101-1 to 101-x, Since the LFC control status can be displayed, the operator of the LFC management apparatus 102 can know the LFC control status for each of the power systems 101-1 to 101-x.

[4] Modifications of First to Third Embodiments In the above embodiments, the details of the communication networks 103-1 to 103-x have not been described, but some or all of the communication protocols are described. It can be an internet protocol.

  Conventionally, it is generally sent by a communication device represented by a remote monitoring control device (TC) or a cyclic digital information transmission device (CDT). In this case, various communication protocols are prepared for each communication device. Therefore, it was necessary to design a communication interface separately depending on the communication device to be connected.

  On the other hand, in this modification, in the multi-system LFC systems 100 to 100B, by adopting an Internet protocol as a communication protocol for uplink information or downlink information, the system can be constructed more easily. The degree of freedom of communication can be improved, and the system construction cost can be reduced.

  In this case, in order to perform secure HTTP communication, a communication protocol that can be encrypted is adopted, communication is performed after encryption, virtual private network (VPN) It is preferable to carry out via In order to suppress communication delay, encoding / decoding at the time of encryption is preferably performed by hardware rather than by software.

[5] Fourth Embodiment FIG. 6 is a schematic configuration block diagram of a multi-system LFC system according to a fourth embodiment.
In FIG. 6, the difference from the multi-system LFC system of the first to third embodiments is that the multi-system LFC system 100A is used via the LFC management apparatus 102 and the second communication network (for example, the Internet). The user terminal of a user (including a pre-contract user) is connected.
In addition, instead of the connected user terminal via the second communication network, a server is connected, or the LFC management apparatus 102 is connected via a local second communication network (including a case where connection is made with a connection cable). A user terminal may be connected.

  The multi-system LFC system 100A according to the fourth embodiment is roughly classified into a plurality of power systems 101-1 to 101-x, a multi-system LFC management device 102, and power systems 101-1 to 101-x. A plurality of user terminals 105 </ b> A to 105 </ b> C connected via the communication networks 103-1 to 103-3, the second communication network 104, and the second communication network 104 that connect the LFC management apparatus 102 so as to communicate with each other And.

  In the following description, processing at the time of new contract, contract revision, and contract termination for users (including pre-contract users) who use the multi-system LFC system 100A will be described.

FIG. 7 is a process flowchart of the fourth embodiment.
[5.1] At the time of a new contract First, a case where a user before contract makes a new contract will be described.
When applying to the LFC function provider who operates and manages the multi-system LFC system 100A for the use of the multi-system LFC system 100A, the site provided by the LFC function provider is, for example, the Internet The user terminal 105A is connected to the LFC management apparatus 102 via the constructed second communication network 104.

Then, the pre-contract user makes a new contract application for receiving the provision of the LFC function (step S1; contract step).
Thereby, the multi-system LFC system 100A determines whether the application content in the contract step is a new contract, a contract revision, or a contract end (step S2).

  In this case, since this is a new contract (step S1; new contract), in the second embodiment described above, the multi-system LFC is transmitted from the user terminal 105A in the same manner as when the power system 101-2 is newly added. Connect to the setting unit 141 of the system 100A.

  Then, using the user terminal 105A, data setting for using the LFC function for a new power system (new system) is performed on the setting unit 141 (step S3a).

  Specifically, using the user terminal 105 </ b> A, the setting unit 141 uses the LFC function for a new power system (new system) to input data necessary for maintaining the frequency corresponding to the new power system. The system characteristic data, control data, and output data settings are received and recorded in the setting data recording unit 142. As a result, the setting data recording unit 142 stores input data for the new power system, system characteristic data, control data, and output data generation data input from the setting unit 141.

Subsequently, the multi-system LFC system 100A generates LFC data for starting the LFC function in the new system (step S4a).
Specifically, upon receiving an instruction from the user terminal 105A that the power system is newly set as an LFC control target, the management unit 144 receives the data update unit 143 from the input data for the power system that is a new system. Instruct to create system characteristic data, control data and output data.

  In addition, the management unit 144 generates an input unit, a calculation unit, a distribution unit, and an output unit for a power system that is a new system, and sets the standby state without starting.

  When the data updating unit 143 receives an instruction from the management unit 144 to create input data, system characteristic data, control data, and output data for a power system that is a new system, the newly added power System input data, system characteristic data, control data, and output data are generated, and the contents are recorded in the setting data recording unit 142. Power system input data, system characteristic data, control data, and output The content is the same as the content of the business data.

Then, after the data updating unit 143 creates the contents of the power system input data, system characteristic data, control data, and output data, the management unit 144 includes the input unit for the previously generated power system, Starts the calculation unit, distribution unit, and output unit.
Thereby, the multi-system LFC system 100A shifts to an LFC execution step in which the LFC function is continuously performed in the new system (step S5a).
As a result, the activated input unit, calculation unit, distribution unit, and output unit periodically perform the same operation as that of the multiple-capacity LFC system 100 of the first embodiment.

[5.2] Contract Revision Next, a case where a contract user performs contract revision will be described.
When applying to the LFC function provider who operates and manages the multi-system LFC system 100A for a contract revision of the use of the multi-system LFC system 100A, the site provided by the LFC function provider, for example, The user terminal 105A connects to the LFC management apparatus 102 via the second communication network 104 constructed as the Internet.

Then, the contract user applies for contract revision (step S1; contract step).
Thereby, the LFC management apparatus 102 of the multi-system LFC system 100A determines whether the application content in the contract step is a new contract, contract revision, or contract termination (step S2).

In this case, since the contract is revised (step S2; contract revision), in the second embodiment described above, processing is performed as in the case of changing the LFC control conditions.
Then, using the user terminal 105A, the setting unit 141 is contracted as input data, system characteristic data, control data, and output data for the power system necessary for maintaining the frequency of the already registered power system. The process proceeds to a maintenance step for inputting new setting data for changing the content (setting) (step S3b).

As a result, the user terminal 105 </ b> A via the setting unit 141 can newly input a contract for revision as input data, system characteristic data, control data, and output data necessary for maintaining the frequency of the already registered power system. Enter the correct setting data.
The setting data recording unit 142 stores input data for the power system to be newly set, system characteristic data, control data, and output data generation data input from the setting unit 141.

  Subsequently, the multi-system LFC system 100A shifts to the LFC data switching step of switching the LFC data for realizing the LFC function in the existing system of the user corresponding to the user terminal 105A to switch the LFC data after the contract revision (step S4b).

  When the management unit 144 receives an update instruction (revision instruction) for data corresponding to the power system, the management unit 144 provides the data update unit 143 with new input data, system characteristic data, control data, and output corresponding to the power system. Instruct to create data.

  Subsequently, when the data updating unit 143 receives an instruction from the management unit 144 to create new input data, system characteristic data, control data, and output data for the existing power system, before the power system contract is revised. The corresponding input unit, calculation unit, distribution unit, and output unit are temporarily stopped, and then the contents of the power system input data, system characteristic data, control data, and output data are recorded in the setting data recording unit 142 The contents are updated to the same contents as the contents of the input data, system characteristic data, control data, and output data of the power system corresponding to the user who is making the contract revision.

  Then, after the data updating unit 143 creates the contents of the input data, system characteristic data, control data, and output data of the power system after the contract revision, the management unit 144 is in the suspended state after the contract revision The input unit, calculation unit, distribution unit, and output unit for the new power system are activated.

As a result, the LFC management apparatus 102 of the multi-system LFC system 100A shifts to an LFC execution step for continuously executing a new LFC function after the contract revision (step S5b).
As a result, the input unit, the calculation unit, the distribution unit, and the output unit activated after the contract revision operate periodically thereafter, and perform the same operation as in the first embodiment.

[5.3] At Contract Termination Next, a case where a contract user terminates a contract will be described.
When applying to the LFC function provider who operates and manages the multi-system LFC system 100A to terminate the contract for using the multi-system LFC system 100A, the site provided by the LFC function provider, for example, The user terminal 105A connects to the LFC management apparatus 102 via the second communication network 104 constructed as the Internet.

The contract user applies for contract termination using the user terminal 105A (step S1; contract step).
Thereby, the LFC management apparatus 102 of the multi-system LFC system 100A determines whether the application content in the contract step is a new contract, contract revision, or contract termination (step S2).

In this case, since the contract is terminated (step S2; contract terminated), the LFC management apparatus 102 performs the same process as in the case of stopping the LFC control in the second embodiment described above.
Then, the contract user uses the user terminal 105A to delete the input data, system characteristic data, control data, and output data necessary for maintaining the frequency of the already registered power system to the setting unit 141. Enter instructions.

  As a result, the contract user uses the user terminal 105 </ b> A to the setting unit 141 to terminate the contract, so that the power system input data, system characteristic data, necessary for maintaining the frequency of the already registered power system, The process proceeds to a maintenance step for deleting the control data and output data (step S3c).

  Then, the setting unit 141 of the LFC management apparatus 102 has already been registered, and the input data, system characteristic data, control data, and output data necessary for maintaining the frequency of the power system that is the target of contract termination are stored. In response to the deletion, a deletion instruction is input to the setting data recording unit 142.

  The setting data recording unit 142 of the LFC management apparatus 102 generates input data, system characteristic data, control data, and output data for the power system to be terminated based on the deletion instruction input from the setting unit 141. Remember that was deleted.

  Subsequently, the LFC management apparatus 102 of the multi-system LFC system 100A shifts to an LFC end step for ending the LFC function provision contract in the user's existing system corresponding to the user terminal 105A (step S4c).

  When the management unit 144 of the LFC management apparatus 102 receives an instruction to terminate the contract of the power system to be contract terminated (effectively excluded from the LFC control target), the input unit that has been moving periodically until that time, calculation The unit, the distribution unit, and the output unit are stopped and deleted.

  Thereafter, the management unit 144 of the LFC management apparatus 102 instructs the data update unit 143 to update the input data, the system characteristic data, the control data, and the output data of the power system subject to contract termination.

  Thereby, the data update unit 143 attempts to update the contents of the input data, system characteristic data, control data, and output data recorded in the setting data recording unit 142 based on an instruction from the management unit 144. However, since the setting data recording unit 142 records that these data have been deleted, an operation for effectively deleting the input data, system characteristic data, control data, and output data is performed. Do.

As a result, the provision of the LFC function to the power system after the contract is terminated.
The provision of the LFC function to the remaining power system continues, and the input unit, calculation unit, distribution unit, and output unit of the remaining power system operate periodically thereafter, and are the same as in the first embodiment. Perform the action.

  As described above, according to the multi-system LFC system of the fourth embodiment, the LFC function provider starts providing the LFC function as a service to a plurality of specific system LFC operators (users). Alternatively, the LFC function can be provided as a service by revising the contract (changing the operating conditions).

In addition, the end of provision of the LFC function service can be performed using the multi-system LFC system.
In the above description, the user terminal is directly connected to the LFC management apparatus via the second communication network (Internet). However, a contract management server is provided, and the contract management server is used as an external device of the LFC management apparatus. It is also possible to configure to perform similar processing.

[6] Fifth Embodiment In each of the above embodiments, the set data of each power system 101-1 to 101-x (system) stored in the setting data recording unit 142 is one set each. In the fifth embodiment, a plurality of sets of setting data of each power system 101-1 to 101-x (system) stored in the setting data recording unit 142 is stored.

FIG. 8 is an explanatory diagram of a data recording example of the setting data recording unit of the fifth embodiment.
Note that the configuration of the multi-system LFC system of the fifth embodiment is the same as that in the case of FIG. 3, and the detailed description thereof is incorporated.
The setting data recording unit 142A of the fifth embodiment is recorded for each of the power systems 101-1 to 101-x (systems) with a generation identifier for each past change. In FIG. 8, the power system is represented as a system for simplification of illustration.

  More specifically, as shown in FIG. 8, a specific system in which the setting unit 141 has already been set. In the following description, the power system 101-1 is a specific system, and the power system 101-1 is used for input. Changes in the data 131-1, the system characteristic data 132-1, the control data 133-1 and the output data 134-1 are accepted.

  When the received content is recorded in the setting data recording unit 142A as the setting data 130-1 of the power system 101-1, the latest input data 131-2, system characteristic data 132-2, control, etc. Recording data 133-2 and output data 134-2 with an identifier indicating a generation (in the example of FIG. 8, an identifier indicating the (j−1) th generation) and recording the changed input data 131-2, the system characteristic data 132-2, the control data 133-2, and the output data 134-2 are also attached with identifiers indicating generations (in the example of FIG. 8, identifiers indicating the jth generation). It is recorded as j generation setting data 130-1j. As a result, the first generation setting data 130-11 to the jth generation setting data 130-1j are stored as the setting data of the power system 101-1.

  Specifically, the input data 131-1 of the power system 101-1, the system characteristic data 132-1, the control data 133-1 and the output data 134-1 are changed as the jth generation setting data 130-1j. The input setting data 131-1S, the system characteristic setting data 132-1S, the control setting data 133-1S, and the output setting data 134-1S of the power system 101-1 that are input to receive the power are stored.

  Similarly, the deletion of the input data 131-1, the system characteristic data 132-1, the control data 133-1 and the output data 134-1 of the power system 101-1, which is a specific system that has already been set, is accepted. When the received content is recorded in the setting data recording unit 142A, the latest input data 131-1, system characteristic data 132-1, control data 133-1 and output data 134-1 are generated. (In the example of FIG. 8, an identifier representing the (j-1) th generation) is added and recorded, and the changed input data 131-2, system characteristic data 132-2, and control data 133-2 and output data 134-2 are also recorded with an identifier indicating the generation (in the example of FIG. 8, an identifier indicating the jth generation). As a result, the first generation setting data 130-11 to the jth generation setting data 130-1j are stored as the setting data of the power system 101-1, as in the case of accepting the change.

  By configuring in this way, for example, if a problem occurs after setting to the j-th generation setting data, the setting data that has already been used by specifying the generation is used again as new setting data. Easy operation.

  In this case, when the management unit 144 receives an instruction from outside to use the setting data of any generation prior to the j generation, the management unit 144 determines that the currently operating input unit 121-1 Unit 122-1, distribution unit 123-1, and output unit 124-1 are temporarily stopped, and then, for data update unit 143, power system 101 which is a specific system recorded in setting data recording unit 142 A -1 specified generation (for example, input data 131-1 based on input setting data, system characteristic setting data, control setting data, and output setting data corresponding to the setting data of the (j−1) -th generation) And instructing to update the system characteristic data 132-1, the control data 133-1 and the output data 134-1.

  Thus, when receiving an instruction from the management unit 144, the data updating unit 143 receives the setting data for the (j−1) generation of the power system 101-1 recorded in the setting data recording unit 142A, and system characteristic setting. The input data 131-1, system characteristic data 132-1, control data 133-1, and output data 134-1 for the power system 101-1 are updated according to the contents of the data, control setting data, and output setting data. To do.

  Next, the management unit 144 activates the input unit 121-1, the calculation unit 122-1, the distribution unit 123-1, and the output unit 124-1. Thereafter, the input unit 121-1, the calculation unit 122-1, the distribution unit 123-1, and the output unit 124-1 move periodically.

  By adopting such a configuration, according to the fifth embodiment, LFC control can be easily performed under the conditions before the change, and when there is an error in the setting data, the input data 131-1, This can be easily handled when it is desired to perform LFC control by returning the system characteristic data 132-1, the control data 133-1 and the output data 134-1 to the previous generation state.

[7] Effects of Embodiments As described above, according to the multi-system LFC system of each embodiment, for example, a remote island system in Central America, a remote island system in East Asia, and new cities in China and India As in the case of maintaining the frequency of this system, it is possible to cope with a plurality of systems in one LFC system for a plurality of systems.
In addition, it is possible to provide the LFC function as a service to each operator of a plurality of systems far away from the earth using a single LFC system for a plurality of systems.

  The LFC management device of the present embodiment includes a control device such as a CPU, a storage device such as a ROM (Read Only Memory) and a RAM, an external storage device such as an HDD and a CD drive device, a display device such as a display device, It has an input device such as a keyboard and a mouse, and has a hardware configuration using a normal computer.

  The program executed by the LFC management apparatus of the present embodiment is a file in an installable format or an executable format, and is a computer such as a CD-ROM, a flexible disk (FD), a CD-R, a DVD (Digital Versatile Disk). It is recorded on a readable recording medium and provided.

Further, the program executed by the LFC management apparatus of the present embodiment may be stored on a computer connected to a network such as the Internet and provided by being downloaded via the network. The program executed by the LFC management apparatus according to the present embodiment may be provided or distributed via a network such as the Internet.
Further, the LFC management apparatus program of the present embodiment may be provided by being incorporated in advance in a ROM or the like.

  The program executed by the LFC management apparatus of the present embodiment has a module configuration including the above-described units (input unit, calculation unit, distribution unit, output unit, setting unit, data update unit, management unit). As the hardware, a CPU (processor) reads the program from the storage medium and executes it to load the above-described units onto the main storage device. The input unit, calculation unit, distribution unit, output unit, setting unit, data An update unit and a management unit are generated on the main storage device.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

Claims (10)

An LFC management device that manages LFC control for each of a plurality of power systems having at least one of a generator and a storage battery system,
Based on the input data for each power system, a plurality of input units to which measurement data is input from each of the plurality of power systems,
A plurality of calculation units for calculating supply and demand imbalance amounts based on system characteristic data for each power system and the measurement data;
Ratio of margin to output upper and lower limit values of the generator constituting the plurality of power systems, ratio of margin to discharge power upper limit value / charge power upper limit value of the storage battery system, and the power system A plurality of distribution units for calculating distribution of the supply / demand imbalance amount to at least one of the generator and the storage battery system based on the control data for each, the measurement data, and the supply / demand imbalance amount;
A plurality of output units for outputting data for controlling the generator or the storage battery system based on the output data for each power system and the distributed supply and demand imbalance amount;
A data recording unit that stores the input data corresponding to each of a plurality of power systems, the system characteristic data, the control data, and the output data in advance in an updatable manner;
LFC management device with An LFC management device that manages LFC control for each of a plurality of power systems having at least one of a generator and a storage battery system,
Based on the input data for each power system, a plurality of input units to which measurement data is input from each of the plurality of power systems,
A plurality of calculation units for calculating supply and demand imbalance amounts based on system characteristic data for each power system and the measurement data;
A plurality of distributions for calculating a distribution of the supply / demand imbalance amount to at least one of the generator and the storage battery system based on the control data for each power system, the measurement data, and the supply / demand unbalance amount And
A plurality of output units for outputting data for controlling the generator or the storage battery system based on the output data for each power system and the distributed supply and demand imbalance amount;
A data recording unit that stores the input data corresponding to each of a plurality of power systems, the system characteristic data, the control data, and the output data in advance in an updatable manner;
A setting unit for inputting setting data for setting the addition, revision, or deletion of the input data, the system characteristic data, the control data, and the output data when the power system is added, revised, or deleted; ,
A setting data recording unit for storing the setting data;
A data updating unit for updating the input data, the system characteristic data, the control data, and the output data based on the setting data stored in the setting data recording unit;
A management unit that manages addition or deletion of the power system based on the updated input data, the grid characteristic data, the control data, and the output data;
L FC management device with. A plurality of control status display units that are provided for each power system, obtain control status data of the input unit, the calculation unit, the distribution unit, and the output unit, and perform display control;
A plurality of indicators that are provided for each power system and display the control status of the corresponding power system under the control of the corresponding control status display unit;
The LFC management apparatus according to claim 1 or 2, further comprising: An LFC management apparatus that is connected to each of a plurality of power systems having at least one of a generator and a storage battery system via a first communication network and manages LFC control of the plurality of power systems. There,
Based on the input data for each power system, a plurality of input units to which measurement data is input from each of the plurality of power systems,
A plurality of calculation units for calculating supply and demand imbalance amounts based on system characteristic data for each power system and the measurement data;
A plurality of distributions for calculating a distribution of the supply / demand imbalance amount to at least one of the generator and the storage battery system based on the control data for each power system, the measurement data, and the supply / demand unbalance amount And
A plurality of output units for outputting data for controlling the generator or the storage battery system based on the output data for each power system and the distributed supply and demand imbalance amount;
A data recording unit that stores the input data corresponding to each of a plurality of power systems, the system characteristic data, the control data, and the output data in advance in an updatable manner;
A setting unit that receives an additional contract for a new power system, a contract revision for an existing power system, or a contract termination for an existing power system from the information processing apparatus via the second communication network;
LFC management device with An LFC management device connected to each of a plurality of power systems having at least one of the generator and the storage battery system via a first communication network and managing LFC control of the plurality of power systems; ,
A user terminal or a server that can be connected to the LFC management device via a second communication network;
The LFC management device
Based on the input data for each power system, a plurality of input units to which measurement data is input from each of the plurality of power systems,
A plurality of calculation units for calculating supply and demand imbalance amounts based on system characteristic data for each power system and the measurement data;
A plurality of distributions for calculating a distribution of the supply / demand imbalance amount to at least one of the generator and the storage battery system based on the control data for each power system, the measurement data, and the supply / demand unbalance amount And
A plurality of output units for outputting data for controlling the generator or the storage battery system based on the output data for each power system and the distributed supply and demand imbalance amount;
A data recording unit that stores the input data corresponding to each of a plurality of power systems, the system characteristic data, the control data, and the output data in advance in an updatable manner;
A setting unit that accepts an additional contract for a new power system, a contract revision for an existing power system or a contract end for an existing power system from the user terminal via the second communication network;
LFC system with The setting unit accepts the additional contract, the contract revision or the contract termination from the user terminal, and sets the addition or deletion of the input data, the system characteristic data, the control data, and the output data. A setting data recording unit for storing the setting data by inputting setting data for
A data updating unit for updating the input data, the system characteristic data, the control data, and the output data based on the setting data stored in the setting data recording unit;
A management unit that manages addition, revision, or deletion of the power system based on the input data after the update, the grid characteristic data, the control data, and the output data;
The LFC system according to claim 5, further comprising: There is a data recording unit that pre-stores input data, system characteristic data, control data, and output data corresponding to each of a plurality of power systems having at least one of a generator and a storage battery system in an updatable manner. And a method executed by an LFC management apparatus that manages LFC control,
Based on the input data for each power system, a plurality of input steps in which measurement data is input from each of the plurality of power systems;
A plurality of calculation steps for calculating a supply and demand imbalance amount based on the system characteristic data and the measurement data for each power system;
Ratio of margin to output upper and lower limit values of the generator constituting the plurality of power systems, ratio of margin to discharge power upper limit value / charge power upper limit value of the storage battery system, and the power system A plurality of distribution steps for calculating distribution of the supply / demand imbalance amount to at least one of the generator and the storage battery system based on control data for each, the measurement data, and the supply / demand imbalance amount;
A plurality of output steps for outputting data for controlling the generator or the storage battery system based on the output data for each power system and the distributed supply and demand imbalance amount;
With a method. There is a data recording unit that pre-stores input data, system characteristic data, control data, and output data corresponding to each of a plurality of power systems having at least one of a generator and a storage battery system in an updatable manner. And a method executed by an LFC management apparatus that manages LFC control,
Based on input data for each power system, a plurality of input steps in which measurement data is input from each of the plurality of power systems;
A plurality of calculation steps for calculating a supply and demand imbalance amount based on the system characteristic data for each power system and the measurement data;
A plurality of distributions for calculating a distribution of the supply / demand imbalance amount to at least one of the generator and the storage battery system based on the control data for each power system, the measurement data, and the supply / demand unbalance amount Steps,
A plurality of output steps for outputting data for controlling the generator or the storage battery system based on the output data for each power system and the distributed supply and demand imbalance amount;
A setting step for accepting an additional contract for a new power system, a contract revision for an existing power system or a contract termination for an existing power system;
With a method. There is a data recording unit that pre-stores input data, system characteristic data, control data, and output data corresponding to each of a plurality of power systems having at least one of a generator and a storage battery system in an updatable manner. A program for controlling an LFC management apparatus for managing LFC control by a computer,
The computer,
A plurality of input means for inputting measurement data from each of the plurality of power systems based on the input data for each power system;
A plurality of calculating means for calculating the supply and demand imbalance amount based on the system characteristic data and the measurement data for each power system;
Ratio of margin to output upper and lower limit values of the generator constituting the plurality of power systems, ratio of margin to discharge power upper limit value / charge power upper limit value of the storage battery system, and the power system A plurality of distribution means for calculating distribution of the supply and demand imbalance amount to at least one of the generator and the storage battery system based on the control data for each, the measurement data and the supply and demand imbalance amount;
A plurality of output means for outputting data for controlling the generator or the storage battery system based on the output data for each power system and the distributed supply and demand imbalance amount;
Program to make it work. There is a data recording unit that pre-stores input data, system characteristic data, control data, and output data corresponding to each of a plurality of power systems having at least one of a generator and a storage battery system in an updatable manner. A program for controlling an LFC management apparatus for managing LFC control by a computer,
The computer,
A plurality of input means for inputting measurement data from each of the plurality of power systems based on the input data for each power system;
A plurality of calculation means for calculating a supply and demand imbalance amount based on the system characteristic data for each power system and the measurement data;
A plurality of distributions for calculating a distribution of the supply / demand imbalance amount to at least one of the generator and the storage battery system based on the control data for each power system, the measurement data, and the supply / demand unbalance amount Means,
A plurality of output means for outputting data for controlling the generator or the storage battery system based on the output data for each power system and the distributed supply and demand imbalance amount;
A setting means for accepting an additional contract for a new power system, a contract revision for an existing power system or a contract termination for an existing power system;
A program with

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