JP2004015882A - Distributed power supply system and method and operation program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enhance the reliability and cost efficiency of energy supply. <P>SOLUTION: A distributed power supply base A is constituted of a plurality of consumers 3 having a distributed power supply 4 and a load 5. The distributed power supplies 4 of the consumers 3 are connected to this intermediate system 2, and are provided with consumer controllers 6 for managing and controlling the distributed power supplies 4 and loads 5. The consumer controllers 6 are connected with a distributed power supply base controller 7 through the Internet 9. The distributed power supply base controller 7 manages and controls all the distributed power supply bases. If a request to buy power is made by a consumer 3 and a request to sell power is made by another consumer 3, the distributed power supply base controller 7 combines the consumers 3 together based on predetermined conditions. The combined consumers 3 sell and buy power between them. Thus, even if a consumer falls short of power, the consumer can be supplied with power from the distributed power supply 4 of another consumer 3. As a result, the reliability and cost efficiency of energy supply is enhanced. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention configures a middle system composed of a plurality of customers connected to an electric power system, and uses the middle system as a distributed power source base. The present invention relates to an improved distributed power supply system, an operation method thereof, and an operation program.
[0002]
[Prior art]
At present, power consumers are working on distributed energy systems that generate power using relatively compact power sources such as gas turbines, diesel engines, micro gas turbines, and fuel cells. The distributed energy system is CO ₂ And the reduction of NOx emissions, deregulation of the electric power business, and reform of the energy consumption structure. For example, in the United States, clean, inexpensive, low-noise, compact micro gas turbines have already been adopted. Also, evaluation tests of micro gas turbines are being actively conducted in Japan.
[0003]
[Problems to be solved by the invention]
Here, in order to achieve customer satisfaction of various energy consumers through the use of the distributed energy system, it is necessary to construct a system from the viewpoint of reliability and economical efficiency of energy supply. Therefore, the present invention has been made in view of the above, and an object of the present invention is to provide a distributed power supply system capable of dramatically improving the reliability and economy of energy supply, an operation method thereof, and an operation program. .
[0004]
[Means for Solving the Problems]
In order to achieve the above object, a distributed power supply system according to the present invention configures an intermediate system with respect to an electric power system, and includes a distributed power supply base in which distributed power sources and loads of a plurality of customers are connected in the intermediate system. A customer controller that is included in the distributed power supply site and manages and controls the distributed power supply and load in the distributed power supply site, and is connected to the customer controller via a communication network, and based on the information of the customer controller, And a decentralized power supply site controller for performing management control regarding power interchange between consumers.
[0005]
At the decentralized power source site, the power of the decentralized power source of the customer connected to the middle system is exchanged for the operation of the load of another customer. The decentralized power supply site controller performs management control regarding the interchange of power between consumers. The middle system means an intermediate system from a power system to a so-called distribution system with a load as a termination, and has a configuration in which a distributed power source is provided in the middle system. Since power is exchanged within the distributed power source base of the middle system, the need for partial load operation of the distributed power source for load fluctuations is reduced, and compared to the case where the distributed power source is operated alone. The efficiency and reliability of energy supply.
[0006]
The distributed power supply system according to the present invention configures a middle system with respect to the power system, and a plurality of distributed power sites that connect distributed power sources and loads of a plurality of customers in the middle system, and each distributed power site includes: A plurality of customer controllers for managing and controlling the distributed power supply and the load in the distributed power supply site, the plurality of customer controllers are connected to the plurality of customer controllers by a communication network, and the one distributed power supply site is connected based on the information of the customer controller. And a decentralized power supply site controller for managing and controlling power interchange between the customers.
[0007]
That is, a plurality of the distributed power supply points can be provided for the power system, and each of the distributed power supply points is provided with a customer controller and a distributed power supply point controller, and power is exchanged between the customers in the distributed power supply points. Like that. This reduces the necessity of performing the partial load operation of the distributed power supply with respect to the load fluctuation, and can improve the economy and reliability of energy supply by the distributed power supply as compared with the case where the distributed power supply is operated alone.
[0008]
In the distributed power supply system according to the present invention, among the plurality of customers, a customer controller of one customer transmits a power purchase request to a distributed power supply site controller, and the other customer among the plurality of customers is The customer controller transmits the power sale request to the distributed power site controller, and the distributed power site controller combines the power purchase request and the power sale request based on a predetermined combination process, and receives the other demand from the one customer. It is characterized by controlling to buy and sell electricity to the house.
[0009]
In this distributed power supply system, a power purchase request and a power sale request from a customer controller are combined by a predetermined combination process to trade power. The power purchase and sale management between consumers is performed collectively by a distributed power supply controller that manages and controls the distributed power supply sites. The predetermined combination process is also executed by the distributed power supply controller. Collective management by the distributed power supply controller enables smooth power trading.
[0010]
In the distributed power supply system according to the present invention, in the above-described configuration, when one of the customer of the power purchase request and the customer of the power sale request is singular, based on the required purchase price and sale price, Of the most profitable customers.
[0011]
When a single customer is most profitable, typically the customer can purchase power at the lowest cost or sell power at the highest price. In addition, it is a single consumer who enjoys this benefit based on market principles. In this way, the principle of competition can be applied to the purchase and sale of electric power within the distributed power source base. In addition, as a specific example, the single consumer may select the cheapest one among a plurality of power selling requests and purchase power at that price, or purchase power at the purchase price requested by the user himself / herself. And the like.
[0012]
In the distributed power supply system according to the present invention, in the above-described configuration, in a case where there are a plurality of consumers of the power purchase request and a plurality of customers of the power sale request, the combination processing is the closest from the required purchase price and sale price. It is characterized by combining customers who demand a buy price and a sell price. In this case, it is possible to provide a union that is closest to the price required by the consumer, that is, the union in which the consumer is most satisfied.
[0013]
The distributed power supply system according to the present invention is characterized in that, in the above configuration, the customer controller requesting power purchase cancels the power purchase request based on selling price information from the customer controller requesting power sale.
[0014]
Even if power is purchased from a certain customer due to the combination processing, if there is a reason such as being too far from the purchase price, canceling the power purchase request can prevent reluctant purchase of power. . In addition, it is possible to prevent consumers from requesting exorbitant prices.
[0015]
In the distributed power supply system according to the present invention, in the above-described configuration, when the distributed power supply of any of the customers in the distributed power supply base malfunctions, the distributed power supply base controller may provide another demand to the customer. It is characterized in that control is performed so that electric power is supplied from a distributed power source in a house under predetermined conditions.
[0016]
When the distributed power supply of a specific customer becomes malfunctioning, the operation of the load of the specific customer is stopped by receiving power from the distributed power supply of another customer without being supplied with power from the power system. No need. For this reason, the reliability of power supply by the distributed power supply can be improved as compared with the case where load operation is performed by a single distributed power supply.
[0017]
In the above configuration, the distributed power supply system according to the present invention, in the combination process, the customer controller of one customer specifies another customer to limit the combination and transmits the information to the distributed power supply site controller, The decentralized power supply site controller is characterized in that it does not combine the one customer with another designated customer.
[0018]
That is, some customers do not like to establish a power trading relationship with a particular customer, and in such a case, the customer designates another particular customer and establishes a relationship with the particular customer. Combinations can be prevented. As a result, a power trading relationship with an unwilling partner is not established.
[0019]
In the distributed power supply system according to the present invention, in the above configuration, the distributed power supply point controllers of the plurality of distributed power supply points substantially purchase and sell power between the distributed power supply points via a power system, and collect a charge of a power company. The means collects a brokerage commission for power trading between the distributed power supply sites from accounts of one or both of the distributed power supply sites.
[0020]
That is, in this distributed power supply system, since the distributed power supply bases are connected to each other by the power system, it is possible to trade power between them. A brokerage commission for power interchange between the two can be collected. As a result, it is possible to make a profit for both the customer and the power company.
[0021]
In the distributed power supply system according to the present invention, in the above-described configuration, the plurality of distributed power supply points each have a distributed power supply station connected to a middle system and connected to a distributed power supply mounted on a moving means such as a vehicle or a ship. And
[0022]
By providing the distributed power supply station, even if the facility of the distributed power supply is not possessed, it is possible to increase the entire power generation amount of the distributed power supply base. That is, if necessary, a distributed power source is brought by the transportation means and connected to the middle system, from which power can be supplied, the initial cost of the system can be reduced, and the power generation amount can be increased when necessary.
[0023]
In the distributed power supply system according to the present invention, in the above configuration, the moving means is a vehicle, and the distributed power supply station uses a gas station having a tank underground, and stores fuel of the distributed power supply in this tank. It is characterized by having.
[0024]
In Japan, where land is small, it is usually difficult to place a distributed power source that is as large as a car, and installing a fuel tank in addition to the distributed power source requires a considerable area. Therefore, if the distributed power source is arranged at the gas station by the moving means and the distributed power source is operated by the fuel stored in the underground tank, the problem of the storage location of the distributed power source can be solved. Further, when the dispersed power source is loaded on the vehicle and moved, the gas station is suitable as a distributed power station because the gas station has a structure in which the vehicle easily enters and stops for the purpose.
[0025]
The distributed power supply system according to the present invention is characterized in that, in the above configuration, the distributed power supply station further includes a power storage means for storing power supplied from the distributed power supply mounted on the connected moving means.
[0026]
By providing the power storage means in the distributed power station, there is no need to restrain the moving means when power is needed. That is, the distributed power source mounted on the moving means is connected to the distributed power station, and the power generated by the distributed power source is stored in the power storage means. Thereby, even if the moving means moves away from the distributed power supply station, the required power is stored in the power storage means, so that it is possible to meet the power demand of the distributed power supply base.
[0027]
The distributed power supply system according to the present invention is characterized in that, in the above configuration, the power storage means can store surplus power in the distributed power supply base. Further, if the surplus power in the distributed power source site is stored, the stored power can be used when the power shortage occurs in the distributed power source site. Thereby, the reliability of the power supply in the distributed power source base can be improved.
[0028]
A distributed power supply system according to the present invention includes a distributed power supply base that configures a middle power system with respect to an electric power system, and connects a distributed power supply and a load of a plurality of customers within the middle power system, and is included in the distributed power supply base. A customer controller for controlling and managing the distributed power supply and load in the distributed power supply base; and a virtual controller configured by grouping specific customers among the plurality of customers based on predetermined conditions in the distributed power supply base. A distributed power supply site, and a virtual distributed power supply site controller that is constructed corresponding to the virtual distributed power supply site, is connected to the customer controller via a communication network, and controls and controls the entire virtual distributed power supply site. Features.
[0029]
When there are a large number of customers, grouping is performed by specific customers, and these groups are set as virtual distributed power supply sites on the program. A distributed power supply site controller is associated with the virtual distributed power supply site, and a dedicated distributed power supply site controller is constructed for the grouped customers. As a result, the grouped consumers are managed and controlled by the dedicated virtual distributed power supply site controller, so that efficient operation as a whole is possible.
[0030]
The distributed power supply system according to the present invention is characterized in that, in the above-described configuration, the grouped virtual distributed power supply points are configured by specific customers who have previously agreed to create virtual distributed power supply points. In this way, it is possible to configure a virtual distributed power source base between specific customers and operate the virtual distributed power source base only by the customers.
[0031]
The distributed power system according to the present invention is characterized in that, in the above configuration, the virtual distributed power point controller determines whether or not to participate in the grouping based on information of a customer who intends to participate in the virtual distributed power point.
[0032]
If a customer participates in the distributed power system unconditionally, efficient operation of the system may be hindered depending on the state of the customer. For this reason, the virtual distributed power supply site controller determines whether participation is possible based on the information of the customer, thereby preventing a decrease in system efficiency. The customer information is, for example, the type of the distributed power source owned by the customer, the maintenance record, the business content of the customer, the time zone, and the like.
[0033]
In the distributed power supply system according to the present invention, in the above-described configuration, when there is a customer who intends to participate in the virtual distributed power supply base when the grouping is performed, the virtual distributed power supply base controller hinders the optimal operation of the system. When there is a risk of causing the customer, a notice of refusal of participation is sent to the customer controller of the customer.
[0034]
By performing the participation rejection notification, it is possible to prevent the problematic customer from participating, efficiently operate the system, and encourage the customer to improve the state. Here, the optimal operation of the system is an operation in which a plurality of customers having normally conceivable loads are grouped using a distributed power supply having normal performance. It is not the optimal operation of the system to put a customer having a distributed power source that is causing trouble due to insufficient maintenance or the like into a group.
[0035]
In the distributed power supply system according to the present invention, in the above-described configuration, the virtual distributed power supply site controller further transmits a notification of improvement from the customer controller of the customer to the virtual distributed power supply site controller after performing the participation rejection notification. The feature is that the participation of the customer is permitted.
[0036]
In other words, even if a customer who has been rejected from participation can improve the problem, he or she can join the system. If the customer has no problem, it can contribute to the efficient operation of the system, so that the economic efficiency and reliability of the distributed power source can be further improved. In addition, it is preferable that the improvement notice is transmitted with attached evidence. Accepting participation with inadequate improvement measures will end up inconveniencing other consumers.
[0037]
In the above configuration, the distributed power supply system according to the present invention is characterized in that the plurality of distributed power supply points have a power transmission / reception system that transmits and receives microwaves between the distributed power supply points. If power is transmitted by microwaves, power can be exchanged between the distributed power sources even if the distributed power sources are not connected by cables. For example, if an artificial satellite is relayed, power can be transmitted to a remote place such as a remote island, a remote place, or a foreign country.
[0038]
An operation method of a distributed power supply system according to the present invention is a method in which a plurality of customers each having a distributed power supply and a load are connected in a distributed power supply base constituting a middle system with respect to an electric power system, and a customer controller in the distributed power supply base is connected. In managing and controlling the distributed power supply site controller, a procedure for issuing a power purchase request from the customer controller of one of the plurality of customers to the distributed power supply site controller via the network, and A procedure for issuing a power sale request from the customer controller to the distributed power site controller via the network, and a predetermined combination of the customer who has issued the power purchase request and the customer who has issued the power sale request by the distributed power site controller. And a procedure for performing power purchase and sale between these consumers based on the combination based on the processing.
[0039]
As described above, by the distributed power supply site controller that manages and controls the distributed power supply sites, the power purchase request and the power sale request are combined with each other based on a predetermined combination process, so that the power purchase and sale can be smoothly performed between the customers. Can be done.
[0040]
In the operation method of the distributed power supply system according to the next invention, in the above-described configuration, the combination processing is performed to the required buy price and sell price when one of the power purchase request customer and the power sale request customer is singular. And performing a combination that provides the most benefit to a single customer based on the combination.
[0041]
As described above, when one of the customer who requests the power purchase and the customer who requests the power sale is singular, the single customer can obtain the maximum profit based on the market principle. The greatest benefit of a single consumer is typically to purchase power at the cheapest or sell power at the most expensive. As a specific example, the single consumer may select the cheapest one among a plurality of power sales requests and purchase power at that price, or purchase power at a purchase price requested by the user himself / herself. And so on.
[0042]
In the operation method of the distributed power supply system according to the present invention, in the above-described configuration, in the case where there are a plurality of consumers for the power purchase request and a plurality of customers for the power sale request, the combination processing includes a request purchase price and a sell price The method includes a step of combining the customers who request the buy price and the sell price closest to the customer.
[0043]
When there are a plurality of consumers who request a power purchase and a plurality of customers who request a power sale, all of the customers who purchase the power and the request that sells the power are closest to each other by combining the requests that are closest to each other. Can perform satisfactory power trading. Note that the allowable difference between the buy price and the sell price may be set in advance.
[0044]
The operation method of the distributed power supply system according to the present invention, in the above configuration, includes a step in which the customer controller requesting power purchase includes a step of canceling the power purchase request based on selling price information from the customer controller requesting power sale. Features.
[0045]
Even if power is purchased from a certain customer by the combination process, if there is a reason such as being too far from the purchase price (specifically, see the following embodiment), the power purchase request can be canceled. Inadvertently purchasing power can be prevented. Further, it is possible to prevent consumers from requesting exorbitant prices, and it is possible to optimize the operation of the entire distributed power source base.
[0046]
The operation method of the distributed power supply system according to the next invention is such that, in the above-described configuration, when the distributed power supply of any one of the customers in the distributed power supply base becomes malfunctioning, the distribution of the other consumers to the customer is performed. The method includes a step of supplying power from a power source under predetermined conditions.
[0047]
When the distributed power supply of a specific customer malfunctions, it is not necessary to stop the operation of the load of the specific customer by receiving power supply from the distributed power supply of another customer. For this reason, the reliability of power supply by the distributed power supply can be improved as compared with the case where load operation is performed by a single distributed power supply. The malfunction of the distributed power source corresponds to a case where the output of the distributed power source is reduced to half or less, a case where the output is stopped due to a failure, and the like.
[0048]
The method of operating a distributed power supply system according to the present invention, in the above-described configuration, relates to a procedure in which, in the combination process, one customer designates another customer restricting the combination, and the designation designates the one customer. A procedure for preventing combination with another customer.
[0049]
Some customers do not want to have a power trading relationship with a particular customer. For example, the distributed power source of the specific customer is not reliable. According to the present invention, the combination with the designated customer is prevented from being performed by the designation from one customer in advance. As a result, a power trading relationship with an unwilling partner is not established.
[0050]
An operation method of a distributed power supply system according to the present invention is a method in which a plurality of customers each having a distributed power supply and a load are connected in a distributed power supply base constituting a middle system with respect to an electric power system, and a customer controller in the distributed power supply base is connected. Is managed and controlled by a distributed power supply site controller, and a plurality of such distributed power supply sites are connected to the power system, and power is exchanged between the distributed power supply sites. And a step of collecting an intermediary commission for power purchase and sale between the distributed power bases from accounts of one or both of the distributed power bases via the network.
[0051]
When power trading is performed between the distributed power supply sites, power trading is performed via a power system. On the other hand, since the power is not sold to the power company that owns the power system, the selling price can be determined by the distributed power bases, and the power company pays a brokerage commission for buying and selling using the power system for one or both Collect from your account. As a result, both the distributed power source base and the power company can enjoy profits.
[0052]
An operation method of a distributed power supply system according to the present invention is a method in which a plurality of customers each having a distributed power supply and a load are connected in a distributed power supply base constituting a middle system with respect to an electric power system, and a customer controller in the distributed power supply base is connected. Is controlled by a distributed power supply site controller, and a plurality of such distributed power supply sites are connected to the power system, and in order to exchange power between the distributed power supply sites, a distributed power supply station provided at each distributed power supply site Is connected to a distributed power source mounted on the moving means, so that power is supplied from the distributed power source.
[0053]
By providing the distributed power supply station, even if the facility of the distributed power supply is not possessed, it is possible to increase the entire power generation amount of the distributed power supply base. As a result, the initial cost of the distributed power supply system can be kept low, and the power generation amount can be increased when necessary from the standpoint of the distributed power supply base.
[0054]
An operation method of a distributed power supply system according to the present invention is a method in which a plurality of customers each having a distributed power supply and a load are connected in a distributed power supply base constituting a middle system with respect to an electric power system, and a customer controller in the distributed power supply base is connected. In managing and controlling the distributed power supply point controller, a procedure of constructing a virtual distributed power supply point by grouping specific customers among the plurality of consumers based on predetermined conditions, and corresponding to the virtual distributed power supply point And a procedure for constructing a virtual distributed power supply site controller configured to perform management control of the entire virtual distributed power supply site.
[0055]
When there are many customers, grouping is performed by specific customers, and these groups are set as virtual distributed power supply bases. A distributed power supply site controller is associated with the virtual distributed power supply site, and a dedicated distributed power supply site controller is constructed for the grouped customers. As a result, the grouped consumers are managed and controlled by the dedicated virtual distributed power supply site controller, so that efficient operation as a whole is possible.
[0056]
An operation method of a distributed power supply system according to the present invention is a method in which a plurality of customers each having a distributed power supply and a load are connected in a distributed power supply base constituting a middle system with respect to an electric power system, and a customer controller in the distributed power supply base is connected. In managing and controlling the distributed power supply site controller, a procedure for constructing a virtual distributed power supply site by grouping specific customers who have previously made a virtual distributed power supply site and corresponding to the virtual distributed power supply site And a procedure for constructing a virtual distributed power supply site controller configured to perform management control of the entire virtual distributed power supply site. In this way, it is possible to configure a virtual distributed power source base between specific customers and operate the virtual distributed power source base only by the customers.
[0057]
The operation method of the distributed power supply system according to the present invention is characterized in that, in the above configuration, the grouping includes a step of determining whether to participate in the virtual distributed power supply base based on information of a customer who intends to participate in the virtual distributed power supply base.
[0058]
When a customer participates in the distributed power supply system unconditionally when the customer participates in the distributed power supply system, efficient operation of the system may be hindered depending on the state of the customer. For this reason, the virtual distributed power supply site controller determines whether participation is possible based on the information of the customer, thereby preventing a decrease in system efficiency.
[0059]
The operation method of the distributed power supply system according to the present invention, in the above configuration, when there is a customer who intends to participate in the virtual distributed power supply base at the time of the grouping, and when the customer is not suitable for optimal operation of the system, It is characterized by including a procedure for rejecting the participation of the customer.
[0060]
By performing the participation rejection notification, it is possible to prevent the problematic customer from participating, efficiently operate the system, and encourage the customer to improve the state. Here, the optimal operation of the system is an operation in which a plurality of customers having normally conceivable loads are grouped using a distributed power supply having normal performance. For this reason, if a customer having a dispersive power source that has a problem participates in a group, optimal operation of the system may be impaired.
[0061]
The operation method of the distributed power supply system according to the present invention, in the above-described configuration, further includes, after rejecting participation, a procedure of permitting participation of the customer based on a notification of implementation of an improvement measure from the customer. I do. If the customer has no problem, it can contribute to the efficient operation of the system, so that the economic efficiency and reliability of the distributed power source can be further improved. Therefore, in the present invention, even a customer who has been rejected to participate can participate in the system if the problem is solved.
[0062]
An operation program for a distributed power supply system according to the present invention causes a computer to execute each procedure described in any one of the above.
[0063]
The distributed power supply system according to the present invention, in the above-described configuration, connects a general load to the power system in the middle system, connects a plurality of important loads to an autonomous system having a distributed power supply, and The power system and the self-generating system are system-linked, a disconnection means is provided in the system connection circuit, and a commercial power supply system for supplying commercial power from the commercial system to a plurality of important loads is provided. The overlap switching means is provided at each connection point with a plurality of autonomous systems connected to a load.
[0064]
After performing a general system interconnection operation, the overlap switching means is switched from the commercial power supply system to the private power generation system, and the middle system connected to the power system and the private power generation system are disconnected via the disconnection means. When operating in a linked state, even if an instantaneous voltage drop occurs due to a lightning strike or the like in the middle system, the important load is under the same conditions as when operating under the autonomous system from the beginning through the cutoff means by power flow control Therefore, the influence of the sag is hardly affected by the blocking means. In addition, it is not necessary to provide a breaking means for each important load or a large breaking means corresponding to the total load of each important load, depending on the operation method, and it is sufficient to provide the overlap switching means for each demand load. Therefore, the cost of the entire system can be reduced.
[0065]
The distributed power supply system according to the next invention, in the above configuration, further monitors the output of the private generator, and in accordance with the output, sequentially switches overlap switching means provided for each of the plurality of important loads, and switches from the power system. Control means for switching power supply to the important load via the commercial power supply system to power supply to the important load via the self-powered system is provided.
[0066]
When the overlap switching means is sequentially switched according to the output, even when the capacity of the interrupting means and the high-speed current limiting interrupter is smaller than the total capacity of the important load, the power flow of the interrupter is monitored and controlled depending on the operation method described later. It is possible to switch from the power system to the self-generated power system, and it is possible to reduce the cost of the apparatus, especially since the capacity of the high-speed current-limiting means can be reduced.
[0067]
The distributed power supply system according to the next invention, in the above configuration, further monitors the current output of the private generator, and newly switches the current output amount and the total load amount of the important load already operated by the private generator. The difference between the planned load amount obtained by adding the load of the important load and the current output amount of the private generator so that the difference falls within the capacity of the shut-off means, and for each of the plurality of important loads. A control means for sequentially switching the provided overlap switching means and switching power supply from the power system to the important load via the commercial power supply system to power supply to the important load via the self-generated power system. Features.
[0068]
If the difference between the planned load amount and the present output amount exceeds the capacity, a power flow larger than the capacity of the breaking means will occur in the breaking means, and a breaking capacity of a larger capacity will be necessary for the excess. However, by controlling the current output amount of the private generator, power flow control in the cutoff means becomes possible. As a result, since the operation can be performed within the predetermined capacity of the shutoff means, a large capacity shutoff means is unnecessary.
[0069]
The distributed power supply system according to the next invention is characterized in that, in the above-described configuration, control means for selectively switching control of the overlap switching means provided for each of the plurality of important loads is further provided. If a specific important load can be selected from among the important loads, only the most important load can be protected at least from an abnormal state of the power system such as a sag.
[0070]
The distributed power supply system according to the next invention is characterized in that, in the above configuration, the capacity of the cutoff means is smaller than the capacity of all the important loads. Note that this configuration does not mean that the capacity of the cutoff means must always be smaller than the capacity of all the important loads.
[0071]
The distributed power supply system according to the next invention is characterized in that, in the above configuration, the overlap switching means includes a switch connected to an electric power system and a switch connected to an autonomous system. Since the overlap switch is composed of at least two switches as described above, it can be realized with a simple configuration. Further, by using such overlap switching means, it is possible to prevent the power supply to the important load from fluctuating at the time of switching.
[0072]
The distributed power supply system according to the next invention is characterized in that, in the above-described configuration, a synchronous control means for performing synchronous control of a power system connected to the switch and an autonomous system is provided. By providing the synchronous control means in the switch of the overlap switch, it is possible to return from the self-generated power system to the power system connected to the power system for each important load.
[0073]
A method of operating a distributed power supply system according to the next invention is to install the distributed power supply system according to any one of the above, and switch the overlap switching means of the important load from the commercial power supply system of the power system to the autonomous system. Power is supplied from the source system to each important load, and operation is performed in a state where the system is linked to the power system via the cutoff means.
[0074]
An operation method of a distributed power supply system according to the next invention includes the installation procedure of the distributed power supply system according to any one of the above, and a method for commercializing the overlap switching means of a specific important load based on a power generation amount of a private generator. A first switching procedure for switching from the commercial power supply system of the system to the private power generation system, and, in accordance with an increase in the amount of power generated by the private power generator, the overlap switching means for a specific important load different from the important load to the power system. A second switching procedure for switching from the commercial power supply system to the private power supply system, and a procedure for repeating the second switching procedure may be included. The operation is performed in a state in which the system is linked to the commercial system via the cutoff means. It is characterized by the following.
[0075]
An operation method of the distributed power supply system according to the next invention includes an installation procedure of the distributed power supply system according to any one of the above, an extraction procedure of extracting a most important load from the plurality of important loads, and A first switching procedure for switching the overlap switching means of the specific most important load from the commercial power supply system of the power system to the private power generation system based on the power generation amount, and A second switching procedure for switching the overlap switching means of the specific most important load different from the load from the commercial power supply system of the power system to the autonomous system, and a procedure for repeating the second switching procedure may be included. Yes, the operation is performed in a state where the system is linked to the electric power system via the cutoff means.
[0076]
The operation method of the distributed power supply system according to the next invention is further characterized in that, in the above configuration, the current output amount of the private generator and the total load amount of the important loads already operated by the private generator are newly switched. The second switching procedure is performed when a difference between the load and the expected load obtained by adding the load falls within the capacity of the shutoff means.
[0077]
The operation method of the distributed power supply system according to the next invention is characterized in that, in the above configuration, when returning from the self-powered system to the power system, synchronization is performed for each overlap switching unit. An operation program for stable power supply according to the next invention causes a computer to execute each procedure described in any one of the above and other than the installation procedure.
[0078]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings. It should be noted that the present invention is not limited by the embodiment. The constituent elements of this embodiment include those that can be easily replaced by those skilled in the art or those that are substantially the same.
[0079]
(Embodiment 1)
FIG. 1 is a configuration diagram showing a distributed power supply system according to Embodiment 1 of the present invention. This distributed power supply system 100 has distributed power supply points A to N configured by a middle system 2 connected to an electric power system 1, and a plurality of customers 3 are hierarchically or in a network in the distributed power supply points A to N. Connected. Each customer 3 includes a distributed power source 4 that is its own power generation facility, a load 5 such as a lighting device that consumes generated electricity, and a customer controller 6 that manages and controls the distributed power source 4 and the load 5. . Further, the distributed power supply system 100 includes a distributed power supply point controller 7 that manages and controls the entire distributed power supply points A to N. The distributed power supply site controller 7 is installed at a predetermined location, and is managed by a management association having a corporate status established by the customer 3 constituting the distributed power supply site A.
[0080]
Each customer controller 6 and distributed power supply site controller 7 are configured by a general-purpose computer including a display device 8 such as an LCD (Liquid Crystal Display) and a CRT (Cathode Ray Tube) and a predetermined program, and are provided by the Internet (WWW: World Wide). The Internet 9 is connected to a network such as a Web (Web) and a WAN (Wide Area Network). The distributed power supply site controller 7 includes a management control program that performs management control on the interchange of power at the distributed power supply sites A to N and the like. Further, the customer controller 6 is provided with a program for managing and controlling the operation of the distributed power supply 4 and the load 5 and the like. Further, the distributed power source base controller 7 has a server program (HTTPd) for providing the base information described in the HTML language to the customer 3. On the other hand, the customer controller 6 of the customer 3 serving as a client is provided with a browser program for analyzing and displaying information from the distributed power source base controller 7. Further, the distributed power supply site controller 7 is provided with a database 10 for storing data on each customer 3.
[0081]
As the distributed power source 4, a diesel engine, a gas engine, a micro gas turbine, a gas turbine, a fuel cell, or the like can be used. The customers 3 include hotels, hospitals, schools, landfills, offices, supermarkets, restaurants, gas stations, sports centers, large factories, small factories, large buildings, railways, neighborhood associations, and general households. be able to. The load 5 of the customer 3 includes lighting such as a fluorescent lamp, power such as an elevator and a pump, office equipment such as a computer and a printer, processing units for chemical substances such as cooling and heating, a heated water pool, garbage, medical equipment such as an MRI, and lightning. A large display device such as a bulletin board can be used.
[0082]
FIG. 2 is an explanatory diagram showing the relationship between the power generation output of various distributed power sources, the power demand for each customer, and the heat demand. As described above, the amount of electric power used differs depending on the customer 3, and the type of the distributed power source 4 used differs depending on the amount of electric power. The decentralized power supply sites A to N do not group the customers 3 having the same power usage mode (power usage, usage time zone, etc.) but group the customers 3 having different power usage modes. Thereby, mutual compensation of the power in the distributed power supply points A to N can be made to function.
[0083]
For example, in the figure, instead of grouping a plurality of general homes as one distributed power source base, consumers 3 having different power use time periods and usage amounts, such as general homes, business hotels and department stores, are combined into one. Group as a distributed power source base. It is not necessary for these consumers 3 to be located close to each other, but it is desirable that they exist in the same area in units of a town. As described above, by grouping the customers 3 having different power usage forms as the distributed power supply bases A to N, it is possible to easily exchange power mutually, thereby enabling economical operation of the entire distributed power supply base. Become.
[0084]
In this distributed power supply system 100, the distributed power supply 4 of the customer 3 performs the most efficient rated operation, exchanges surplus power and insufficient power in the distributed power supply site A, and supplies power from the power system 1. The area is minimized, and preferably an area substantially independent of the power system 1 is realized. The interchange of power is collectively managed and controlled by the distributed power supply site controller 7. In addition, surplus power of the entire distributed power source site A is sold to the power company 11.
[0085]
A specific power interchange system in the distributed power source base A will be described. FIG. 3 is an example of the distributed power supply operation status screen 20 provided by the distributed power supply site controller 7. The distributed power supply operation status screen 20 is displayed on a display device (not shown) of each customer controller 6. FIG. 4 is a conceptual diagram of the power interchange system. The customer controller 6 and the distributed power source base controller 7 connected via the Internet 9 can communicate with each other. For example, when the power of the customer 3A is insufficient, the customer controller 6A sends the distributed power source base. A power purchase request 21 is transmitted to the controller 7. As a result, the distributed power supply site controller 7 receives and registers the power purchase request 21 and waits until there is a power sale request 22. Next, the consumers 3B and 3C having surplus power transmit a power sale request 22 from the customer controller 6B to the distributed power supply site controller 7. The distributed power supply site controller 7 receives and registers this power sale request 22. The request display section 23 of the distributed power supply operation status screen 20 displays that the power purchase request 21 and the power sale request 22 have been made by each of the consumers 3A to 3C (circles 24 in the figure).
[0086]
The power purchase request 21 and the power sale request 22 are registered in the distributed power supply site controller 7 and processed as follows based on a predetermined combination program 25. FIG. 5 is a flowchart illustrating an example of a processing step according to the combination program.
(1) When there is only one power purchase request and one power sale request (step S2)
Assuming that both the power purchase request 21 and the power sale request 22 exist (step S1), the sale price presented by the customer 3 who wants to sell power and the purchase price desired by the customer 3 who wants to buy power are determined. The consumer 3 purchases electricity at an intermediate price. At that time, the customer 3 who desires to purchase power can cancel the power purchase request 21 by looking at the selling price (in this case, the intermediate price). It is preferable that the cancellation be automatically performed by the customer controller 6 by inputting the upper limit of the purchase price to the customer controller 6 in advance.
[0087]
(2) When one of the power purchase request and the power sale request is singular (step S4)
{Circle around (1)} When the power purchase request 21 is singular and the power sale request 22 is plural (Step S5), the customer 3 making the power purchase request 21 is among the customers 3 making the power sale request 22. , The cheapest power can be purchased (step S6). At that time, since the purchase price of the customer 3 who has made the power purchase request 21 is not displayed on the distributed power supply operation status screen 20, the requested purchase price is not known to the customer 3 who sold it, and the power purchase request is made. The consumer 3 may be able to purchase power at a lower price than the actually requested purchase price.
{Circle around (2)} On the other hand, if the power sale request 22 is singular and the power purchase request 21 is plural (Step S5), the customer 3 making the power sale request 22 becomes the customer 3 making the power purchase request 21. Can be sold to the customer 3 with the highest price (step S7). At this time, since the selling price of the consumer 3 who has made the power selling request 22 is not displayed on the distributed power supply operation status screen 20, the requested selling price is not known to the selling consumer 3 and the power selling request is made. The consumer 3 may be able to sell power more expensively than the actually requested selling price.
However, in any case, the customer 3 who desires to purchase power can cancel the power purchase request 21 by looking at the actual selling price. As described above, the cancellation is automatically performed by the customer controller 6 by inputting the upper limit of the purchase price to the customer controller 6 in advance.
[0088]
(3) When there are a plurality of power purchase requests and power sale requests (step S8)
The customers 3 with the closest selling price and buying price are combined (step S9). Thereby, each customer 3 can purchase and sell electric power at a price close to the desired price, so that all the customers 3 can be satisfied. In this case as well, the customer 3 desiring to purchase power can cancel the power purchase request 21 based on the actual selling price. Further, the process of whether or not to cancel is automatically performed by the customer controller 6 by inputting the upper limit and the lower limit of the purchase price in advance to the customer controller 6.
Next, when there is a customer 3 having a combination of the customers 3 with the closest selling price and buying price (there is no other customer 3 near the buying price or selling price desired by the customer 3). Processing is performed by the combination of (1) and (2) (step S10).
In addition, since the above (1) to (3) are examples of the combination method of the customers 3, the combination of the customers 3 can be performed under other conditions.
[0089]
(4) Malfunction of distributed power source
For example, when the distributed power supply 4 becomes malfunctioning, the customer 3 needs urgent power, and therefore, when there is an urgent power purchase request 21 from the malfunctioning customer 3 (step S11) Processing is performed such that power is forcibly received from the distributed power source 4 of another customer 3 without performing the processing of (1) to (3) (step S12). Power supply is performed until the malfunctioning distributed power supply 4 recovers (step S13). The power supply source in such a case is determined as follows.
(1) Register one or more customers 3 using a distributed power source 4 (gas turbine, diesel engine, or the like) having a high power generation capacity in advance, and supply power in the order of registration.
{Circle around (2)} In the case where the malfunctioning distributed power source 4 has a low power generation capacity (such as a fuel cell), the customer 3 of the distributed power source 4 having a high power generation capacity is replaced with the customer 3 of the malfunctioning distributed power source 4. Register as a supporter to receive supplies.
{Circle around (3)} When the failed distributed power source 4 has a high power generation capacity and a large load 5 (pump, elevator, compressor for building air conditioning, etc.), the distributed power source 4 is dispersed from all or most of the consumers 3 at the distributed power source base. Power supply.
Since the malfunction is a problem that can occur in any of the distributed power sources 4, the power supply in the case of the malfunction is either free of charge, or the management association is instructed by the customer 3 according to the amount of power generated by its own distributed power source 4. It is preferable that the funds are pooled as insurance money, and the pooled funds are applied and processed.
[0090]
(5) Combination restriction
Although not shown in the flowchart, there may be some customers 3 who do not want to establish a power trading relationship depending on the customers 3. In this case, one customer 3 designates another customer 3 and transmits the information from the customer controller 6. The distributed power supply site controller 7 registers the information, and when one customer 3 is combined with the other designated customer 3 by the combination program 25, the combination processing is invalidated. The invalidated information is transmitted to only the specified customer 3 or the information indicating that the combination itself is not made is transmitted to the other customers 3. The designation of the combination restriction may be required to be accompanied by a reason in order to prevent improper restriction designation. For example, combination restriction can be performed for the following reasons.
{Circle around (1)} The customer 3 who wants to specify is selling electric power at an exorbitant price.
{Circle around (2)} When there is a problem in the reliability of the distributed power source 4 of the customer 3 to be designated (due to insufficient maintenance or the like).
(3) When there is an economic or legal interest with the customer 3 to be designated.
Thereby, each customer 3 can be encouraged to buy and sell electric power at an appropriate price, and each customer 3 can be encouraged to perform sufficient management and maintenance of its own distributed power supply 4. In addition, the nature of the reason can mainly include the reason that an action that hinders the operation of the distributed power supply system 100 can be suppressed, or that the customer 3 has an economic stake, and the like. As long as the reason is included in such a category, the reason is also recognized for reasons other than (1) to (3). It is preferable that the reason is selected in advance from a plurality of reasons displayed on the distributed power source operation status screen 20 and transmitted to the distributed power source site controller 7.
[0091]
In addition, it is preferable to provide evidence for the above reasons. In addition, it is preferable that the evidence be information stored in the database 10 of the distributed power source site controller 7 in order to ensure fairness of the determination. Evidence may be transmitted from the customer controller 6 to the distributed power site controller 7 or mailed to the administrator of the distributed power site controller 7. The execution of the combination restriction is at the discretion of the distributed power source site controller 7 (either automatically determined or set by the administrator). On the other hand, it is not allowed to limit the combination for an unreasonable reason, for example, because the specific customer 3 does not like it.
[0092]
In addition, a state in which the distributed power sources 4 are combined by the combination program 25 is displayed on the status monitor 26 of the distributed power source operation status screen 20. As a specific example, as shown in the figure, a state where power is supplied from the customers G1 and G3 to the customer G2 is displayed. These can be viewed on the display device of the customer controller 6. The monitor table 27 at the bottom of the screen displays the power usage status of each customer 3. The power amount can be changed to the cost display by the display switching button 28. Note that the above combination method is an example, and another combination method may be used.
[0093]
The settlement of the power purchase and sale fee is performed on the network in a fixed period unit such as a month unit. Specifically, trading data of each customer 3 for a certain period is accumulated in the database 10, and the distributed power supply base controller 7 determines the amount to be paid to another customer 3 based on this data, Calculate the amount to be paid from 3. The bank accounts of the customers 3 are connected to each other by the Internet 9, and based on the result of the calculation, settlement is performed on the network.
[0094]
As described above, in the distributed power supply system 100, the distributed power supply 4 of each customer 3 is operated at an efficient rated operation and surplus power is sold or insufficient power is purchased. Operation becomes possible. Therefore, it is economically and ecologically advantageous. Further, even if the distributed power supply 4 of each customer 3 malfunctions, power can be supplied from the distributed power supply 4 of another customer 3, so that the reliability of the entire distributed power supply system 100 increases. On the other hand, when the customer 3 is operating only with its own distributed power supply 4 without constructing the distributed power supply system 100, the distributed power supply 4 may be partially loaded due to a change in the load 5. However, energy conversion efficiency deteriorates and is not economical. Further, since there is no support means when the distributed power supply 4 malfunctions, the reliability is lacking, or if a spare power supply is prepared, the economic burden due to an increase in equipment increases.
[0095]
Further, surplus power in the entire distributed power source base can be sold to the power company 11 via the power system 1. In addition, surplus power can be bought and sold between the distributed power sources A to N. In this case, in order to exchange power through the power system 1, surplus power is temporarily sold to the power company 11, and the surplus power is purchased at the other distributed power sources A to N. The selling price of the surplus power can be determined by the trading party. Note that since the power company 11 does not ultimately purchase surplus power, a sales contract between the power company 11 and the distributed power base A is unnecessary.
[0096]
The power company 11 can also collect the brokerage commission in the purchase and sale of surplus power between the distributed power supply sites. For example, when a power sales contract is made between the distributed power site A and the distributed power site B via the Internet 9, first, the distributed power site A is controlled by the distributed power site controller 7 from the computer 12 of the power company 11. And the data of the sales amount and the sales destination are transmitted. The power company 11 accumulates the data of the power sales amount and the sales destination received from the distributed power supply site A, and transmits the data of the power sales amount to the distributed power supply site controller 7B of the other distributed power supply site B serving as the sales destination via the Internet 9. To send over. The distributed power source site controller 7B of the distributed power source site B receives the power sale information from the computer 12 of the power company 11, and receives the power purchased from the distributed power site A from the power company 11 via the power system 1. The electric power company 11 receives a brokerage fee from the distributed power source site A and / or the distributed power source site B according to the amount of the mediated electric power by a pay-as-you-go system. The settlement of the trading value of the electric power is performed via a network from a bank account in the name of the management union of the distributed power sources A and B. It goes without saying that power can be bought and sold between any of the distributed power supply sites C to N. In the distributed power source base B, each customer 3 uses the power purchased from the other distributed power source base A, but each customer 3 only has to pay a fee to the management association according to the power usage. .
[0097]
(Embodiment 2)
FIG. 6 is a configuration diagram illustrating a distributed power supply system according to Embodiment 2 of the present invention. The distributed power supply system 200 is characterized in that power is exchanged between the distributed power supply points A and B. The configuration of the distributed power supply points A and B constituting the middle system 2 of the distributed power supply system 200 is substantially the same as that of the first embodiment, but the distributed power supply points 201 and The difference is that a power storage system 202 is provided. A description will be given by taking two examples, a distributed power source site A and a distributed power source site B. The distributed power supply station 201 has a function of connecting the portable distributed power supply 204 and storing the power of the connected portable distributed power supply 204 in the power storage device 202. As the portable distributed power supply 204, a distributed power supply truck 203, a distributed power supply vessel 206, and the like can be used.
[0098]
When the power of the distributed power site A is insufficient and the power of the distributed power site B is insufficient, the power shortage information is transmitted from the distributed power site controller 7A of the distributed power site A via the Internet 9 to the distributed power site of the distributed power site B. Sent to controller 7B. It should be noted that a sales contract is made between the distributed power site A and the distributed power site B to exchange power on the network. A distributed power source truck 7 on which a micro gas turbine 204 as a distributed power source is mounted is connected to the distributed power source station 7B of the distributed power source site B (indicated by a dotted line in the figure). The distributed power source site controller 7B of the distributed power source site B stops the power supply by the distributed power source truck 203 based on the shortage information from the distributed power source site A, and disconnects the distributed power source truck 203 from the distributed power source station 201B.
[0099]
The separated distributed power supply truck 203 moves from the distributed power supply location B to the distributed power supply location A, and is connected to the distributed power supply station 201A of the distributed power supply location A. At the distributed power source site A, power is supplied from the micro gas turbine 204 of the distributed power source truck 203. This power supply amount is stored in the distributed power supply site controller 7A of the distributed power supply site A, and transmitted by the distributed power supply site controller 7B of the distributed power supply site B via the Internet 9. The distributed power site B charges the distributed power site A in accordance with the supplied electric energy, and the distributed power site A transfers the account of its own management union to the management union of the distributed power site B via the Internet 9. Transfer.
[0100]
Here, the installation location of the distributed power station 201 is preferably a gas station GS. This is because the gas station GS is provided with a tank 205 for storing fuel underground, and the fuel of the micro gas turbine 204 can be stored in the tank 205. In addition, since there is a gas station GS that has not been used recently, it is suitable as the distributed power station 201 in Japan where land is small. The distributed power supply truck 203 operates the micro gas turbine 204 by receiving fuel supply from the tank 205 of the gas station GS.
[0101]
Further, the distributed power source of the distributed power source truck 203 may be a fuel cell in addition to the micro gas turbine 204. Furthermore, a ship that can be connected to the distributed power station 201 may be not only the distributed power truck 203 but also a ship. In the case of the distributed power source vessel 206, the distributed power source 204 can be equipped with a large-sized generator such as a gas turbine or a diesel engine and a fuel tank. In this case, the distributed power station 201 is preferably installed in a port. In particular, it is useful for power transmission to factory areas adjacent to ports. Further, since a normal ship is equipped with a diesel engine, power may be supplied from a driving diesel engine during berthing.
[0102]
Next, the power storage system 202 of the distributed power station 201 is useful when it is predicted that power shortage will occur in advance. For example, the distributed power supply truck 203 is connected to the distributed power supply station 201A before the power shortage of the distributed power supply site A occurs, and the power generated by the micro gas turbine 204 of the distributed power supply truck 203 is stored in the power storage system 202A. This eliminates the need for the distributed power supply truck 203 to reside at the distributed power supply station 201A at the time when power is required, and can move to the next distributed power supply base. The power storage system 202 includes a flywheel system that converts surplus power into flywheel rotational energy and stores it, a battery storage system that stores surplus power in a sodium-sulfur battery, and a superconducting system that confines surplus power in an electric circuit in a superconducting state. A system such as a coil can be used. In addition to this, the power storage system can also store the surplus power of the distributed power source base. By storing the surplus power, power can be supplied almost in its own distributed power source base. The customer 3 that supplies the surplus power to the power storage system 202 measures the amount of power using a customer controller (not shown), and transmits data on the amount of stored power to the distributed power supply site controller 7. The decentralized power supply site controller 7 stores the power storage amount of each customer 3.
[0103]
The decentralized power supply site controller 7 permits the stored customer 3 to return power within the range of the stored power. In addition, when the returned electric energy is smaller than the stored electric energy, the stored consumer 3 can pay for the remaining electric power from the price of the electric power supplied to the other consumers 3. On the other hand, when the customer 3 who has stored power receives power supply in excess of his own power storage amount, he pays for the excess power amount to the management association of the distributed power source base. In addition, surplus power can be converted into a different substance and stored and transported. For example, hydrogen 207 is generated by surplus power, and the hydrogen 207 is stored. The conversion of hydrogen 207 into electricity is performed using a fuel cell (not shown). Further, oxygen and ozone generated during hydrogen generation may be used for water purification, sewage treatment, and the like. Further, if hydrogen itself is transported from the distributed power source site B to the distributed power source site A, and power is generated by the fuel cell at the distributed power source site A, power can be substantially transmitted.
[0104]
According to the distributed power supply system 200 described above, power can be exchanged between the distributed power supply points A and B. Further, since the distributed power source 204 can be added when necessary, there is no need to install a spare distributed power source or prepare a distributed power source having a large power generation amount. Therefore, the distributed power supply system 200 can be configured at low cost. In addition, power can be exchanged between the distributed power sites A and B without passing power through the power system.
[0105]
(Embodiment 3)
FIG. 7 is a configuration diagram showing a distributed power supply system according to Embodiment 3 of the present invention. This distributed power supply system has substantially the same configuration as the distributed power supply system 100 according to Embodiment 1, but is characterized in that a plurality of distributed power supply site controllers exist. In this distributed power supply system 300, a large number of customers 3 exist in a distributed power supply base A constituting the middle system 2, and a customer controller 6 of the customer 3 is connected to a distributed power supply base controller 7 via the Internet 9. Connected to The distributed power source site controller 7 constructs a virtual distributed power source site controller 301 in a program inside a computer.
[0106]
The virtual distributed power supply site controller 301 groups predetermined customers 3 out of a large number of customers 3 and treats this group as one virtual distributed power supply site 302. As described above, the customers 3 include a plurality of types of customers 3 having different power usage modes, and the combination of the customers 3 changes economical efficiency, reliability, and the like in the distributed power source base A. . For example, even if large factories that are the same customers 3 constitute the distributed power source base A, the amount of electric power to be used is large and the peak of the electric power use is often in the same time zone. And you have to buy electricity from a power company. Further, when a distributed power supply malfunctions, it cannot be compensated by another distributed power supply, and a problem occurs in the reliability of the entire system.
[0107]
For this reason, in the distributed power supply system 300, the optimal combination is selected by the customers 3 from a large number of customers 3, or the distributed power supply site controller 7 automatically selects and performs grouping. Further, since it is free for the customer 3 in the distributed power supply site A to participate in the distributed power supply system 300, the system is targeted only to the customer 3 who has issued a request for participation in the distributed power supply system 300. To build. Of course, it is also possible to withdraw after joining. FIG. 8 shows an example of a preferable combination of consumers. When the customer 3 includes a convenience store 31, a factory 32, a school 33, a hospital 34, and a general home 35, for example, as shown in the customer 3 surrounded by a frame 36 in FIG. Small convenience store 31, a school 33 that finishes relatively early in the daytime, a hospital 34 that is open from morning to night and uses a small but constant power, and a general household 35 that starts using power mainly in the evening , A combination can be realized in which the total power consumption is relatively stable throughout the day. In addition, since the number of the general homes 35 is larger than the number of the other consumers 3, it is also a preferable means to perform the overall adjustment based on the number of the general homes 35.
[0108]
Further, even if the same factory 32 is used, for example, the factory 32a mainly operating at night and the factory 32b which is closed at night as shown by the frame 37 in FIG. It will be easy to combine. Further, in the case of a relatively large-scale customer 3 such as a factory 32, a hospital 34, a school 33, or the like, it is easy to assemble if the power use state is different (for example, a combination surrounded by a frame 38). In order to perform such a combination, the distributed power source site controller 7 has a database 10 of the power use state of each customer 3.
[0109]
FIG. 9 is a flowchart showing a grouping process of the distributed power supply system. In the distributed power supply system 300, first, a specific customer 3 and the customer 3 can cooperate to create a unique virtual distributed power supply base 302. Second, the distributed power supply site controller 7 can automatically combine the customers 3 to form the virtual distributed power supply site 302. First, when there is a participation request from a large number of customers 3 (step S1), it is registered in the distributed power source site controller 7 (step S2), and it is determined whether or not an arbitrary destination is designated by the customer 3 (step S2). Step S3). Here, an arbitrary participant refers to another customer 3 or an individual group after grouping (virtual distributed power source base 302). Since there is no group to participate in at the time of the first grouping, comparison is made between the customers 3. When there is no request for the designation of the participant between the customers 3, the registered many customers 3 are arbitrarily grouped (step S4). On the other hand, when there is a designation of the participation destination, the customers 3 whose participation requests match are grouped as one group (steps S5 and S6). By this grouping, a plurality of virtual distributed power sites 302 are constructed in the distributed power site A. In particular, when the contracted customers 3 form one group, it means that the original virtual distributed power base 302 including only the customers 3 is formed.
[0110]
Further, the distributed power source site controller 7 constructs a virtual distributed power source site controller 301 for managing and controlling the distributed power source 4 and the load 5 of the customers 3 in the group for each group. Although the virtual distributed power supply site controller 301 actually shares the hardware computer having the distributed power supply site controller 7, the virtual distributed power supply site controller 301 that is different for each group is constructed and provided on a program. As a result, a plurality of virtual distributed power site controllers 301 exist in the distributed power site controller 7, and these virtual distributed power site controllers 301 are connected to the grouped consumer controllers 6 via the Internet 9. . In particular, the group of the contracted customers 3 owns the bespoke virtual distributed power supply site controller 301 in the distributed power supply site controller 7.
[0111]
Then, the virtual distributed power site 302 is operated for each group until the distributed power site controller 7 receives a new participation request (step S7). When there is a participation request from the new customer 3, the registration is performed in the distributed power supply site controller 7 in the same manner as described above. Here, the customer 3 who makes a new participation request to the already formed group has acquired the information of the group via the Internet, and specifically, operates the list of the customers 3 of the group, profitability, and the like. Information such as the evaluation of the state and the stability is disclosed to each customer 3 on the Web site of the distributed power source base controller 7, and the destination of the group to participate can be designated based on this information and the like. This designation information is decrypted by the distributed power source site controller 7 (step S3), and is collated with the conditions for joining this group (step S5). The participation condition may be determined between the grouped customers 3 or may be automatically determined by the distributed power supply site controller 7 based on a criterion of whether efficient operation can be performed. If the result of the comparison with the participation conditions indicates that the participation is permitted, the new customer 3 is grouped to the participation destination. If participation is not permitted, the distributed power supply site controller 7 groups the new customers 3 into an arbitrary group.
[0112]
Of course, when a plurality of customers 3 make a participation request in order to create a new group (virtual distributed power supply base 302), the distributed power supply base controller 7 uses the original virtual distributed power supply base 302 and virtual controller Build 301. As a result, the customers 3 who cooperate for some reason for business can freely form a virtual distributed power supply system and efficiently operate it. In addition, the cancellation of the cooperative relationship may be determined by the consumers 3.
[0113]
The basis for the automatic grouping is whether or not the above-described efficient and stable operation can be performed. For this reason, the participants and the new participants are required to use their own distributed power supply 4. Information such as details and an average power usage state must be transmitted to the distributed power supply site controller 7. The distributed power source site controller 7 stores these pieces of information in a database. A specific combination of consumers can not be individually described in detail because the power usage state varies depending on the customer 3. However, main information such as the details of the distributed power source 4 of the customer 3 and the average power usage state is described. By obtaining, it is possible to automatically determine a preferred combination. The information of the customer 3 to be transmitted to the distributed power source base controller 7 includes, for example, the following.
(1) Type and rated output of distributed power supply 4, date of manufacture, maintenance record, recall information, manager and its qualifications
(2) 5 types of loads, planned to be added
▲ 3 ▼ Type of customer 3, address, business description and time, capital status, last year's power usage status
[0114]
Note that the automatic combination by the distributed power source base controller 7 is intended to determine an economical and stable combination and to group the customers 3, so that all the combinations are simply performed as in the first embodiment. As compared with the case where the customers 3 are grouped together, there may be a situation where the customers 3 that are not suitable for the optimal operation of the system cannot participate in the distributed power supply system 300. On the other hand, if the distributed power supply 4 and the load 5 have performances that can be considered normally, there is no problem in participating in the distributed power supply system 300. That is, it is considered that the customer 3 who is not qualified to participate in the system 300 has some cause, and the cause is a. When the output decrease can be easily predicted due to insufficient maintenance of the distributed power source, b. When the decentralized power source clearly malfunctions due to lack of fuel purchase funds, c. If the life of the distributed power source has already passed, d. If the distributed power supply has a design flaw, e. If the load is too large for the distributed generator, f. It is conceivable that the distributed power source remains unchanged despite the fact that the load is expected to increase.
[0115]
FIG. 10 is a flowchart showing a process up to permission to participate in the distributed power supply system. When participating in the distributed power supply system 300, the customer 3 who is a participant must transmit the customer information of the customer 3 to the distributed power supply site controller 7 (step S1). The distributed power supply site controller 7 determines whether or not the customer 3 is eligible to participate in the distributed power supply system 300 based on the customer information (step S2). The criterion is whether or not the above-mentioned reasons a to f are satisfied. The customer information is compared with the reasons a to f, and if the corresponding reason does not exist, it is determined that the customer is qualified to participate. Judge that you are not eligible to participate. The customer 3 who has determined that he or she does not have the participation qualification is once notified that participation in the distributed power supply system 300 is refused (step S3), and transmits an improvement plan from the distributed power supply site controller 7 (step S4). For example, the decentralized power supply site controller 7 points out the relevant problem, and sends a specific improvement method to the customer controller 6 via the Internet 9 and presents it. If it is determined that there is a participation qualification, participation is permitted (step S8).
[0116]
The customer 3 whose participation has been rejected implements an improvement measure and transmits the effect together with the customer information from the customer controller 6 to the distributed power source base controller 7 (steps S5 and S6). Then, when it is determined by the distributed power source base controller 7 that the customer does not correspond to any of the reasons a to f (step S7), a new participation qualification for the distributed power system 300 can be obtained (step S8). . In addition, improvements can be made and retransmissions can be repeated until qualification is obtained. The virtual distributed power site 302 and the virtual distributed power site controller 301 constructed by the grouping have the same functions as the distributed power site A and the distributed power site controller 7 shown in the first embodiment, and have the same functions as the above. The system is managed and operated by the method.
[0117]
As described above, in the distributed power supply system 300 according to the third embodiment, the customers 3 can construct the original virtual distributed power supply site 302 and the virtual distributed power supply site controller 301 and independently manage them. Other customers 3 are automatically grouped. As a result, the distributed power supply system 300 can be operated economically and stably.
[0118]
(Embodiment 4)
FIG. 11 is a configuration diagram showing a distributed power supply system according to Embodiment 4 of the present invention. The distributed power supply system 400 performs power interchange between a plurality of distributed power supply sites A and B, and is characterized in that microwave power transmission is performed as a means for the interchange. The distributed power stations A and B, which are the middle system 2 connected to the power system 1, have the same configuration as in the first embodiment, and further include a power storage system 401 and a microwave transmission / reception system 402. In particular, even when the power systems 1 are not connected by electric wire cables, power can be interchanged between the distributed power sites A and B.
[0119]
A power storage system 401 such as a flywheel system is provided in a part of the middle system 2. The power storage system 401 receives a microwave power transmitting antenna 403 formed by integrating plate-shaped semiconductors, and receives microwaves. A power receiving antenna 404 is provided. As a relay means for microwave power transmission, an artificial satellite 405 is used. The artificial satellite 405 is also provided with a power receiving antenna 406 for receiving microwaves and a microwave power transmitting antenna 207.
[0120]
The surplus power stored in the power storage system 401B at the distributed power source base B is converted into microwaves m, transmitted from the power transmitting antenna 403 to the artificial satellite 405, and received by the power receiving antenna 406 of the artificial satellite 405, Power is transmitted to the ground from the power transmission antenna 407 as it is. The transmitted microwave m is received by the power receiving antenna 404 at the distributed power source site A, and is converted from the microwave m into electric power. This electric power is temporarily stored in the power storage system 401A of the distributed power source base A.
[0121]
According to the above configuration, it is possible to exchange power between different distributed power supply points A and B. In particular, since power transmission can be performed between the distributed power sites A and B in a state where the power system 1 is not connected by a cable, power can be interchanged between remote islands or when a different power company operates. This is useful when, for example, power is to be exchanged between distributed power supply sites constructed in a power system. When power is transmitted using an artificial satellite, power can be exchanged even when the distributed power source base A or B exists in a foreign country. For this reason, the surplus power of the distributed power source base B in the country where the power price is low can be transmitted to the distributed power source base A in the country where the power price is high. In addition to using the artificial satellite 405, a microwave antenna may be relayed by attaching a power receiving antenna and a power transmitting antenna to an intermediate lighthouse. Further, the microwave m is directly transmitted from the power transmitting antenna 403 of the distributed power source site A, and the microwave m is received by the power receiving antenna 404 of the distributed power source site B or vice versa. Electricity may be interchanged.
[0122]
(Embodiment 5)
FIG. 12 is a configuration diagram showing a distributed power supply system according to Embodiment 5 of the present invention. This distributed power supply system 500 has a structure in which power is exchanged between distributed power supplies 4 in each distributed power supply base. Each distributed power supply 4 has an overlap switch 501 constituted by two switches 502 and 503. Is provided. The switch 502 of the overlap switch 501 is connected to the middle system 2 of the power system 1, and the other switch 503 is connected to the distributed power system 504 that connects the distributed power sources 4 to each other. I have. In addition, the consumers 3A to 3C will be described as an example.
[0123]
When receiving power supply from the power system 1, the switch 502 of each overlap switch 501 is closed and the switch 503 is opened. Next, when power is exchanged between the distributed power sources 4 in the distributed power source site A, the switches 503 of each overlap switch 501 are closed, and both switches 502 and 503 are closed. The container 502 is opened. Thereby, power can be supplied to the load of the distributed power supply 4 without interruption. Further, the switch 503 of the overlap switch 501 having a specific load may be connected to the distributed power supply system 504. For example, the switches 502B and 502C of the overlap switch 501B and the overlap switch 501C are opened, the switches 503B and 503C are closed and connected to the distributed power system 504, and the switch 503A of the overlap switch 501A is closed. The switch 502A is opened and connected to the middle system 2, the load 4A receives power supply from the power system 1 and the distributed power source, and the other loads 4B and 4C obtain power by mutual power exchange between the distributed power source 4. .
[0124]
In this way, each of the customers 3A to 3C can freely select the power interchange. Further, by using the overlap switching device 501, a power failure due to power interchange does not occur.
[0125]
FIG. 13 is a configuration diagram showing a modification of the distributed power supply system according to Embodiment 5 of the present invention. The distributed power supply system 550 has substantially the same configuration as the distributed power supply system 500, except that the distributed power supply 4C of the customer 3C is used as a common power supply. That is, the customers 3A and 3B are provided with the overlap switches 501A and 501B, and the customer 3C is not provided with the overlap switches, and the distributed power supply is connected to the distributed power supply system 504. I have. When receiving power supply from the power system 1, the switch 502 of each overlap switch 501 is closed and the switch 503 is opened. Next, when power is exchanged between the distributed power sources 4 in the distributed power source site A, the switches 503 of each overlap switch 501 are closed, and both switches 502 and 503 are closed. The container 502 is opened. Thereby, power can be supplied to the load of the distributed power supply 4 without interruption.
[0126]
Further, similarly to the above, the load 5B can be connected to the distributed power supply system 504, and the load A can be connected to the middle system 2. In that case, the switch 502A of the overlap switch 501A may be closed, the switch 503A may be opened, the switch 502B of the overlap switch 501B may be opened, and the switch 503B may be closed. Such a configuration has an advantage that the wiring structure is simple, and is particularly effective when the capacity of the distributed power supply 4C is larger than the capacity of the distributed power supplies 4A and 4B.
[0127]
(Embodiment 6)
FIG. 14 is a configuration diagram showing a distributed power supply system according to Embodiment 6 of the present invention. This stabilized power supply system 600 aims to stabilize the power supply in the distributed power source base described in the first to fourth embodiments. The stabilized power supply system 600 is configured to supply power to a load by system-linking a commercial system (power system) and a self-powered system, and specifically, a power purchase bus 61 supplied with power from a power company. And a self-generated bus 63 supplied with power from a distributed power source 62 of a self-generated power system. A high-speed current-limiting device 64 for instantaneous voltage reduction is provided between the purchased bus 61 and the self-generated bus 63. An interconnection circuit breaker 70 is provided. The power purchase bus 61 is connected to one or a plurality of general loads 65 that are allowed to have an instantaneous voltage drop (including a power failure). On the other hand, a plurality of important loads 66 that are not allowed to sag are connected to the self-generated bus 63. Examples of the important load 66 include a personal computer, an electromagnetic switch, and a semiconductor manufacturing device. Examples of the general load 5 include an electric lamp in an office, cooling and heating, and the like. The classification of the important loads 66 and the general loads 65 is performed on the basis of those for which voltage sag is technically not allowed and those for which economical sag is not desirable.
[0128]
Further, a commercial power supply wiring 67 of another system is drawn out from the power purchasing bus 61 (first system A), and is linked to the respective important loads 66 after branching. In the present embodiment, the middle system of the first to fourth embodiments includes a power purchasing bus 61, a self-generated bus 63, and a commercial power supply wiring 67. An overlap switch 68 is provided at a link point between the self-generated bus 63 (second system B) and the first system A. The overlap switch 68 performs switching from the first system A to the second system B or switching from the second system B to the first system A after a period in which the first system A and the second system B are used together. Has functions. The high-speed current limiting circuit 64 has a structure in which a reactor is combined with a rectifier-type mixing bridge using a thyristor and a diode. The control device 9 is composed of a general-purpose PLC (Programmable Logic Controller) or a general-purpose computer and predetermined software, and controls the high-speed current-limiting device 64, the overlap switch 68, and the distributed power source 62. As the distributed power source 62, one or a combination of a gas turbine, a micro gas turbine, a diesel engine, a fuel cell, and the like can be given.
[0129]
Further, the distributed power supplies 62 are mutually connected by a distributed power supply system 504. In addition, the distributed power supply 62 is provided with an overlap switch 501 constituted by two switches 502 and 503. The switch 502 of the overlap switch 501 is connected to the commercial power supply wiring 67 of the power system 1, and the other switch 503 is connected to the distributed power system 504. The functions and effects of the overlap switch 501 and the distributed power system 504 are the same as those described in the fifth embodiment.
[0130]
Although a plurality of distributed power supplies 62 are described, they can be treated as substantially one distributed power supply by the connection of the overlap switch 501 and the distributed power supply system 504. In the following description, it is assumed that the overlap switching device 501 is switched to operate while performing power interchange between the distributed power sources 62.
[0131]
FIG. 15 is a configuration diagram showing the structure of the overlap switch 68. As shown in FIG. The overlap switch 68 has a structure in which two switches 81 and 82 are combined. One switch 81 is connected to the first system A, and the other switch 82 is connected to the second system B. Further, one ends of both switches 81 and 82 are connected to the important load 66. Further, each overlap switch 68 is provided with a synchronization controller 83 for performing synchronization control between the first system A and the second system B. This is necessary when individually switching important loads from the self-powered system to the commercial system (details will be described later).
[0132]
Next, the operation of the stabilized power supply system 100 will be described. FIG. 16 is a flowchart showing the operation of the stabilized power supply system. In the case of the initial operation in which the distributed power supply 62 is not operated or has not reached the rated operation (step S1), the overlap switch 68 is switched to connect the first system A and the important load 66, Power is supplied from the power purchase bus 61 to the important load 66 via the first system A. In addition, the power of the distributed power source 62 prepares conditions for entering the synchronous operation with the power purchase bus 61 from the self-generated bus 63 via the high-speed current-limiting circuit breaker 64 and the interconnection breaker 70.
[0133]
Next, after the distributed power supply 62 reaches the steady operation and reaches the synchronous operation with the first system (step S2), the overlap switch 68 is switched from the first system A to the second system B. In this procedure, first, the first system A and the important load 66 are connected by one switch 81, and then the second system B and the important load 66 are connected by the other switch 82. Both the first system A and the second system B are connected (step S3). At this time, the power purchasing bus 61 and the self-generated bus 63 are system-linked by the high-speed current-limiting circuit breaker 64 and the high-speed circuit breaker 70, and have already been synchronized. Subsequently, the switch 81 is opened to disconnect the first system A, and only the second system B is connected (step S4). By this overlap switching, the uninterruptible switching for the important load 66 can be performed.
[0134]
In the state where the operation is switched to the second system B, the normal operation is performed (step S5), and each important load 66 enters below the self-generated system by the distributed power source 62 by the power flow control and is separated from the first system A. As a result, the important load 66 is operated only by the self-powered system, and receives power supply from the distributed power source 62 from the beginning even if a voltage sag occurs due to a lightning strike or the like in any of the commercial systems. Since the current limiting and the high-speed interruption are performed by the high-speed current limiting interruption device 64, the instantaneous sag hardly affects the important load 66. The switching of the important load 66 is performed based on a command from a control device 69 that monitors the operation state of the distributed power supply 62.
[0135]
Also, when switching from the second system B to the first system A, both the second system B and the first system A are once connected and then the second system B is disconnected. Examples of such reverse switching include maintenance work, additional installation, and replacement of the distributed power supply 62. Here, the capacity of the distributed power supply 62 is the sum of all the capacities of the important loads 66. However, there is almost no load fluctuation of the autonomous system at the time of a momentary voltage drop, and the overlap switch 68 is the most important. Since it is attached to the load, the required load capacity is relatively accurately determined, and it is sufficient if the power generation has the required minimum capacity. For this reason, the performance of the distributed power source 62 can be appropriately suppressed, and the equipment cost can be reduced. In addition, a diesel engine or the like having low adaptability to load fluctuation can be used as the distributed power source 62.
[0136]
Of course, in the normal operation state, the surplus electric power of the distributed power source 62 can be sold to the commercial power company linked to the system via the high-speed current limiting cutoff device 64 (the high-speed current limiting cutoff switch is in the ON state). Further, in the stabilized power supply system 600, the existing load can be treated as the important load 66 by installing the overlap switch 68 at the connection point between the first system A and the second system B. That is, in this stabilized power supply system 600, the first system may be provided from the beginning, and the overlap switch 68 is provided at a point where the first system A is directly linked to the second system B. Since it suffices to provide them, the important load 66 can be easily added in terms of equipment. This important load 66 may be handled as an important load 66 by attaching an overlap switch 68 to an existing load, or a new load may be installed together with the overlap switch 68 and handled as an important load 66. good.
[0137]
Further, in the stabilized power supply system 600, the capacity of the high-speed current-limiting circuit breaker 64 can be reduced. The reason is as follows. FIG. 17 is a flowchart illustrating an example of switching from a commercial system to a self-generated system. First, assume that the commercial power is initially 150 kW, the self-generated power is 0 kW, and the loads of the important loads 66a to 66c are each 50 kW. Further, the capacity of the high-speed current limiter 64 is set to 100 kW. When the output of the distributed power source 62 is increased to 100 kW from this state (step S1), the commercial power is sufficient at 50 kW. At this time, since the overlap switch 68 is connected to the commercial system, the high-speed current-limiting device 64 Causes a 100 kW power flow.
[0138]
Next, when the important load 66a is switched from the commercial system to the self-generating system, in a state where both the switches 81 and 82 of the overlap switch 68 of the important load 66a are closed, the electric power in the commercial system and the self-generating system is closed. The flow is determined by the system impedance. Subsequently, when the switch 81 of the overlap switch 68 is opened to connect the important load 66a to the distributed power supply 62 (step S2), 50 kW of electric power of the distributed power supply 62 is supplied to the important load 66a via the second system B. You. Also, in this state, there is a margin of 50 kW in the output of the distributed power supply 62, so that a power flow of 50 kW occurs in the high-speed current-limiting device 64 from the autonomous system to the commercial system. In addition, the commercial power at this time is 100 kW obtained by adding the 50 kW to the original 50 kW.
[0139]
Next, when switching the important load 66b from the commercial system to the self-generating system, both the switches 81 and 82 of the overlap switch 68 of the important load 66b are closed, and then the switch 81 is opened to distribute the important load 66b. When connected to the power supply 62 (step S3), 50 kW of power of the distributed power supply 62 is supplied to the important load 66a via the second system B. In this state, since the output 100 kW of the distributed power supply 62 is consumed by the important loads 66a and 66b, no power flow occurs in the high-speed current limiting breaker 64. In addition, the commercial power at this time is only 50 kW originally.
[0140]
Here, assuming that the important load 66c is switched from the commercial system to the self-generating system without increasing the output of the distributed power source 62, when the important load 66c is connected to the self-generating system by the overlap switch 68, the high-speed current limiting is performed. A power flow of 50 kW occurs in the shutoff device 64 from the commercial system to the self-generated system. With this amount of power, there is no problem because the capacity of the high-speed current limiter 64 is 100 kW, but if the load of the important load 66c is 150 kW, for example, an electric power flow exceeding the capacity of the high-speed current limiter 64 is caused. This means that the high-speed current-limiting device 64 of the capacity must be prepared. Therefore, the size of the high-speed current limiter 64 is increased, which leads to an increase in cost.
[0141]
In the present invention, when the important load 66c is switched, the output of the distributed power source 62 is increased to 150 kW (step S4), and in that state, the overlap switch 68 of the important load 66c is switched from the commercial system to the self-generating system (step S4). S5). In this state, a 50 kW power flow from the self-powered system to the commercial system occurs in the high-speed current limiter 64 before switching, and the power flow becomes 0 kW after switching. Even if the load of the important load 66c is 150 kW as in the above example, if the output of the distributed power supply 62 is increased to 150 kW to 250 kW and then the overlap switch 68 of the important load 66c is switched, the high-speed current limiting interruption is performed. The power flow in the device 64 is kept between 0 kW and 100 kW.
[0142]
In other words, by executing the above switching method, it is not necessary to prepare the high-speed current limiting device 64 having a capacity corresponding to the output of the distributed power source 62 (at least the amount of power when all the important loads 66 are operated). A small-capacity high-speed current-limiting device 64 can be used. In the above description, the important loads 66a to 66c are taken as an example. However, the same steps as described above are repeated by the number of the important loads 66, and all the important loads 66 are changed from the first system A of the commercial system to the third system of the autonomous system. Switch to system B.
[0143]
The above operation of the overlap switch 68 is performed based on a command from a control device 69 that monitors the operation status (output, etc.) of the distributed power supply 62. When a plurality of important loads 66 are sequentially switched to the autonomous system, the order of the important loads 66 to be switched is determined according to a program stored in the storage unit of the control device 69. For example, the order in which the important loads 66 are switched may be fixed in advance, or the order in which the important loads 66 are switched according to the amount of power generated by the distributed power source 62 may be switched.
[0144]
Also, in the above example, as shown in the flowchart of FIG. 17, the load of the important load 66 and the output control of the distributed power supply 62 have been described with specific examples. However, when this is generalized, the flowchart of FIG. Become like That is, by increasing the output of the distributed power supply 62 to a predetermined value (step S1) and performing the overlap switching of the specific important load 66, it is determined whether or not a power flow larger than the capacity occurs in the high-speed current limiter 64. A decision is made (step S2). More specifically, the control device 69 determines the current total load of the important loads 66 (for example, the important loads 66a and 66b) that have already been switched to the autonomous system and the important load 66 that is to be newly switched (for example, the important load). 66c) is compared with the current output amount of the distributed power source 62, and the difference between the planned load amount of the important load 66 and the current output amount of the distributed power source 62 is determined by the high-speed current-limiting device. If the capacity exceeds 64, it is determined that a power flow larger than the capacity occurs. When it is determined that a power flow larger than the capacity is generated, the power flow is controlled so that the output of the distributed power supply 62 is increased so that the power flow is equal to or smaller than the capacity (steps S1 and S2).
[0145]
On the other hand, when it is determined that the generated power flow is equal to or less than the capacity of the high-speed current limiting interrupter 64, the new important load 66 to be switched is switched (step S3). That is, if the current output amount of the distributed power supply 62 increases and the difference from the planned load amount falls within the capacity of the high-speed current-limiting circuit breaker 64, the control device 69 causes the overlap switch 68 to transfer the important load 66 to the commercial system. Switch to autonomous system. Then, the procedures of steps S1 to S3 are performed until all the important loads 66 are switched from the commercial system to the self-generating system (step S4). Note that the determination reference value is based on the case where the difference between the planned load amount and the current output amount exceeds the capacity of the high-speed current limiter 64. However, the determination may be made with a predetermined margin. For example, the capacity may be set so as not to exceed 90% of the capacity of the high-speed current-limiting device 64, or may be set so as not to exceed 110% of the capacity.
[0146]
By performing such a switching procedure, the capacity of the high-speed current limiter 64 can be reduced. Specifically, it is possible to use a high-speed current-limiting device 64 having a smaller capacity than the total load of all the important loads 66 (compared to this, if the important loads 66a to 66c are switched at one time under the conditions of FIG. 4). , The capacity of the high-speed current limiter 64 needs to be 150 kW). Further, the high-speed current limiter 64 only needs to have a larger capacity than the load of the critical load 66 which is the maximum load among all the critical loads 66. In other words, if the important loads 66 are switched one by one, the difference between the current output amount and the scheduled load amount only needs to be within the capacity of the high-speed current-limiting device 64. It suffices if the capacity of the high-speed current limiter 64 is large.
[0147]
Further, in the stabilized power supply system 600 according to the present embodiment, since the overlap switch 68 of the important load 66 can be selectively switched by the control device 69, of the loads having the overlap switch 68, Only a specific load can be treated as the important load 66. That is, the normal plural important loads 66 are further classified into the most important loads (for example, 66a and 66b) and the mere important loads (for example, 66c and 66d) in advance or as appropriate, and the switching of the overlap switch 68 is controlled. I do.
[0148]
This is useful, for example, when the amount of power generated by the distributed power source 62 differs over time due to maintenance or the like. If any one of the plurality of distributed power sources 62 is stopped for maintenance or the like, it becomes difficult to cover all the important loads 66. Therefore, if power is supplied preferentially to only the specific important loads 66a and 66b within the range of the currently supplied power amount, the instantaneous voltage drop of the most important loads 66a and 66b can be reliably prevented. FIG. 19 is a flowchart illustrating an example of a procedure for supplying power to the most important load. First, the control device detects the amount of power generated by the entire distributed power supply 62 (step S1).
[0149]
Next, it is determined whether or not the power of all the important loads 66 can be covered by the total power generation (step S2). Power is supplied to the important load 66 (step S3). On the other hand, if all the important loads 66 cannot be covered, the most important loads 66a and 66b are extracted from the plurality of important loads 66 according to the procedure stored in the storage unit of the control device 69 (step S4). In this extraction procedure, a predetermined load is selected, or a load to be prioritized at that time is automatically selected.
[0150]
Next, the controller 69 switches the overlap switches 68a, 68b of the extracted most important loads 66a, 66b to receive power supply from the private power system (step S5). On the other hand, the unextracted loads 66c and 66d are supplied with power from the first system A, and thus are affected by the sag of the commercial system. Then, the control device 69 monitors the fluctuation of the power generation amount of the distributed power supply 62 (step S6), and when the fluctuation occurs in the power generation amount, for example, when the distributed power supply 62 after maintenance is turned on, the total power generation amount is again reduced. It detects (step S1) and performs the processing of steps S2 to S6. In this way, even when the amount of private power generation is insufficient, the most important load is not affected by the sag.
[0151]
The synchronization control device 83 shown in FIG. 2 is installed between the first system A and the second system B. When the output of the distributed power source 62 is reduced due to, for example, a failure or maintenance, the synchronous control device 83 is overloaded with all the important loads 66. (Preferred) important load 66 must be returned from the autonomous system to the commercial system. At this time, if the high-speed current-limiting device 64 is open for maintenance or the like, power cannot be received in a synchronized state. Therefore, the synchronization control device 83 performs synchronization between the autonomous system and the commercial system. To return the specific important load 66 from the self-propelled system to the commercial system.
[0152]
Specifically, a synchronization control device 66 is provided in each overlap switch 68 and controls the synchronization between the first system A and the second system B. When the output of the distributed power source 62 decreases, the control device 69 monitors the output reduction, and activates the synchronous control device 83 of the specific important load 66 (for example, the most important load) according to a command from the control device 69. , And performs synchronous control of the first system A and the second system B. The switching from the second system B to the first system A is performed by the overlap switch 68 in a state where synchronization is established. Thus, the overload can be operated with the commercial power. In addition, by providing the synchronization control device 83 in each of the overlap changers 68, each of the important loads 66 (actually, at the time of simultaneously switching a plurality of loads, at least at one location) can synchronize the first system and the second system. , It is possible to quickly switch to the commercial system. Note that the important loads having the synchronization control device 83 need not be all the important loads. For example, it may be provided only for an important load in which an instantaneous voltage drop or a power failure cannot be tolerated.
[0153]
Even if the synchronization control device is not attached to the switches 81 and 82, the installation position is not limited to this as long as synchronization can be obtained for each overlap switch 68. Further, the predetermined important loads 66 may be grouped, and a common synchronous control device may be provided for the overlap switch 68 of the important loads in the group. In this way, the important load in the group can be quickly returned from the self-propelled system to the commercial system.
[0154]
In the above-described embodiment, the description has been given using the high-speed current limiting circuit breaker 64, but the high-speed current limiting circuit breaker 64 can be replaced with a normal circuit breaker. Employing a circuit breaker can reduce the cost of the entire system. On the other hand, if the high-speed current-limiting device 64 is used, it is possible to take a thorough measure against sag. In addition, since the cost per capacity of the high-speed current-limiting device 64 is high, if the capacity of the high-speed current-limiting device 64 can be reduced as in the present invention, remarkable cost reduction can be achieved. In any case, the use of the overlap switch 68 enables uninterruptible switching.
[0155]
【The invention's effect】
As described above, in the distributed power supply system according to the present invention, a distributed power supply base in which a middle power supply system is configured with respect to a power grid, and a distributed power supply and a load of a plurality of customers are connected in the middle power grid, A customer controller that is included in the base and manages and controls the distributed power supply and load in the distributed power base, and a customer in the distributed power base that is connected to the customer controller via a communication network and that is based on information from the customer controller. With the provision of the distributed power supply site controller that performs management control regarding power interchange between the power supplies, the economic efficiency and reliability of energy supply by the distributed power supply can be improved.
[0156]
Also, in the distributed power supply system of the present invention, a plurality of distributed power supply bases, in which a distributed power supply and loads of a plurality of customers are connected in the middle power supply system, and a plurality of distributed power supply bases, Is a plurality of customer controllers for managing and controlling the distributed power supply and load in the distributed power supply site, and the plurality of customer controllers are connected to the plurality of customer controllers via a communication network, and the single distributed power supply is based on information of the customer controller. Since a distributed power supply site controller is provided for performing management control regarding power interchange between consumers in the base, the economics and reliability of energy supply by the distributed power supply can be independently improved at each distributed power supply base.
[0157]
Further, in the distributed power supply system of the present invention, among the plurality of consumers, the customer controller of one of the customers transmits a power purchase request to the distributed power supply site controller, and the demand controller of the other The consumer controller of the house transmits the power sale request to the distributed power site controller, and the distributed power site controller combines the power purchase request and the power sale request based on a predetermined combination process, and from the one customer to another Since power is controlled so as to be bought and sold to customers, power can be traded smoothly and the economics and reliability of the distributed power source can be improved.
[0158]
Further, in the distributed power supply system of the present invention, when one of the customer requesting the power purchase and the customer requesting the power sale is singular, as the combination process, the single customer In this case, the single customer can operate the distributed power supply most economically.
[0159]
Further, in the distributed power supply system according to the present invention, when there are a plurality of consumers who request a power purchase and a plurality of customers who request a power sale as a combination process, the nearest purchase price and sale price among the required purchase prices and sale prices are provided. Are combined with each other, so that the customers associated with the combination can obtain the most satisfaction.
[0160]
Further, in the distributed power supply system of the present invention, the customer controller requesting power purchase cancels the power purchase request based on the selling price information from the customer controller requesting power sale. Can be prevented.
[0161]
Further, in the distributed power supply system according to the present invention, when the distributed power supply of any of the customers in the distributed power supply base malfunctions, the distributed power supply base controller disperses the other consumers to this customer. Since the power is controlled so as to be supplied from the power supply under predetermined conditions, the load operation can be continued even if the distributed power supply malfunctions, so that the reliability of the distributed power supply is improved.
[0162]
Further, in the distributed power supply system of the present invention, in the combination processing, the customer controller of one customer designates another customer whose combination is to be restricted, transmits the information to the distributed power supply base controller, and Since the controller does not combine the one customer with another designated customer, it is possible to prevent a power trading relationship with an unwilling partner from being established.
[0163]
Further, in the distributed power supply system of the present invention, the distributed power supply point controllers of the plurality of distributed power supply points substantially exchange power between the distributed power supply points via the power system, and the power company's fee collection means includes: Since the brokerage commission for the power purchase and sale between the distributed power sites is collected from the accounts of one or both of the distributed power sites, not only the consumers but also the power companies can make a profit.
[0164]
Further, in the distributed power supply system of the present invention, since the plurality of distributed power supply points each have a distributed power supply station connected to the middle system and connected to a distributed power supply mounted on a moving means such as a vehicle or a ship, the initial cost of the system is reduced. And the amount of power generation can be increased when necessary.
[0165]
Further, in the distributed power supply system of the present invention, the moving means is a vehicle, and the distributed power supply station uses a gas station having a tank underground, and stores fuel of the distributed power supply in this tank. It solves the problem of placing distributed power sources and is suitable for distributed power stations.
[0166]
Further, in the distributed power supply system according to the present invention, since the distributed power supply station includes the power storage means for storing the electric power supplied from the distributed power supply mounted on the connected moving means, the distributed power supply station restrains the moving means mounted with the distributed power supply. Without this, power can be supplied from the distributed power source.
[0167]
Further, in the distributed power supply system according to the present invention, since the power storage means can store the surplus power in the distributed power supply point, the reliability of power supply in the distributed power supply point can be improved.
[0168]
Further, in the distributed power supply system of the present invention, the distributed power supply system includes a distributed power supply site in which a middle power system is configured with respect to the power system, and a distributed power supply and loads of a plurality of consumers are connected in the middle power system. A customer controller for managing and controlling the distributed power supply and load in the distributed power supply site, and a group of specific customers among the plurality of customers based on predetermined conditions in the distributed power supply site. And a virtual distributed power supply site controller configured to correspond to the virtual distributed power supply site, connected to the customer controller via a communication network, and performing management control of the entire virtual distributed power supply site. Therefore, it is managed and controlled by a dedicated distributed power supply site controller, and efficient operation can be performed.
[0169]
Also, in the distributed power supply system of the present invention, the grouped virtual distributed power supply points are constituted by specific customers who have previously agreed to create virtual distributed power supply points. Operation of power supply bases can be performed.
[0170]
Also, in the distributed power supply system of the present invention, the virtual distributed power supply site controller determines whether or not to participate in the grouping based on the information of the customers who are going to participate in the virtual distributed power supply site. The operation is hardly hindered by a specific customer, and the reliability of the distributed power system is improved.
[0171]
Further, in the distributed power supply system according to the present invention, when there is a customer who intends to participate in the virtual distributed power supply base during grouping, the virtual distributed power supply base controller may impede the optimal operation of the system. When there is a request, a notification of refusal of participation is sent to the customer controller of this customer, so that the problem user can be prevented from participating and the system can be operated efficiently. Can be encouraged.
[0172]
Further, in the distributed power supply system according to the present invention, the virtual distributed power supply site controller sends a notification of improvement from the customer controller of the customer to the virtual distributed power supply site controller after performing the participation rejection notification, and thereby, Since participation is allowed, efficient operation of the system is promoted, and the economics and reliability of the distributed power source are improved.
[0173]
In the distributed power supply system according to the present invention, the plurality of distributed power supply points have a power transmission / reception system for transmitting and receiving microwaves between the distributed power supply points. Electricity can be exchanged between the distributed power supply sites.
[0174]
Further, in the operation method of the distributed power supply system according to the present invention, a plurality of consumers each having a distributed power supply and a load are connected to the power system in the distributed power supply base constituting the middle system, and the demand in the distributed power supply base is reduced. In managing and controlling the home controller by the distributed power site controller, a procedure for issuing a power purchase request from the customer controller of one of the plurality of customers to the distributed power site controller via the network, A procedure to issue a power sale request from the home customer controller to the distributed power site controller via the network, and the distributed power site controller determines the customer who issued the power purchase request and the customer who issued the power sale request And a procedure for performing power purchase and sale between these consumers based on the combination process of It can be smoothly power trading between.
[0175]
Further, in the operation method of the distributed power supply system according to the present invention, when one of the customer of the power purchase request and the customer of the power sale request is singular, the combination process is performed based on the required buy price and the sell price. Since the procedure includes a procedure of performing a combination that gives the greatest benefit to the customer, the power trading that maximizes the customer can be performed.
[0176]
Further, in the operation method of the distributed power supply system according to the present invention, the combination processing is performed in the case where there are a plurality of customers of the power purchase request and a plurality of customers of the power sale request, and the combination process is the closest from the required purchase price and the sell price. Since it includes the procedure of combining the customers who request the buy price and the sell price, it is possible for all the customers to perform a satisfactory power trade.
[0177]
Further, in the operation method of the distributed power supply system according to the present invention, the customer controller requesting power purchase includes a procedure for canceling the power purchase request based on the selling price information from the customer controller requesting power sale. In this way, it is possible to prevent the purchase of electric power and to prevent customers from requesting exorbitant prices, and to optimize the operation of the entire distributed power supply base.
[0178]
Further, in the operation method of the distributed power supply system according to the present invention, when the distributed power supply of any one of the customers in the distributed power supply base malfunctions, the distributed power supply of another customer is transmitted to this customer under a predetermined condition. Therefore, the reliability of power supply by the distributed power source can be improved.
[0179]
Further, in the operation method of the distributed power supply system according to the present invention, in the combination processing, a procedure in which one customer designates another customer who restricts the combination, and another demand related to the designation with the one customer This includes a procedure for preventing a combination with a house, so that a power trading relationship with an unwilling partner is not established.
[0180]
Further, in the operation method of the distributed power supply system according to the present invention, a plurality of consumers each having a distributed power supply and a load are connected to the power system in the distributed power supply base constituting the middle system, and the demand in the distributed power supply base is reduced. The home controller is managed and controlled by a distributed power supply site controller, and a plurality of such distributed power supply sites are connected to the electric power system. And the step of collecting an intermediary commission for power purchase and sale between the distributed power supply sites from the account of one or both of the distributed power supply sites via the network. And the utilities can benefit.
[0181]
Further, in the operation method of the distributed power supply system according to the present invention, a plurality of consumers each having a distributed power supply and a load are connected to the power system in the distributed power supply base constituting the middle system, and the demand in the distributed power supply base is reduced. The home controller is controlled and controlled by a distributed power supply site controller. Further, a plurality of such distributed power supply sites are connected to the electric power system, and in order to exchange power between the distributed power supply sites, the distributed power supply Since the power supply station is connected to the distributed power supply mounted on the moving means, power is supplied from the distributed power supply, so that the initial cost of the distributed power supply system can be kept low and power generation can be performed when necessary from the standpoint of the distributed power supply base. The amount can be increased.
[0182]
Further, in the operation method of the distributed power supply system according to the present invention, a plurality of consumers each having a distributed power supply and a load are connected to the power system in the distributed power supply base constituting the middle system, and the demand in the distributed power supply base is reduced. In managing and controlling the home controller by the distributed power supply site controller, a procedure of grouping specific customers among the plurality of customers based on predetermined conditions to construct a virtual distributed power supply site, and corresponding to the virtual distributed power supply site And a procedure for constructing a virtual distributed power supply site controller that performs management control of the entire virtual distributed power supply site, so that it is managed and controlled by a dedicated distributed power supply site controller, and efficient operation can be performed. .
[0183]
Further, in the operation method of the distributed power supply system according to the present invention, a plurality of consumers each having a distributed power supply and a load are connected to the power system in the distributed power supply base constituting the middle system, and the demand in the distributed power supply base is reduced. In managing and controlling the home controller by the distributed power supply site controller, the procedure to construct a virtual distributed power supply site by grouping specific customers who have decided to create a virtual distributed power supply site in advance and to respond to the virtual distributed power supply site And a procedure for constructing a virtual distributed power supply site controller that performs management control of the entire virtual distributed power supply location, so that the virtual distributed power supply location can be operated only by a specific customer.
[0184]
Further, the method for operating the distributed power supply system according to the present invention includes a procedure for determining whether or not to participate in the group based on the information of customers who are willing to participate in the virtual distributed power supply base. Thus, proper operation can be performed.
[0185]
Further, in the distributed power supply system operation method of the present invention, when there is a customer who intends to participate in the virtual distributed power supply base at the time of grouping, and when the customer is not suitable for optimal operation of the system, This includes a procedure for rejecting the participation of the user, thereby preventing the problem customer from participating, efficiently operating the system, and prompting the customer to improve the condition.
[0186]
In addition, the method for operating the distributed power supply system according to the present invention includes a procedure for allowing participation of the customer based on the notification of the improvement from the customer after the participation is refused. And promote the economics and reliability of distributed power sources.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing a distributed power supply system according to Embodiment 1 of the present invention.
FIG. 2 is an explanatory diagram showing a relationship among power generation output of various distributed power sources, power demand for each customer, and heat demand.
FIG. 3 is an example of a distributed power source operation status screen provided by a distributed power source site controller.
FIG. 4 is a conceptual diagram of a power interchange system.
FIG. 5 is a flowchart illustrating an example of a process performed by a combination program.
FIG. 6 is a configuration diagram illustrating a distributed power supply system according to Embodiment 2 of the present invention.
FIG. 7 is a configuration diagram showing a distributed power supply system according to Embodiment 3 of the present invention.
FIG. 8 is an explanatory diagram showing an example of a preferable combination of consumers;
FIG. 9 is a flowchart showing a grouping process of the distributed power supply system.
FIG. 10 is a flowchart illustrating a process up to permission to participate in the distributed power system.
FIG. 11 is a configuration diagram showing a distributed power supply system according to Embodiment 4 of the present invention.
FIG. 12 is a configuration diagram showing a distributed power supply system according to Embodiment 5 of the present invention.
FIG. 13 is a configuration diagram showing a modification of the distributed power supply system according to Embodiment 5 of the present invention.
FIG. 14 is a configuration diagram showing a stabilized power supply system according to Embodiment 6 of the present invention.
FIG. 15 is a configuration diagram showing a structure of an overlap switch.
FIG. 16 is a flowchart showing the operation of the stabilized power supply system.
FIG. 17 is a flowchart illustrating an example of switching from a commercial system to a self-generated system.
FIG. 18 is a flowchart showing a procedure for switching from a commercial system to an autonomous system.
FIG. 19 is a flowchart illustrating an example of a procedure for supplying power to the most important load.
[Explanation of symbols]
100 Distributed power system
A to N Distributed power supply base
1 Power system
2 Middle system
3 consumers
4 Distributed power supply
5 Load
6 Consumer controller
7 Distributed power supply site controller
9 Internet
10 Database
201 Distributed power station
202 Power storage system
203 Distributed Power Truck
204 Distributed power supply
206 Distributed Power Ship

Claims (35)

A distributed power source base that configures a middle grid for the power grid, and connects distributed power sources and loads of a plurality of customers in the middle grid;
A customer controller that is included in the distributed power site and manages and controls the distributed power and load in the distributed power site;
A distributed power station controller connected to the customer controller via a communication network and performing management control regarding power interchange between consumers in the distributed power station based on information of the customer controller;
A distributed power supply system comprising: A plurality of distributed power bases that configure a middle system with respect to the power system, and that connect distributed power sources and loads of a plurality of customers in the middle system,
Each distributed power supply site
A plurality of customer controllers for managing and controlling the distributed power supply and load in the distributed power supply base;
A distributed power supply site controller connected by a communication network with the plurality of customer controllers and performing management control regarding power interchange between customers in the one distributed power supply site based on information of the customer controller,
A distributed power supply system comprising: Among the plurality of customers, the customer controller of one customer sends a power purchase request to the distributed power supply site controller,
Among the plurality of customers, a customer controller of another customer sends a power sale request to the distributed power source base controller,
The distributed power supply site controller controls the power purchase request and the power sale request by combining them based on a predetermined combination process so as to trade power from the one customer to another customer. Or the distributed power system according to 2. The combination process, when one of the customer of the power purchase request and the customer of the power sale request is singular, based on the required buy price and sell price, perform the combination that provides the most benefit to the single customer. The distributed power supply system according to claim 3, wherein: In the combination process, when there are a plurality of consumers of the power purchase request and a plurality of customers of the power sale request, the customers who request the closest buy and sell prices among the required buy and sell prices are combined with each other. The distributed power supply system according to claim 3, wherein: The distributed power supply according to any one of claims 1 to 5, wherein the customer controller that requests power purchase cancels the power purchase request based on selling price information from the customer controller that requests power purchase. system. If the distributed power source of any of the customers in the distributed power source site malfunctions, the distributed power source site controller supplies power to the customer from the distributed power source of another customer under predetermined conditions. The distributed power supply system according to claim 1, wherein the distributed power supply is controlled so as to supply power. In the combination process, the customer controller of one customer specifies another customer to limit the combination and transmits the information to the distributed power site controller, and the distributed power site controller communicates with the one customer. The distributed power supply system according to any one of claims 3 to 5, wherein a combination with another designated customer is not performed. The distributed power supply site controllers of the plurality of distributed power supply sites substantially exchange power between the distributed power supply sites via a power system, and a charge collection unit of a power company performs power purchase and sale between the distributed power supply sites. 3. The distributed power system according to claim 2, wherein the brokerage fee is collected from accounts at one or both of the distributed power sites. The plurality of distributed power supply sites each include a distributed power supply station connected to a middle system and connected to a distributed power supply mounted on a moving means such as a vehicle or a ship. A distributed power supply system according to claim 1. The said moving means is a vehicle, The said distributed power supply station utilizes the gas station which has a tank underground, The fuel of a distributed power supply is stored in this tank, The fuel supply of Claim 10 characterized by the above-mentioned. Distributed power system. 12. The distributed power supply system according to claim 10, wherein the distributed power supply station further includes a power storage unit that stores electric power supplied from a distributed power supply mounted on the connected moving unit. The distributed power supply system according to claim 12, wherein the power storage unit can store surplus power in a distributed power supply base. A distributed power source base that configures a middle grid for the power grid, and connects distributed power sources and loads of a plurality of customers in the middle grid;
A customer controller that is included in the distributed power site and manages and controls the distributed power and load in the distributed power site;
Within the distributed power supply site, a virtual distributed power supply site configured by grouping specific customers among the plurality of customers based on predetermined conditions,
A virtual distributed power supply site controller that is constructed corresponding to the virtual distributed power supply site, is connected to the customer controller via a communication network, and performs management control of the entire virtual distributed power supply site;
A distributed power supply system comprising: 15. The distributed power supply system according to claim 14, wherein the grouped virtual distributed power supply points are configured by specific customers who have previously made virtual distributed power supply points. The distributed power supply system according to claim 14, wherein the virtual distributed power supply site controller determines whether or not to participate in the grouping based on information of a customer who wants to participate in the virtual distributed power supply site. At the time of the grouping, the virtual distributed power supply site controller, when there is a customer who wants to participate in the virtual distributed power supply site, when there is a risk that the customer may interfere with the optimal operation of the system, the demand of this customer The distributed power supply system according to claim 14, wherein a notification of participation refusal is sent to the house controller. Further, the virtual distributed power supply site controller, after performing a participation rejection notification, transmits an improvement notification from the customer's customer controller to the virtual distributed power supply site controller, thereby permitting participation of the customer. The distributed power supply system according to claim 17, wherein: The distributed power supply system according to claim 2, wherein the plurality of distributed power supply points include a power transmission / reception system that transmits and receives microwaves between the distributed power supply points. 4. 20. The apparatus according to claim 1, further comprising: a distributed power supply system for connecting the plurality of distributed power supplies, and overlap switching means for switching between the middle power supply and the distributed power supply system. A distributed power supply system according to claim 1. A plurality of customers each having a distributed power source and a load are connected in a distributed power source site that constitutes a middle system with respect to the power system, and when the customer controller in the distributed power source site is managed and controlled by the distributed power source site controller,
A procedure for issuing a power purchase request to a distributed power supply site controller via a network from a customer controller of one of the plurality of consumers,
A procedure for issuing a power sale request from a customer controller of another customer to the distributed power base controller via a network,
By a distributed power supply site controller, a customer who has issued a power purchase request and a customer who has issued a power sale request are combined based on a predetermined combination process, and a procedure for performing power trading between these customers,
A method of operating a distributed power system, comprising: The combination process, when one of the customer of the power purchase request and the customer of the power sale request is singular, a procedure of performing a combination that gives the single customer the most benefit based on the required buy price and sell price. The method of operating a distributed power supply system according to claim 21, comprising: In the combination process, when there are a plurality of consumers of the power purchase request and a plurality of customers of the power sale request, the customers who request the closest buy and sell prices among the required buy and sell prices are combined with each other. 22. The method according to claim 21, further comprising the steps of: 24. The consumer controller requesting power purchase includes a procedure for canceling the power purchase request based on selling price information from the customer controller requesting power sale, according to any one of claims 21 to 23. Of the distributed power system in Japan. In the case where the distributed power supply of any of the customers in the distributed power supply base malfunctions, the method includes a step of supplying power to the customer from the distributed power supply of another customer under predetermined conditions. The method for operating a distributed power supply system according to claim 21, wherein: In the combination processing,
A procedure in which one customer designates another customer who restricts the combination;
A procedure for preventing the combination of the one customer and another customer according to the designation,
The method of operating a distributed power supply system according to any one of claims 21 to 24, comprising: A plurality of customers, each having a distributed power source and a load, are connected in a distributed power source site constituting a middle system to the power system, and a customer controller in the distributed power source site is managed and controlled by the distributed power source site controller,
Further, a plurality of such distributed power supply points are connected to the power system, and in order to exchange power between the distributed power supply points,
A procedure for buying and selling power on a network via a power system between the distributed power sources,
Collecting a brokerage commission for power purchase and sale between the distributed power sites from the account of one or both of the distributed power sites via a network;
A method of operating a distributed power system, comprising: A plurality of customers, each having a distributed power source and a load, are connected in a distributed power source site constituting a middle system to the power system, and a customer controller in the distributed power source site is managed and controlled by the distributed power source site controller,
Further, a plurality of such distributed power supply points are connected to the power system, and in order to exchange power between the distributed power supply points,
An operation method of a distributed power supply system, characterized in that a distributed power supply mounted on a moving means is connected to a distributed power supply station provided at each distributed power supply base to receive power supply from the distributed power supply. A plurality of customers each having a distributed power source and a load are connected in a distributed power source site that constitutes a middle system with respect to the power system, and when the customer controller in the distributed power source site is managed and controlled by the distributed power source site controller,
A procedure of grouping specific customers among the plurality of consumers based on predetermined conditions to construct a virtual distributed power source base,
A procedure for building a virtual distributed power point controller that is constructed corresponding to the virtual distributed power point and performs management control of the entire virtual distributed power point;
A method of operating a distributed power system, comprising: A plurality of customers each having a distributed power source and a load are connected in a distributed power source site that constitutes a middle system with respect to the power system, and when the customer controller in the distributed power source site is managed and controlled by the distributed power source site controller,
A procedure for grouping specific customers who have previously agreed to create a virtual distributed power supply base and constructing a virtual distributed power supply base,
A procedure for building a virtual distributed power point controller that is constructed corresponding to the virtual distributed power point and performs management control of the entire virtual distributed power point;
A method of operating a distributed power system, comprising: 30. The distributed power system operation method according to claim 29, further comprising a step of determining whether or not to participate in the grouping based on information of a customer who intends to participate in the virtual distributed power source base. At the time of the grouping, when there is a customer who wants to participate in the virtual distributed power source base, and when the customer does not fit the optimal operation of the system, the method includes a step of rejecting participation of the customer. 30. The method for operating a distributed power system according to claim 29. 33. The method according to claim 32, further comprising, after rejecting participation, a procedure for permitting the participation of the customer based on a notification of the implementation of the improvement measure from the customer. An operation program for a distributed power supply system for causing a computer to execute each procedure according to any one of claims 21 to 33. In the distributed power source base, a general load is connected to the power system in the middle system, and a plurality of important loads are connected to a self-generating system having a distributed power source, and the power system and the self-generating system are system-linked,
This system linking circuit is provided with a breaking means,
A commercial power supply system for supplying commercial power from the commercial system to a plurality of important loads is provided,
21. The distributed power supply system according to claim 1, further comprising an overlap switching unit at a connection point between the commercial power supply system and a plurality of private power systems connected to the important load.

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