JP6373645B2 - Power management equipment - Google Patents

Description

  The present invention relates to a power management apparatus.

  With the start of liberalization of power retail, it is possible to procure power from specific power companies as well as conventional power companies, and various power procurement methods have been proposed that are cheaper than before. (For example, refer to Patent Document 1). In Patent Document 1, while predicting the amount of power that can be generated based on information such as weather and temperature and the characteristic information of the generator, the amount of power demand is predicted, and the amount of power that is procured from the outside based on both predicted values A technique for procuring electric power at a low cost by calculating the above is disclosed.

JP 2006-050834 A

  With the recent increase in environmental protection awareness, the policy is to promote power generation using renewable energy. For example, power based on renewable energy (also referred to as “green power”) has been popularized by providing a fixed purchase system for power generation using renewable energy.

  By using electric power based on such renewable energy, it is possible to procure electric power at low cost. For example, by using power supplied by solar power generation, it is possible to procure power cheaply compared to the case of using power supplied from a conventional power company or power supplied from a specific scale power company. Can be planned.

  However, it is known that the amount of power that can be supplied by photovoltaic power generation varies greatly depending on the weather. For example, when the power supplied by solar power generation decreases rapidly, the power shortage from a conventional electric power company or the like is procured. When power is procured in this way, it is necessary to pay a penalty (extra charge) to an electric power company or the like, and there is a risk that procurement costs will increase against cheap power procurement.

  As described in Patent Document 1, various methods for preventing the occurrence of the above-described penalty by predicting the amount of power that can be generated based on weather information and generator information are also proposed. ing. However, there is still a possibility of paying a penalty, and there is a problem that utilization of power supplied by solar power generation is difficult.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a power management apparatus that facilitates the use of power based on renewable energy that may be penalized.

In order to achieve the above object, the present invention provides the following means.
The power management apparatus according to the present invention is a power generation facility that supplies power based on renewable energy, the power value procured from the renewable energy power generation facility in which the value of power generated by weather conditions varies, and other power generation A power management device that determines a ratio with a power value procured from a facility, a function of a ratio of a power value procured from the renewable energy power generation facility, wherein the power value procured from the renewable energy power generation facility A procurement function that is a function of the sum of a value multiplied by one price factor and a power value procured from the other power generation facility multiplied by a second price factor, and a plan previously procured from the renewable energy power generation facility And an imbalance function that is a function obtained by multiplying the power value obtained by subtracting the actual power value procured from the renewable energy power generation facility by the third price coefficient. Te, wherein the computation unit is provided for determining the ratio of the power value procured from the renewable energy power generation equipment.

  According to the power management apparatus of the present invention, since the ratio of the power value to be procured from the renewable energy power generation facility is obtained based on the procurement function and the imbalance function, the overall cost for power procurement is reduced. It becomes easy.

  Generally, the first price coefficient is set to be smaller than the second price coefficient due to policy reasons for promoting renewable energy power generation facilities. Moreover, since the third price coefficient is a coefficient related to the electric power procured on the day, the value is larger than the first price coefficient and the second price coefficient. Therefore, the cost at the time of procuring electric power can be suppressed by increasing the ratio of electric power procured from the renewable energy power generation facility. However, the renewable energy power generation facility cannot generate power as planned, and the generated power value may be lower than the planned value. In this case, the shortage of electric power is procured on the day, and as a result, there is a risk that the cost for procuring electric power increases.

  Therefore, based on the procurement function and the imbalance function, it is possible to determine the ratio of the power value to be procured from the renewable energy power generation facility considering the case where the generated power in the renewable energy power generation facility is lower than the planned value. This makes it easier to control the overall cost of procurement.

  In the above invention, the storage unit storing the first price coefficient, the second price coefficient, and the third price coefficient, and the first price coefficient, the second price coefficient, and the third price from the outside An acquisition unit for acquiring at least one coefficient, and at least one of the first price coefficient, the second price coefficient, and the third price coefficient stored in the storage unit is the acquisition It is preferable that at least one of the first price coefficient, the second price coefficient, and the third price coefficient is replaced with a part.

  In this way, by providing the acquisition unit and acquiring at least one of the first price coefficient, the second price coefficient, and the third price coefficient from the outside, the first price coefficient, the second price coefficient, and the third price coefficient Even if at least one of fluctuates, it can be dealt with.

  In the above invention, the storage unit further stores a correction coefficient for correcting the third price coefficient or the imbalance function, and the calculation unit uses the third price coefficient corrected by the correction coefficient. It is preferable to determine the ratio of the power value procured from the renewable energy power generation facility based on the imbalance function or the imbalance function corrected by the correction coefficient.

  As described above, the imbalance function can be corrected by correcting the third price coefficient or the imbalance function with the correction coefficient. In other words, the degree of imbalance risk avoidance can be adjusted.

In the said invention, it is preferable that the input part which inputs the said correction coefficient is further provided.
Thus, by inputting the correction coefficient from the input unit, for example, an administrator who manages the ratio of the power value procured from the renewable energy power generation facility can input the desired correction coefficient. In other words, it is possible to input a correction coefficient that reflects the intention of the administrator, for example, a correction coefficient that is intended to increase the ratio of renewable energy while being aware of the imbalance risk, or an imbalance risk. It is possible to input a correction coefficient intended to be avoided as much as possible.

In the above invention, the correction coefficient is preferably a coefficient that is determined based on a probability distribution relating to variations in power values generated by the renewable energy power generation facility.
By using a correction coefficient that is determined based on the probability distribution related to the variation in the power value generated by the renewable energy power generation facility in this way, it is possible to avoid imbalance risk according to the renewable energy power generation facility and procure power. This makes it easier to reduce overall costs.

  According to the power management device of the present invention, since the ratio of the power value to be procured from the renewable energy power generation facility is obtained based on the procurement function and the imbalance function, the power of the power based on the renewable energy with the possibility of paying a penalty is obtained. There is an effect that it can be used easily.

It is a model diagram explaining the structure of the power management apparatus which is one Embodiment of this invention. It is a schematic diagram explaining the model which estimates the electric power generation amount in the calculating part of FIG. It is a graph explaining the electric power generation amount estimated by the calculating part. FIG. 4A is a graph showing the relationship between procurement cost, imbalance risk cost, and total cost, and FIG. 4B shows a state in which the imbalance risk and total cost are corrected by the correction coefficient. It is a graph.

A power management apparatus according to an embodiment of the present invention will be described with reference to FIGS.
In the present embodiment, the renewable energy power generation facility that supplies power based on renewable energy is the solar power generation facility 30, the other power generation facility is the power company 50, and the power management apparatus 1 includes the load facility 40. A description will be given of an example in which the ratio of the amount of power to be procured from the solar power generation facility 30 is obtained and the amount of power to be procured is managed.

  Note that the power generation facility that supplies power based on renewable energy may be the solar power generation facility 30 or the wind power generation facility as described above, and the generated power varies depending on weather conditions. As long as it is a power generation facility, the type of the power generation facility is not particularly limited. The other power generation facilities may be the electric power company 50 as described above, or may be a specific scale electric power company, and are not particularly limited.

  As shown in FIG. 1, the power management apparatus 1 obtains a ratio between the amount of power procured by the load facility 40 from the solar power generation facility 30 and the amount of power procured from the power company 50. The power amount procured from 30 and the power amount procured from the power company 50 are managed.

  The power management apparatus 1 is a computer system having a CPU (Central Processing Unit), ROM, RAM, hard disk, input / output interface, and the like. The control program stored in the ROM or the like is for causing the CPU to function as the calculation unit 11 and for causing the input / output interface or the like to function as the acquisition unit 12, the output unit 13, and the input unit 14. It functions as the unit 15.

  The acquisition unit 12 acquires information related to the buying and selling price of electric power from a server of the electric power market (external) 55. Examples of information related to the buying and selling of power acquired by the acquiring unit 12 may include a first price coefficient C1, a second price coefficient C2, and a third price coefficient C3, which are power purchase prices per unit power amount. .

  Here, the first price coefficient C <b> 1 is a power purchase price per unit power amount used when power is procured from the solar power generation facility 30. The second price coefficient C2 is a power purchase price per unit amount of electric power used when procuring electric power from the electric power company 50 based on a demand and supply plan established in advance.

  The third price coefficient C3 is a power purchase price per unit amount of electric power used when procuring electric power from the electric power company 50. For example, electric power that was scheduled to be procured from the solar power generation facility 30 based on a supply and demand plan The power purchase price per unit power amount used when procuring power from the power company 50 in order to make up for the shortage power amount that is the difference in power amount actually procured from the solar power generation facility 30 from the amount.

  Furthermore, the acquisition part 12 acquires the weather information regarding a weather condition from the weather server 20 via information communication networks 2, such as the internet. Examples of weather information acquired by the acquiring unit 12 include weather forecast character data, GPV data (Grid Point Value data), satellite images, sky images, and the like for an area where the photovoltaic power generation facility 30 includes the installation position. can do.

  The storage unit 15 stores the first price coefficient C1, the second price coefficient C2, and the third price coefficient C3 acquired by the acquisition unit 12. In the present embodiment, the first price coefficient C1, the second price coefficient C2, and the third price coefficient C3 will be described by applying to the example acquired by the acquisition unit 12 and stored in the storage unit 15. Even if at least one of the first price coefficient C1, the second price coefficient C2, and the third price coefficient C3 is acquired by the acquisition unit 12 and stored in the storage unit 15, the remaining coefficients may be stored in the storage unit 15 in advance. Well, not particularly limited.

  The first price coefficient C1, the second price coefficient C2, and the third price coefficient C3 stored in the storage unit 15 are the first price coefficient C1 and the second price coefficient that are periodically acquired by the acquisition unit 12, respectively. C2 and the third price coefficient C3 may be repeatedly updated.

  Further, the storage unit 15 includes a database of facility information indicating the amount of power generated by the solar power generation facility 30 in predetermined weather information, and power generation indicating the probability of the power value generated by the solar power generation facility 30 under predetermined weather conditions. A database of information is also stored.

  The facility information is, for example, information indicating a correspondence relationship between the power generation amount generated by the solar power generation facility 30 when the predetermined solar radiation amount is obtained and the solar radiation amount, and is information unique to each solar power generation facility 30. is there. For example, even if the same amount of solar radiation is obtained, the power generation information represents variation in the amount of power generated in the solar power generation facility 30, and is information indicating the probability that each of the varied power generation amounts will appear. is there. The power generation information may be preliminarily estimated, or may be sequentially updated based on the power generation results accumulated by operating the solar power generation facility 30.

  The input unit 14 is used by the administrator of the power management apparatus 1 to input a desired correction coefficient. The correction coefficient is a third price coefficient or a coefficient for correcting an imbalance function described later, and adjusts the ratio of the amount of power procured from the solar power generation facility 30 by the load facility 40.

  The calculating part 11 calculates | requires the regeneration energy ratio RL which is a ratio of the electric energy procured from the solar power generation equipment 30. FIG. The detailed contents of the calculation process for obtaining the regeneration energy ratio RL will be described later.

  The output unit 13 notifies the solar power generation facility 30 of the amount of power P1 that is the amount of power to be procured and notifies the power company 50 of the amount of power P2 that is the amount of power to be procured. The output unit 13 may be connected to the photovoltaic power generation facility 30 and the electric power company 50 via an information communication network such as the Internet, or may be connected via a dedicated line, in particular a transmission for transmitting a control signal. The form of the means is not limited.

Next, a power amount management method in the power management apparatus 1 having the above configuration will be described with reference to FIGS.
First, the power management apparatus 1 acquires a numerical weather model, a satellite image, and a sky image from the weather server 20 using the acquisition unit 12. The numerical weather model includes weather forecast character data and GPV data. Furthermore, the acquisition part 12 acquires solar radiation data from the solar radiation sensor which measures the solar radiation amount installed in the solar power generation facility 30.

  The calculation part 11 performs the calculation which estimates the electric power generation amount generated by the solar power generation equipment 30 by indirect prediction or direct prediction as shown in FIG. First, calculation by indirect prediction will be described. The calculation unit 11 performs calculation for predicting future solar radiation based on the acquired numerical weather model, satellite image, sky image, solar radiation data, and estimated conversion model CM1.

  Thereafter, the calculation unit 11 acquires facility information and power generation information from the storage unit 15, and the photovoltaic power generation facility 30 based on the acquired facility information and power generation information, the obtained solar radiation prediction, and the estimated conversion model CM <b> 2. Predicts the amount of power generated.

  In the case of calculation by direct prediction, the calculation unit 11 directly predicts the amount of power generated by the solar power generation facility 30 without calculating future solar radiation prediction. Specifically, the photovoltaic power generation facility 30 generates power based on the acquired numerical weather model, satellite image, sky image and solar radiation data, estimated conversion model CM1, facility information and power generation information, and estimated conversion model CM2. Predict the amount of power generated.

  Next, the power generation amount predicted by the calculation unit 11 will be described with reference to FIG. In FIG. 3, the horizontal axis indicates the passage of time, and the vertical axis indicates the power value generated by the solar power generation facility 30 or the power value procured from the solar power generation facility 30. Therefore, the electric energy is shown as an area in FIG.

  The predicted value of the power value generated by the photovoltaic power generation facility 30 estimated by the calculation unit 11 based on the numerical weather model, satellite image, sky image and solar radiation data, facility information, etc. is, for example, the curve FC in FIG. As shown in The theoretical maximum value of the power value that can be generated by the solar power generation facility 30 is, for example, as shown by the curve MX in FIG.

  The range of the variation in the power value generated by the photovoltaic power generation facility 30 calculated by the arithmetic unit 11 based on the numerical weather model, satellite image, sky image and solar radiation data, power generation information, etc. is, for example, the region of FIG. As shown by VB. The upper limit of the region VB is the above-described curve MX, and the lower limit is the curve MN. The curve MN indicates, for example, the lowest power value in the range of power value variation.

  In other words, the region VB also indicates a probability distribution in which a power value generated by the solar power generation facility 30 appears. The probability distribution has the highest appearance probability of the power value related to the vicinity of the curve FC that is the predicted value, and the appearance probability of the power value related to the position decreases as the distance from the curve FC moves upward or downward in FIG. Distribution.

  On the other hand, the region RB sandwiched between the horizontal axis and the curve MN in FIG. 3 is a region indicating that there is a low possibility of being affected by variations in the power value generated by the solar power generation facility 30, and the region RB This is an area indicating that the reliability with which the power value included in can be supplied is higher than the predetermined reliability. The region VB is a region indicating that the reliability with which the power value can be supplied is equal to or less than a predetermined reliability. The predetermined reliability may be a predetermined value, or may be a value that is newly set based on the operation results of the photovoltaic power generation facility 30, and the numerical value is particularly limited. is not.

  The computing unit 11 creates a plan for the amount of power P1 that the load facility 40 procures from the solar power generation facility 30 based on the prediction of the amount of power generation described above. Specifically, as shown in FIG. 3, an example in which the period during which power generation is performed in the photovoltaic power generation facility 30 is divided into a plurality of periods of equal length and the amount of power P1 to be procured in each period is obtained. Apply and explain. The length of the plurality of periods may be a length divided by a minute unit such as 30 minutes, or may be a length divided by a time unit such as one hour.

  The computing unit 11 further creates a plan for the amount of power P2 procured from the power company 50 based on the total amount of power required by the load facility 40 and the plan for the amount of power P1 procured from the solar power generation facility 30. It is also referred to as a supply and demand plan including the plan for the amount of power P1 and the plan for the amount of power P2.

  Note that the amount of power P1 procured from the solar power generation facility 30 has a difference PD between the actual amount of power P1 procured due to changes in weather conditions and the planned amount of power P1 on that day. May occur. In this case, the power management apparatus 1 performs control to supply power corresponding to the difference PD from the power company 50 to the load facility 40.

  The calculation unit 11 is a function of the ratio of the amount of power procured from the solar power generation facility 30 (hereinafter also referred to as “regenerative energy ratio”), and is based on a procurement function and an imbalance function for obtaining the cost of power procurement. A calculation process for determining a renewable energy ratio that reduces the cost of power procurement is performed.

  Here, the procurement function has a value obtained by multiplying the power amount P1 procured from the solar power generation facility 30 by the first price coefficient C1, and a value obtained by multiplying the power amount P2 procured from the power company 50 by the second price coefficient C2. It is a function expressed as a sum. The imbalance function is a function expressed by multiplying the difference PD by the third price coefficient C3.

  As shown by a curve L1 in FIG. 4A, the power procurement cost obtained by the procurement function decreases as the ratio (regeneration energy ratio) of the amount of power P1 procured from the solar power generation facility 30 increases.

  On the other hand, the cost of the imbalance risk obtained by the imbalance function increases as the regeneration energy ratio increases, as shown by the curve L2. Thus, increasing the regeneration energy ratio means that the amount of power P1 procured from the solar power generation facility 30 is increased. When the power amount P1 increases, as shown in FIG. 3, the probability that the increased power amount P1 is procured decreases and the difference PD occurs, in other words, the probability that an imbalance risk occurs.

  The calculation unit 11 has the lowest total energy (curve L3 in FIG. 4A) that is the sum of the power procurement cost obtained from the procurement function and the imbalance risk cost obtained from the imbalance function. An arithmetic process for obtaining the ratio RL is performed.

  When a correction coefficient is input from the input unit 14, the calculation unit 11 performs a calculation process for obtaining a regeneration energy ratio RL that provides the lowest overall cost using an imbalance function that takes the correction coefficient into consideration. As an imbalance function considering the correction coefficient, a function using a coefficient obtained by multiplying the third price coefficient C3 by a correction coefficient, a function using a coefficient obtained by subtracting the correction coefficient from the third price coefficient C3, or a difference PD For example, the third price coefficient C3 is multiplied and the correction coefficient is subtracted.

  The cost of the imbalance risk obtained by the imbalance function considering the correction coefficient moves so as to reduce the cost, for example, as shown by a curve L2 in FIG. Then, the total cost, which is the sum of the power procurement cost obtained from the procurement function and the imbalance risk cost obtained from the imbalance function, also moves as shown by a curve L3 in FIG. As a result, the regenerative energy ratio RL at which the total cost is the lowest moves in the direction in which the ratio of the amount of power P1 procured from the solar power generation facility 30 increases (the right direction in FIG. 4B).

  In the above description, the correction coefficient that increases the value of the regeneration energy ratio RL is described as being applied. However, a correction coefficient that decreases the value of the regeneration energy ratio RL can be input. In this case, the imbalance risk cost (curve L2) moves in a direction in which the cost increases, and the total cost (curve L2) also moves in a direction in which the cost increases.

  When the regenerative energy ratio RL is obtained, the calculation unit 11 performs a process of outputting the power amount P1 and the power amount P2 that are power amounts procured to the solar power generation facility 30 and the power company 50 via the output unit 13, respectively. Do.

  According to the power management apparatus 1 having the above configuration, since the ratio of the amount of power to be procured from the solar power generation facility 30 is obtained based on the procurement function and the imbalance function, the overall cost is suppressed when the power is procured. It becomes easy to plan.

  Generally, the first price coefficient C1 is set to be smaller than the second price coefficient C2 due to policy reasons for promoting the photovoltaic power generation facility 30 and the like. Further, the third price coefficient C3 is a coefficient related to the electric power procured on the day, and thus has a value larger than the first price coefficient C1 and the second price coefficient C2. Therefore, by increasing the ratio of the amount of power procured from the solar power generation facility 30, it is possible to suppress the cost when procuring power. However, the solar power generation facility 30 may not generate power as planned, and the amount of power to be generated may be lower than the planned value. In this case, the shortage of electric power is procured on the day, and as a result, there is a risk that the cost for procuring electric power increases.

  Therefore, based on the procurement function and the imbalance function, it is possible to obtain the ratio of the amount of power to be procured from the solar power generation facility 30 in consideration of the case where the generated power in the solar power generation facility 30 is lower than the planned value. As a result, it is easy to reduce the overall cost when procuring electric power, and it is possible to facilitate the use of electric power based on the photovoltaic power generation facility 30 with a possibility of paying a penalty.

  By providing the acquisition unit 12 to acquire the first price coefficient C1, the second price coefficient C2, and the third price coefficient C3 from the electric power market 55, the first price coefficient C1, the second price coefficient C2, and the third price Even if the coefficient C3 fluctuates, it can be dealt with.

  The imbalance function can be corrected by correcting the third price coefficient C3 or the imbalance function with the correction coefficient. In other words, the degree of imbalance risk avoidance can be adjusted.

  By inputting the correction coefficient from the input unit 14, for example, an administrator who manages the ratio of the amount of power procured from the photovoltaic power generation facility 30 can input a desired correction coefficient. In other words, a correction coefficient reflecting the manager's intention can be input, for example, a correction coefficient intended to increase the ratio of the amount of power procured from the photovoltaic power generation facility 30 with knowledge of imbalance risk, Alternatively, a correction factor intended to avoid imbalance risk as much as possible can be input.

  By using a correction coefficient that is determined based on a probability distribution related to variations in the amount of power generated by the photovoltaic power generation facility 30, it is possible to avoid imbalance risk according to the photovoltaic power generation facility 30 and to comprehensively procure power. This makes it easier to control costs.

  The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention. For example, in the above-described embodiment, the power management apparatus 1 and the load facility 40 have been described separately as being applied and connected via the information communication network 2 or the like. The present invention is not limited to the apparatus 1 and the load facility 40 that are separately installed, and can also be applied to an apparatus in which both are installed integrally.

  DESCRIPTION OF SYMBOLS 1 ... Power management apparatus, 11 ... Operation part, 12 ... Acquisition part, 14 ... Input part, 15 ... Memory | storage part, 30 ... Solar power generation equipment (renewable energy power generation equipment), 50 ... Electric power company (other power generation equipment) 55 ... Electricity market (external), C1 ... First price coefficient, C2 ... Second price coefficient, C3 ... Third price coefficient

Claims (3)

A power generation facility that supplies power based on renewable energy, the power value procured from a renewable energy power generation facility in which the value of power generated by weather conditions varies, and the power value procured from other power generation facilities A power management device that determines the ratio,
A function of the ratio of power values procured from the renewable energy power generation facility,
A procurement function that is a function of a sum of a value obtained by multiplying a power value procured from the renewable energy power generation facility by a first price factor and a value obtained by multiplying a power value procured from the other power generation facility by a second price factor. When,
An imbalance that is a function obtained by multiplying a power value of a difference obtained by subtracting an actual power value procured from the renewable energy power generation facility from a preplanned power value procured from the renewable energy power generation facility by a third price coefficient Functions and
Based on the calculation unit for obtaining the ratio of the power value procured from the renewable energy power generation facility ,
An output unit for notifying the renewable energy power generation facility of the power value procured from the renewable energy power generation facility, and notifying the other power generation facility of the power value procured from the other power generation facility;
An input unit for inputting a correction coefficient for correcting the third price coefficient or the imbalance function;
A storage unit for storing the correction coefficient;
Is provided ,
The calculation unit is configured to supply electric power procured from the renewable energy power generation facility based on the imbalance function using the third price coefficient corrected by the correction coefficient or the imbalance function corrected by the correction coefficient. A power management apparatus characterized by obtaining a ratio of values . An acquisition unit for acquiring at least one of the first price coefficient, the second price coefficient, and the third price coefficient from the outside;
The storage unit further stores the first price coefficient, the second price coefficient, and the third price coefficient,
At least one of the first price coefficient, the second price coefficient, and the third price coefficient stored in the storage unit is the first price coefficient acquired from the acquisition unit, the second price coefficient, The power management apparatus according to claim 1, wherein the power management apparatus is replaced with at least one of the third price coefficient. The correction factor, the power management device according to claim 1 or 2, wherein the renewable energy power generation equipment is a coefficient determined based on the probability distribution variations in the power value to generate power.

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