JP2002369380A - Power supply system and method for accounting power charge for the supply - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system that enables customers more practically and simply to save electric power effectively by an appropriate guidance through a power charge, and that thereby makes the power supply controllable. SOLUTION: This power supply system is provided with a generator 4 that generates electric power, an energy-saving demand issuing means 18 that generates an energy-saving demand signal when the electric power demanded by customers is likely to exceed a prescribed power value, a power determining means 40 that determines whether or not the consumed power by the customers has passed a preset energy-saving level, and an energy-saving performance times displaying part 38 that leaves a record when the energy-saving demand signal has suppressed the consumed power below the energy-saving level during a designated period. The energy-saving performance times displaying part 38 is composed of an energy-saving performance counter, for instance.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electric power supply system for supplying electric power to an electric power consumer, and more particularly, to a possibility that an electric power demand approaches the electric power supply capacity of the electric power supplier and causes a problem in the electric power supply. The present invention relates to a power supply system capable of effectively causing a power demander to save power by an appropriate guidance through a power rate or the like when there is a power rate. Further, the present invention relates to a method of charging a power rate in such a power supply system.

[0002]

2. Description of the Related Art In general, the demand for electric power greatly varies depending on the season and time, but the storage of electric power is not easy, unlike water and city gas, and the present situation is that pumping power generation is very limited. For this reason, the power supply companies have to have power generation facilities that can cope with the peak of the power demand, and the facility operation rate does not increase throughout the year, which poses a cost problem.

[0003] In view of the above situation, electric power suppliers have been striving to equalize the electric power demand by setting separate rates for a plurality of sections according to time zones and the like, and have been implementing them efficiently. Various proposals have also been made on methods and devices for performing such operations, and for example, Japanese Patent Application Laid-Open No. 2000-266781 discloses a multi-rate electricity meter.

However, in this type of method and apparatus,
Price is set in advance so that an appropriate demand leveling effect can be obtained based on rough forecasts of supply and demand by season or by hour.Although there is a certain effect, it is fixed, and power demand is fixed. There is a problem that it is not possible to respond flexibly in response to changes in Further, for example, Japanese Patent Application Laid-Open No. 5-28
Japanese Patent No. 464 discloses a power distribution control system in which a power supply side acts on a demand side to reduce (conserve) power consumption. Japanese Patent Application Laid-Open No. 5-28
A first power distribution control system disclosed in Japanese Patent No. 464 is a communication system including a center communication terminal, a plurality of customer communication terminals operatively connected to the center communication terminal via a communication line, and connected to a load group. A center-side communication terminal, wherein the center-side communication terminal outputs a presentation signal including a load reduction request time to the customer-side communication terminal, and an incentive amount based on a response signal input from the customer-side communication terminal. Selection signal output means for outputting a selection signal to one or a plurality of customer-side communication terminals having a smaller number of times. A response signal output means for outputting a response signal including an incentive amount calculated based on a plurality of reduction potentials to the center communication terminal; and a selection signal from the center communication terminal. And a power reduction means for reducing the predetermined time the power supply to the load group based on.

A second power distribution control system disclosed in Japanese Patent Application Laid-Open No. Hei 5-28464 is a system in which a center-side communication terminal is operatively connected to the center-side communication terminal via a communication line. A plurality of customer-side communication terminals connected to the group, wherein the center-side communication terminal outputs a presentation signal including the load reduction request time to the customer-side communication terminal; Selection signal output means for outputting a selection signal to one or a plurality of customer-side communication terminals selected by a function using the reduced power amount, the reduced time, and the incentive amount based on the response signal to be performed. In addition, the above-mentioned customer-side communication terminal uses the load reduction request time and one or more reduction potentials in the presentation signal from the center-side communication terminal and one or a plurality of reduction potentials to calculate the amount of power reduction, reduction time, and a. Response signal output means for outputting a response signal including the sentence amount to the center-side communication terminal; and power reduction means for reducing power supply to the load group for a predetermined time based on a selection signal from the center-side communication terminal. ing.

A third power distribution control system disclosed in Japanese Patent Application Laid-Open No. Hei 5-28464 is a system in which a center-side communication terminal is operatively connected to the center-side communication terminal via a communication line. A plurality of customer communication terminals connected to the group, wherein the center communication terminal outputs a presentation signal including the load reduction request time and the incentive amount to the customer communication terminal; For one or more customer-side communication terminals in which the product of the reduced power amount and the reduced time is large based on the response signal output from the communication terminal,
Selection signal output means for outputting a selection signal including a reduced time, a reduced power amount, and an incentive amount calculated by the reduced power amount and the reduced time in the response signal, wherein the customer-side communication terminal is a center-side communication terminal Response signal output means for outputting to the center communication terminal a response signal including a load reduction request time and an incentive amount and a reduction power amount and a reduction time calculated based on one or more reduction potentials in a presentation signal from the center side; A power reduction unit configured to reduce power supply to the load group for a predetermined time based on a selection signal from the communication terminal.

However, in these power distribution control systems, advanced functions are required not only for the center communication terminal but also for the customer communication terminal, and the communication volume between the center communication terminal and the customer communication terminal increases. Further, whether or not the customer side (power demand side) consumes a certain amount of power every day, or the amount of power consumed day by day is determined in advance, otherwise, the definition of the reduced power is ambiguous, There is doubt about its effectiveness.

Further, Japanese Patent Application Laid-Open No. 2000-60031 discloses a power supply leveling system using electronic incentive data. In this power supply leveling system, electronic incentive data is transmitted from a power supplier side to a power user side in real time online using a communication system, and the power user side transmits the electronic incentive data according to a preset program. The electronic incentive data is processed, and the power using equipment is controlled in real time based on the processing result.

[0009] However, Japanese Patent Application Laid-Open No. 2000-60031 does not detail the specific contents of the incentive, but merely attempts to reduce the power demand by simply changing the hourly rate. If there is a concern that electricity rates could be significantly higher, such fluctuations in electricity rates would not always be able to control power consumption as expected, and electricity rate revenue would be significantly unstable There are also concerns. In addition, if the degree of incentive that corresponds to each incentive menu on a one-to-one basis for each applicable time zone is transmitted in real time online, a huge amount of communication is required, and it can be applied to large-scale customers. However, it is not suitable for small consumers such as ordinary households.

[0010]

SUMMARY OF THE INVENTION It is an object of the present invention to make it possible for power consumers to save power effectively and easily by appropriate guidance through power tariffs, thereby enabling power supply. Is to provide a power supply system that enables control of the power supply. Further, another object of the present invention is to calculate a power rate more realistically and easily in a power supply system that can effectively save power by a power consumer through an appropriate guidance through the power rate. It is an object of the present invention to provide a method of charging an electric power fee.

[0011]

SUMMARY OF THE INVENTION The present invention relates to a generator for generating electric power, and a power-saving request issuing means for generating a power-saving request signal when there is a possibility that the power demand on the consumer side exceeds a predetermined power value. Power determination means for determining whether or not the power consumption of the consumer has exceeded a preset power saving level, and recording when the power consumption has not exceeded the power saving level throughout the period specified by the power saving request signal. And a recording unit to be left.

According to the present invention, the power saving request issuing means generates the power saving request signal when the demand power on the demand side exceeds a predetermined power value, for example, a predetermined power value in consideration of the power generation capacity of the generator. However, for example, when the power supply side has a plurality of generators, the predetermined power value is set in consideration of the power generation capabilities of the plurality of generators. In connection with such a power saving request signal, a power determining means is provided in relation to each consumer. This power determination means determines whether or not the power consumption on the consumer side exceeds a preset power saving level. This power saving level is set to, for example, 30% power saving of the power receiving contract capacity by a contract with the power supply side, and when the power receiving contract capacity is, for example, 5 kW, the power saving level is set to, for example, 1.5 kW power saving of 3.5 kW. Is set. This power saving level may be set to a plurality of levels. For example, when two power saving levels are set,
As the first power saving level, for example, 2.5 kW of 50% power saving (2.5 kW power saving) of the power receiving contract capacity (for example, 5 kW) is set, and as the second power saving level, for example, 30 of the power receiving contract capacity.
3.5 kW of% power saving (1.5 kW power saving) is set.
Throughout the specification, “demand power” refers to the total amount of power received by all consumers, and “power consumption” refers to the amount of power received by each customer.

When such a power saving request signal is generated,
During the period specified by the power saving request signal, it is determined whether the power consumption of the consumer has exceeded the power saving level,
When the power consumption has never exceeded the power saving level throughout the designated period, the recording means records this.
Such a recording means is composed of, for example, a power saving execution counter. By looking at the contents recorded by the recording means, it is possible to easily understand how much each consumer has cooperated with the power saving request on the power supply side to save power.
And by giving the incentive to reduce the electricity rate according to the degree of contribution in cooperating with this power saving request, in other words, the amount of power saved according to the recorded contents of the recording means, the consumers will cooperate in saving power and the power supply side will In addition, the power saving effect can be obtained realistically and easily, and the excess equipment can be reduced. The period specified by the power saving request signal may be set, for example, for each generated power saving request signal, or the period of one power saving request signal may be set to, for example, 1 to 3 hours. When an appropriate time, for example, two hours, is set in advance and a power saving request is made for a long time, the power saving request signal may be generated a plurality of times.

Further, in the present invention, the power saving request issuing means generates a power saving request first level signal when there is a possibility that the demand power on the consumer side exceeds a first predetermined power value,
A power-saving second level signal is generated when there is a possibility that the power exceeds a second predetermined power value smaller than the first predetermined power value, and the power determination unit determines when the power-saving request first level signal is generated. Determining whether the power consumption of the consumer has exceeded the first power saving level, and when the power saving request second level signal is generated, the second power saving in which the power consumption of the consumer is greater than the first power saving level. It is characterized by determining whether or not the level has been exceeded.

According to the present invention, a first power saving level is set as a power saving level, and a second power saving level larger than the first power saving level is set. When the power receiving contracted capacity is, for example, 5 kW, the first power saving level is set, for example. 2.5% of 50% power saving
kW is set, and for example, 3.5 kW of 30% power saving is set as the second power saving level. If there is a possibility that the power demand on the consumer side may increase significantly (there is a risk of exceeding the first predetermined power value) (for example, during the daytime in summer), the power-saving request issuing means outputs the power-saving request signal as the power-saving request signal. Generate a level signal. When the power saving request first level signal is generated, each consumer determines whether the power consumption has exceeded the first power saving level. In addition, when there is a possibility that the power demand on the consumer side may increase significantly (there is a risk of exceeding the second predetermined power value) (for example, before or after the daytime in summer), the power saving request issuing means outputs the power saving request signal as the power saving request signal. Generate a two-level signal. When the power saving request second level signal is generated, each consumer determines whether the power consumption has exceeded the second power saving level. As described above, in addition to the power saving request first level signal, the power saving request second level signal is generated in accordance with the power demand on the consumer side, so that it is possible to issue a power saving request more finely to promote power saving.

In the present invention, the recording means includes a power saving execution counter, and the power saving execution counter does not exceed a power saving level of the first power saving level during a period specified by the power saving request first level signal. The first count value is added when the power consumption is reduced, and the power consumption is reduced to the second level through a period specified by the power saving request second level signal.
When the power saving level is not exceeded, the second count value is added.

According to the present invention, the degree of power saving execution is measured by a power saving execution counter, and the power saving execution counter indicates that the power consumption of each customer is at the first power saving level (period) by the power saving request first level signal. 2.5k
W), the first count value is added, and the power consumption of each consumer is reduced to the second power saving level (3.5 kW) throughout the period specified by the power saving request second level signal.
Is not exceeded, the second count value is added. As described above, by changing the count value to be added according to the power saving level, an incentive according to the power saving level can be given to the consumer, and the power saving effect can be achieved while satisfying the consumer.

Further, according to the present invention, the power determining means includes:
When the power saving request first level signal is generated, it is determined whether or not the power saving request counter has exceeded the second power saving level in addition to the first power saving level. The second count value is added when power consumption exceeds the first power saving level but does not exceed the second power saving level throughout a specified period.

According to the present invention, when the power saving request first level signal is generated, the power judging means performs the second power saving level (3.5 kW) in addition to the first power saving level (2.5 kW).
Is determined. Then, the power saving execution counter adds the second count value when the power consumption exceeds the first power saving level but does not exceed the second power saving level throughout the period specified by the power saving request first level signal. As described above, when the power saving request first level signal is generated, a count value corresponding to the degree of cooperating with the power saving request is added. Can be given to.

Further, according to the present invention, there is further provided an operation control means for controlling an operation state of at least a part of the power consuming device of the consumer, wherein the operation control means is provided for a period specified by the power saving request signal. At least a part of the power consuming device is operated in a power saving mode. According to the present invention, operation control means for controlling at least a part of the operation state is provided in association with the consumer's power consuming device, and throughout the period specified by the power saving request signal, the operation control means Operate at least a part of the power consuming equipment in the power saving mode, and operate in this manner to automatically perform the power saving operation when the power demand is large and to respond to the power saving request from the power supplier. Can be. The power consuming devices that are operated and controlled by the operation control means include air conditioners such as air conditioners, indoor lighting devices, and the like. The operation is performed by raising the temperature to a predetermined temperature (for example, 2 ° C.).
0%) is forcibly turned off.

Further, according to the present invention, a power saving request signal is generated when there is a possibility that the power demand on the consumer side exceeds a predetermined power value, and the generated power saving request signal is sent to the consumer side,
Determine whether or not the power consumption of the consumer has exceeded a preset power saving level, and record when the power consumption has not exceeded the power saving level throughout the period specified by the power saving request signal, A power fee charging method in a power supply system, wherein a power saving execution fee is adjusted from a fee in accordance with recorded contents in this period.

According to the present invention, a power saving request signal is generated when the power demand on the consumer side exceeds the predetermined power value, and the generated power saving request signal is sent to the consumer side. The transmission of the power saving request signal can be performed by wire or wireless, and in the case of wire, a telephone line or an Internet communication network can be used.In consideration of simplicity of communication and simultaneous broadcasting, wireless communication is required. Although desirable, wired is desirable in view of reliability of communication by reducing disturbances such as noise.

When the power saving request signal is sent in this way, it is determined whether or not the power consumption of the consumer has exceeded a preset power saving level, and the power consumption is reduced over the period specified by the power saving request signal. If it has never been exceeded, it is recorded that the power saving request has been achieved. And
A power saving execution fee is calculated according to the degree of achievement of the power saving request, and the power saving execution fee calculated from the power fee for a predetermined period, for example, every month is adjusted and the customer is charged, and such a charging method is used. As a result, power saving can be achieved while satisfying customers. It is easy to adjust the power saving execution fee by reducing the power saving execution fee from the power fee.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a power supply system (a system for implementing a method of charging a power fee) according to the present invention will be described with reference to the accompanying drawings. First Embodiment First, referring to FIG. 1 to FIG. 3, a power supply system according to a first embodiment (a system for executing a method of charging a power fee).
Will be described. FIG. 1 is a block diagram schematically illustrating a power supply system according to a first embodiment. FIG. 2 is a front view illustrating a power reception amount measurement meter in the power supply system in FIG. 1. 6 is a flowchart showing a flow of executing a power saving request in one power supply system.

In FIG. 1, the power supply system shown includes a generator 4, a power transmission meter 6 and a control computer 8, which are provided on the side of a power supplier 2 (for example, a power supplier). 10 (for example, a factory, a general household, or the like). Describing the power supplier side, the generator 4
Generates electric power to be supplied to the consumer 10 and includes one or a plurality of generators 4. The generated power generated by the generator 4 is sent to the power delivery meter 6, and after the power delivery meter 6 measures the power delivery, the power is sent to each consumer 10 via the power transmission line 14. Will be sent. The control computer 8 on the side of the power supplier 2 includes a control unit 16, a power saving request issuing unit 18, a memory 20, and a timing unit 22. The measured output signal from the power output meter 6 is sent to the control computer 8, and the control means 16 controls the operation of the generator 4 based on the measured output signal, whereby the generated power is controlled. . In this embodiment, past power demand data is stored in the memory 20 and a predetermined power value serving as a reference for generating a power saving request signal (this predetermined power value is related to the power generation capacity of the generator 4). Is set, and the power saving request issuing means 18 is stored.
Generates a power saving request signal when the measured transmission amount value of the power transmission amount measurement meter 6 is about to exceed the predetermined power value. In this embodiment, the power saving request signal is generated using, for example, a two-hour power saving request as one unit. When a power saving request is made continuously for two hours, two power saving request signals are continuously generated.

The power supplier 2 further includes a storage device 2
4 and transmission means 26 are provided. Storage device 24
Is composed of, for example, a hard disk drive, and stores information on the measurement transmission amount of the power transmission amount measurement meter 6, information on the power saving request signal generated by the power saving request issuing unit 18, and the like. Further, the transmitting means 26 transmits a signal to each customer 10
In this embodiment, the generated power saving request signal is transmitted wirelessly to each consumer 10 in this embodiment.

Next, the power demander 10 will be described. The power receiving meter 12 is installed at each demander 10.
Each customer 10 via the power transmission line 14 from the power supplier 2
Is measured, that is, the amount of power received by the consumer 10, and is transmitted to the power consuming device 28 of each consumer 10 via the received power meter 12. The power consuming device 28
When the consumer 10 is a general home, various electric devices such as a TV, a washing machine, a refrigerator, an air conditioner, a lighting device,
When the customer 10 is a factory, the equipment 10 is various equipment such as a conveyor, an air conditioner, a compressor, and production equipment.

In this embodiment, the received power measuring meter 12
It includes a power measurement unit 30, a measurement value calculation unit 32, an integrated power display unit 34, a power saving request count display unit 36, a power saving execution count display unit 38, and a power determination unit 40. The power measuring means 30 measures the amount of power transmitted to the power consuming device 28,
The measurement value calculation means 32 calculates the power consumption at that time based on the measurement signal and calculates the accumulated power consumption up to now. The integrated power display unit 34 includes an integration counter, and displays an integrated power value of power consumption. The power saving request number display section 36 is constituted by a power saving request counter, and displays a power saving request count value. Also, the power saving execution number display unit 3
Reference numeral 8 denotes a power saving execution counter, which displays the number of times of execution of the power saving request. The power saving execution counter constitutes recording means for recording the result of executing the power saving request.
The power determining unit 40 determines whether the power consumption has exceeded a preset power saving level, and determines that the power saving request issued by the power supplier 2 has been satisfied when the power consumption has not exceeded the preset power saving level. I do. The power saving level is set in relation to the power receiving contract capacity with the power supplier 2. In this embodiment, the power saving level is set to, for example, 30% of the power receiving contract capacity. When the power receiving contract capacity is, for example, 5 kW, the power saving level is, for example, It is set to 3.5 kW, which is 1.5 kW power saving. Note that the measurement value calculation means 32 and the power determination means 40 are constituted by, for example, a microprocessor.

The power reception meter 12 further includes a reset unit 42, a power saving request display lamp 44, a clock unit 46, and a memory 48. The reset means 42 comprises, for example, a reset switch.
Is reset, the display contents of the power saving request number display section 36 and the power saving execution number display section 38 are reset. After the meter reader has read the measurement information (ie, the integrated power value, the power saving request count value, and the power saving execution count value) of the power reception amount measurement meter 12 and then resets the reset unit 42, the power saving request count value and the power saving execution count value are changed. The number of power saving requests and the number of power saving executions up to each meter reading can be checked by performing the resetting operation in this manner. Using the meter reading results, the power rate is charged to each consumer 10 as described later. You will be charged. The power saving request display lamp 44 is lit during the power saving request period specified by the power saving request signal, and notifies the consumer 10 that it is in the power saving request state. By notifying in this way, each consumer becomes conscious of power saving, and by providing incentives as described later, more effective power saving can be achieved while satisfying the customer. The power saving request based on the power saving request signal is executed using the time measured by the clock unit 46, and the power saving level (3.5 kW in this embodiment) at the time of executing the power saving request is stored in the memory 48.

On the power consumer 10 side, a receiving means 50 is further provided. The receiving unit 50 is configured by a receiving device that receives a signal, receives a power saving request signal transmitted from the transmitting unit 26 of the power supplier 2, and sends the received power saving request signal to the power reception meter 12. In this embodiment, the received power measuring meter 12 is configured as shown in FIG. 2, includes a rectangular parallelepiped meter housing 52, an integrated power display unit 34 is provided at a lower part on the front of the meter housing 52, , A power saving request number display section 36 and a power saving execution number display section 38 are provided. A power saving request display lamp 44 is arranged on the side of the power saving request number display section 36. By arranging the power saving request number display unit 36 and the power saving execution number display unit 38 side by side in this manner, it is possible to easily grasp how much the power saving request is responded to from the power supplier 2. However, when the ratio of the actual power saving request to the power saving request is small, it is clearly understood that it is necessary to cooperate with the power saving more. In the case where a power saving request is issued wirelessly or the like, there is a concern that an illegal power saving request is issued by malicious intent. However, the number of requests displayed on the power saving request number display unit 36 and the issue of the power saving request of the power supplier 2 are issued. By checking the record (stored in the storage device 24), it is possible to easily confirm whether or not there has been an unauthorized power saving request.

Next, referring to FIG. 3 together with FIG.
The flow of execution of a power saving request in the power supply system according to the embodiment will be described as follows. When the power demand is about to exceed the predetermined power value in the power supply state from the power supplier 2 to the power consumer 10, the process proceeds from step S1 to step S2, where the power supplier 2 generates a power saving request signal. You. The power delivery signal measured by the power delivery meter 6 is sent to the control computer 8,
The power saving request issuing means 18 of the computer 8 determines the power transmission amount from the current power transmission amount (in other words, the current power demand amount) and the past power demand data stored in the memory 20 to a predetermined power value (memory 20 It is determined whether it is going to exceed the predetermined power value.
A power saving request signal is generated to prevent the power demand from exceeding the power generation capacity of the generator 4.

When the power saving request signal is generated in this manner, this signal is transmitted from the transmitting means 26 (step S).
3), the receiving means 50 of the consumer 10 receives this power saving request signal (step S4). Thus, the power saving request signal is transmitted to the power reception amount measuring meter 12, the counter value of the power saving request counter constituting the power saving request number display section 36 is incremented by "1", and it is displayed that the power saving request is issued. (Step S5).

Thereafter, when the power saving request start time comes based on the time information included in the power saving request signal, the process proceeds from step S6 to step S7. It is preferable to provide an appropriate time interval between the issuance of the power saving request signal and the execution of the power saving request, for example, an interval of about 1 to 120 minutes. It is possible to easily respond to the power saving request by stopping the operation of the vehicle.

In step S7, it is determined whether or not the power consumption of the consumer 10 during the power saving request has exceeded the power saving level (in this embodiment, when the power receiving contract capacity is 5 kW, the power consumption is set to 3.5 kW). That is, the power determination unit 40 compares the power consumption calculated by the measurement value calculation unit 32 with the power saving level stored in the memory 48, and determines whether the power consumption has exceeded the power saving level. During the power saving request, the power saving request display lamp 44 is turned on.

If the power consumption exceeds the power saving level during the power saving request, the process proceeds from step S7 to step S8, where the power saving check of the power consumption is completed, and the power supplier 2
The power-saving execution counter constituting the power-saving execution number display unit 38 is not incremented because the power-saving request is not responded to. On the other hand, if the power consumption has never exceeded the power saving level during the power saving request from the power saving request start time to the power saving request end time, steps S7 and S9
Then, the process proceeds to step S10, where the counter value of the power saving execution counter is incremented by "1" assuming that the power saving request is responded to from the power supplier 2, and then the power saving check of the power consumption ends. In this way, a power saving check is performed for the power saving request issued by the power supplier (step S1).
1).

The result of such a power saving check is reflected in the power rate charged to each power consumer, the power rate is discounted according to the number of times of cooperating with the power saving request, and such an incentive is given to the consumer. This makes it possible to achieve effective power saving while satisfying consumers. The power rate is the sum of the basic rate that is not substantially related to the power consumption and the metered rate that is related to the power consumption, but the incentive for this power saving request is operated to be reduced within the range of the basic rate. It is desirable to do.
For example, if the basic rate of the power rate is 5000 yen / month, when the power saving request is achieved, the reduction is performed, for example, 500 yen / time, and the customer is charged using such a rate system. Can be It should be noted that if the number of power saving requests increases, the basic fee may be reduced to 0 yen.
It is also possible to set so as not to reduce the amount by more than 000 yen / month.

Second Embodiment Next, a power supply system according to a second embodiment will be described with reference to FIGS. FIG. 4 is a block diagram schematically showing a configuration on the power consumer side of the power supply system of the second embodiment, and FIG. 5 shows a flow of executing a power saving request in the power supply system of FIG. It is a flowchart. In the second embodiment, a power saving request first level signal is generated when a request with a large power saving ratio is made, and a power saving request second level signal is generated when a request with a small power saving ratio is made. ing. In the second embodiment, those substantially the same as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

In FIG. 4, a power reception meter 12A provided on the power consumer side of the power supply system shown in FIG.
In connection with generation of two types of power saving request signals (a power saving request first level signal and a power saving request second level signal),
It is configured as follows. Power saving request count display section 36A
Is constituted by a power saving request counter. For example, when a power saving request first level signal is sent, the count value is set to "1".
When the power saving request second level signal is transmitted by adding "0", the count value is added by "5". The power saving execution count display unit 38A is configured by a power saving execution counter. When the first power saving level is satisfied during the power saving request by the power saving request first level signal, the first count value, for example, “10” Is added, and the first power-saving level is not satisfied during the power-saving request by the power-saving request first-level signal, but when the second power-saving level is satisfied, a second count value such as “ 5 is added, and when the second power saving level is satisfied during the power saving request by the power saving request second level signal, the second count value “5” is added as the count value. I have. In addition, during the power saving request by the power saving request first level signal, the power determination unit 40A compares the power consumption of the consumer (power measured by the power receiving meter 12A) with the first power saving level and the second power saving level. It is determined whether or not these power saving levels have been exceeded, and whether or not the power consumption has exceeded the second power saving level during a power saving request by the power saving request second level signal.

The first and second power saving levels are set in consideration of the power receiving contract capacity of each consumer. In this embodiment, for example, when the power receiving contract capacity is 5 kW, the power receiving contract capacity is set as the first power saving level. 2.5 kW which is 50% power saving is set, 3.5 kW which is 30% power saving of the power receiving contract capacity is set as the second power saving level, and the set first and second power saving levels are stored in the memory 48A. .

The power receiving meter 12A is further provided with a power saving request first level display lamp 62 and a power saving request second level display lamp 64. The power saving request first level display lamp 62 lights up during the power saving request by the power saving request first level signal to notify the fact, and the power saving request second level display lamp 64 lights up during the power saving request by the power saving request second level signal. And let them know.

In the second embodiment, a part of the operation of the power consuming device 28 is operated in the power saving mode in response to a power saving request from the power supplier. That is, the power consuming device 28 includes a specific lighting device 66 operated in the power saving mode, a specific air conditioner 68 operated in the power saving mode, and a general power consuming device 70 operated regardless of the power saving mode. ing. The operation of the specific lighting device 66 and the specific air conditioning device 68 is controlled by an operation control unit 72 including, for example, a control computer, and a power saving request signal (a power saving request first level signal and a power saving request second level signal) from a power supplier. Is transmitted to the operation control means 72 via the receiving means 50, the operation control means 72 operates the specific lighting device 66 and the specific air conditioning device 68 in the power saving mode during the power saving request by the power saving request signal. In this embodiment, in the specific lighting device 66,
In the first level operation of the power saving mode during the power saving request by the power saving request first level signal, for example, 50% of them are automatically turned off, and the second level operation of the power saving mode during the power saving request by the power saving request second level signal Then, for example, 30% of them are automatically turned off. Further, during the cooling operation of the specific air conditioner 68, in the first level operation of the power saving mode during the power saving request by the power saving request first level signal, the indoor installation temperature is automatically increased by 4 ° C., and the operation is performed. In the second level operation of the power saving mode during the power saving request by the request second level signal, the indoor set temperature is automatically set to 2 ° C.
Drive up. By operating in the power saving mode in this way, it is possible to automatically respond to the power saving request from the power supplier and contribute to the power saving request.

In the case where a private power generator, a power storage device, and the like are installed on the consumer side, when a power saving request is issued from the power supplier, the private power generator, the power storage device, and the like are activated during the power saving request. Thus, the power receiving amount from the power supplier side may be configured to be small. Even in this case, it is possible to respond to the power saving request from the power supplier side.

In the second embodiment, the basic configuration of the power supplier is substantially the same as that of the first embodiment. When the power demand is likely to greatly increase (in other words, the power demand may exceed the first predetermined power value), the power saving request first level signal is generated, and the power demand may significantly increase (in other words, When the power demand may exceed the second predetermined power value), a power saving request second level signal is generated, and the generated power saving request signal is transmitted to each power consumer. In this connection, the first and second predetermined power values are stored in the memory of the control computer on the power supplier side. Other configurations in the second embodiment are substantially the same as those in the first embodiment.

Next, referring to FIG. 5 together with FIG.
The flow of execution of a power saving request in the power supply system according to the embodiment will be described as follows. When the power demand is going to exceed the first predetermined power value in the power supply state from the power supplier to the power consumer side, the process proceeds from step S21 to step S22, where the power supplier requests the power saving request first level signal. Is generated. The power saving request issuing means of the control computer on the power supplier side determines from the current power transmission amount and the past power demand data stored in the memory whether the power transmission amount is likely to exceed the first predetermined power value. This first
, A power saving request first level signal is generated.

When the power saving request first level signal is generated in this way, this signal is transmitted from the power supplier (step S23), and the receiving side receiving means 50 transmits this power saving request first level signal. Receive (Step S24).
Thus, the power saving request first level signal is transmitted to the power reception amount measurement meter 12A, the display value of the power saving request number display section 36 is added by "10", and the power saving request first level signal is issued. Is displayed, and the power saving request first level signal is sent to the operation control means 72.

Thereafter, when the power saving request start time comes based on the time information included in the power saving request first level signal, the process proceeds from step S25 to step S26, and based on the power saving request first level signal, the operation control means 72. Switches the specific lighting device 66 and the specific air conditioner 68 to the first level operation in the power saving mode, and the power of the specific lighting device 66 and the specific air conditioner 68 is automatically saved. And
In such an operating state, it is determined whether or not the power consumption on the consumer side has exceeded the first power saving level (in this embodiment, when the power receiving contract capacity is 5 kW, the power consumption is set to 2.5 kW). That is, the power determination unit 40A compares the power consumption calculated by the measurement value calculation unit 32 with the first power saving level stored in the memory 48A, and determines whether the power consumption has exceeded the first power saving level. During the power saving request, the power saving request first level display lamp 62 is turned on.

During the power saving request, the power consumption becomes first.
If the power saving level has not been exceeded, step S27
Then, the process proceeds to step S29 via step S28, assuming that the power saving request from the power supplier is sufficiently satisfied, the display value of the power saving execution frequency display unit 38A is incremented by "10", and then the power saving check of the power consumption is ended ( Step S3
0).

On the other hand, if the power consumption exceeds the first power saving level (2.5 kW) during the power saving request by the power saving request first level signal, the process moves from step S27 to step S31, and the power consumption is reduced to the second power saving level (this mode). Then, if the power receiving contract capacity is 5 kW, the power receiving contract capacity is set to 3.5 kW). That is, the power determination unit 40A compares the power consumption with the second power saving level stored in the memory 48A, and determines whether the power consumption has exceeded the second power saving level.

During the power saving request, the power consumption becomes first.
Although the power saving level was exceeded, the second power saving level (3.5 kW)
Does not exceed once, the process proceeds to step S33 via steps S31 and S32, and assuming that the power saving request from the power supplier has been satisfied to some extent, the display value of the power saving execution count display unit 38A is incremented by "5". The power saving check of the power consumption ends (step S34).

On the other hand, during the power saving request by the power saving request first level signal, the power consumption is reduced to the second power saving level (3.5 k
W) also exceeds step S31 to step S3
In step 5, the power saving check of the power consumption is completed because the power saving request from the power supplier is not satisfied. In this case, the display content of the power saving execution count display unit 38A remains unchanged.
In this embodiment, during the power saving request by the power saving request first level signal, the power determination unit 40 compares and determines the power consumption with the first and second power saving levels. A comparison may be made with only one power saving level.

Although the case where the power demand is likely to exceed the first predetermined power value has been described, when the power demand is likely to exceed the second predetermined power value smaller than the first predetermined power value, steps S21 to S21 are performed. Step S37 via S36
The power supply side generates a power saving request second level signal. The power saving request issuing means of the control computer on the power supplier side determines from the current power transmission amount and the past power demand data stored in the memory whether the power transmission amount is likely to exceed the second predetermined power value. When the second predetermined power value is about to be exceeded, a power saving request second level signal is generated.

When the power saving request second level signal is generated in this way, this signal is transmitted from the power supplier side (step S38), and the receiving side receiving means 50 transmits this power saving request second level signal. It receives (step S39).
Thus, the power saving request second level signal is transmitted to the power receiving amount measuring meter 12A, the display value of the power saving request number display section 36 is added by "5", and the power saving request second level signal is issued. And the power saving request
The level signal is sent to the operation control means 72.

Thereafter, when the power saving request start time comes based on the time information included in the power saving request second level signal, the process proceeds from step S40 to step S41, and based on the power saving request second level signal, the operation control means 72. Switches the specific lighting device 66 and the specific air conditioner 68 to the second level operation in the power saving mode, and the power of the specific lighting device 66 and the specific air conditioner 68 is automatically saved. And
In such an operating state, it is determined whether or not the power consumption on the consumer side has exceeded the second power saving level (3.5 kW). During the power saving request, the power saving request second level display lamp 64 is turned on.

During the power saving request, the power consumption becomes the second.
If the power saving level has not been exceeded, step S42
Then, the process proceeds to step S44 via step S43, in which it is determined that the power saving request from the power supplier is satisfied, the display value of the power saving execution count display unit 38A is incremented by "5", and the power saving check of the power consumption ends (step S45). ).

On the other hand, if the power consumption exceeds the second power saving level during the power saving request by the power saving request second level signal, the process proceeds from step S42 to step S35, and the power saving request from the power supplier is satisfied as described above. If there is no power saving check, the power saving check of the power consumption ends, and the value displayed on the power saving execution count display unit 38A remains unchanged. In the second embodiment as well, the execution of the power saving request is performed as described above, and the result of the power saving check is reflected in the power rate charged to each power consumer in substantially the same manner as in the first embodiment, Electricity rates are discounted according to the count value of the power saving execution counter according to the power saving request, and by giving incentives to consumers in this way, it is possible to achieve effective power saving while obtaining customer satisfaction. Become.

Although the embodiment of the power supply system according to the present invention has been described above, the present invention is not limited to such an embodiment, and various changes and modifications can be made without departing from the scope of the present invention. is there. For example, in the embodiment described above, the power saving execution fee is calculated according to the degree of achievement of the power saving request, and the power saving execution fee is reduced from the power fee. The power saving non-execution fee may be calculated according to the degree of unachieved power, and the power saving non-execution fee may be added to the power fee.

For example, in the above embodiment, the power saving request counter and the power saving execution counter
These counters may be provided on the power supplier 2 side, and in such a configuration, the communication between the power supplier 2 and each consumer 10 side may be performed. Communication means for two-way communication is provided.

[0058]

According to the power supply system of the first aspect of the present invention, the power saving request issuing means generates a power saving request signal when there is a possibility that the demand power on the consumer side exceeds a predetermined power value. During the power saving request by the power saving request signal, the power determining means determines whether or not the power consumption on the consumer side has exceeded a preset power saving level, and the power consumption decreases over the period specified by the power saving request signal. If it has never exceeded, the recording means records this. Therefore, by looking at the contents recorded by the recording means, it is possible to easily understand how much each consumer has cooperated with the power saving request on the power supply side to save power.

According to the power supply system of claim 2 of the present invention, the first power saving level and the second power saving level larger than the first power saving level are set as the power saving levels, and the power consumption on the consumer side is set. Is very high, the power saving request issuing means generates a power saving request first level signal. If there is a possibility that the power consumption on the consumer side may increase, the power saving request issuing means generates a power saving request second level signal. Since the signal is generated, the power saving request can be issued more finely to save power. According to the power supply system of claim 3 of the present invention, since the count value to be added differs according to the power saving level, an incentive according to the power saving level can be given to the consumer, and the satisfaction of the consumer can be obtained. However, the power saving effect can be more effectively achieved.

According to the power supply system of claim 4 of the present invention, when the power saving request first level signal is generated, the power determining means determines whether or not the power saving request has exceeded the second power saving level in addition to the first power saving level. The first count value is added when the power saving level does not exceed the first power saving level, and the second count value is added when the power saving level exceeds the first power saving level but does not exceed the second power saving level. A count value according to the degree of cooperation is added, and an incentive for power saving can be given frequently corresponding to power saving cooperation. Further, according to the power supply system of claim 5 of the present invention, during the power saving request by the power saving request signal, the operation control means operates at least a part of the operation state of the power consuming device in the power saving mode. Power saving is automatically achieved when there are many.

Further, in the method of charging a power rate according to claim 6 of the present invention, a power saving request signal is generated when there is a possibility that the demand power on the consumer side exceeds a predetermined power value, and the power saving request signal is designated by the power saving request signal. When the power consumption has never exceeded the power saving level throughout the period, it is recorded that the power saving request has been achieved. Then, a power saving execution fee is calculated according to the degree of achievement of the power saving request, and by adjusting the power saving execution fee from a normal power fee and charging the customer, it is possible to achieve power saving while satisfying the customer. it can.

[Brief description of the drawings]

FIG. 1 is a block diagram schematically illustrating a power supply system according to a first embodiment.

FIG. 2 is a front view showing a power receiving amount measuring meter in the power supply system of FIG. 1;

FIG. 3 is a flowchart showing a flow of executing a power saving request in the power supply system of FIG. 1;

FIG. 4 is a block diagram schematically illustrating a configuration on a power consumer side of a power supply system according to a second embodiment.

FIG. 5 is a flowchart showing a flow of executing a power saving request in the power supply system of FIG.

[Explanation of symbols]

 Reference Signs List 4 generator 6 power transmission amount meter 8 control computer 12, 12A power reception amount meter 16 control means 18 power saving request issuing means 28 power consuming device 30 power measuring means 32 measured value calculating means 34 integrated power display unit 36, 36A power saving Required number of times display unit 38, 38A Number of times of execution of power saving 40, 40A Power determination unit 44 Power saving request indicator lamp 62 First level indicator lamp of power saving request 64 Second level indicator lamp of power saving request 72 Operation control unit

Claims (6)

[Claims] 1. A generator for generating electric power, a power-saving request issuing means for generating a power-saving request signal when there is a possibility that the power demand on the customer side exceeds a predetermined power value, Power determining means for determining whether or not the power saving level has been set, and recording means for recording when power consumption has not exceeded the power saving level throughout a period specified by the power saving request signal. A power supply system characterized by the above-mentioned. 2. The power saving request issuing means generates a power saving request first level signal when there is a possibility that demand power on a consumer side exceeds a first predetermined power value, and generates the first predetermined power value. A power saving second level signal is generated when there is a possibility of exceeding a smaller second predetermined power value, and the power determination unit determines that when the power saving request first level signal is generated, the power consumption of the consumer is It is determined whether or not the first power saving level has been exceeded, and when the power saving request second level signal has been generated, whether or not the power consumption of the consumer has exceeded a second power saving level larger than the first power saving level is determined. The power supply system according to claim 1, wherein the determination is performed. 3. The power-saving execution counter according to claim 1, wherein the power-saving execution counter includes a power-saving execution counter configured to store power when the power consumption does not exceed the first power-saving level throughout a period specified by the power-saving request first level signal. 3. The method according to claim 2, wherein one count value is added, and the second count value is added when power consumption does not exceed the second power saving level throughout a period specified by the power saving request second level signal. A power supply system as described. 4. The power saving requester according to claim 1, wherein
When a level signal is generated, it is determined whether or not the second power saving level has been exceeded in addition to the first power saving level, and the power saving execution counter determines whether or not the power saving request first level signal has passed through the period specified by the power saving request first level signal. The power supply system according to claim 3, wherein the second count value is added when power consumption exceeds the first power saving level but does not exceed the second power saving level. 5. An operation control means for controlling an operation state of at least a part of a power consuming device of a consumer,
The power supply system according to claim 1, wherein the operation control unit operates at least a part of the power consuming device in a power saving mode throughout a period specified by the power saving request signal. 6. A power saving request signal is generated when there is a possibility that the power demand on the consumer side exceeds a predetermined power value, and the generated power saving request signal is sent to the consumer side so that the power consumption of the consumer is determined in advance. Determines whether the power saving level has been exceeded,
Recording when the power consumption does not exceed the power saving level throughout the period specified by the power saving request signal, and adjusting the power saving execution fee from the power fee for a predetermined period according to the recorded content in this period. An electricity billing method in a power supply system.