JP6474983B2 - Measuring device, photovoltaic power generation system, photovoltaic power generation measuring method, and photovoltaic power generation measuring program - Google Patents

Description

  The present invention relates to a measuring device for measuring the amount of power generation in a solar power generation system.

  As energy and environmental issues become more serious, efforts to save energy are attracting attention. Along with this, as a specific approach to this problem in ordinary households, introduction of a photovoltaic power generation system into the household is being promoted. In a solar power generation system, generally, a solar cell module is attached on a roof rack of a house, and DC power corresponding to sunlight is generated by the solar cell module. In such a solar power generation system, the generated DC power is collected and converted into AC power by a power converter (inverter). Furthermore, in such a solar power generation system, it operates in cooperation with an AC commercial power source that is generally used in a residential distribution board via a power generation amount measuring device.

  Japanese Patent Application Laid-Open No. 2004-228561 discloses a technique that can visually monitor instantaneous values and integrated values of DC generated power and AC power consumption at home in real time.

JP 2000-314752 JP

  In the technique of Patent Document 1, for example, when the amount of power generated by a solar cell module suddenly changes due to a sudden cloud, data representing the amount of power transmitted from the solar cell module is measured by the distribution board. The value cannot be synchronized. As a result, the measuring device erroneously displays on the display section that the power consumption has increased despite the fact that the generated power has actually decreased. On the other hand, when the amount of power generated by the solar cell module suddenly increases due to clear clouds, the measurement device incorrectly displays on the display section that power consumption has decreased despite the fact that the generated power has actually increased. . In addition, when the power generation amount data cannot be acquired due to some system side, the power generation is actually performed, but the measurement device may display 0 as the power generation amount on the display unit. Such an erroneous display causes the user to misunderstand that the solar power generation system has failed.

  The present invention has been made to solve the above problems. The present invention is a measuring device capable of displaying data representing an appropriate amount of power generation even when the amount of power generation changes abruptly or even when the current amount of power generation is unknown due to a short-term system failure. The main purpose is to provide etc.

  In order to solve the above-described problem, a first aspect of the present invention is a measuring device that corrects a current power generation value received from a solar cell module using an integrated value of the current power generation value and outputs a corrected current power generation value. It is.

  A second aspect of the present invention is a photovoltaic power generation system including a power conversion device that calculates a power generation current value and the integrated value, and transmits the calculated values to a measurement device, and the measurement device described above. It is.

  According to a third aspect of the present invention, sunlight that receives a power generation current value from a solar cell module, corrects the received power generation current value using an integrated value of the power generation current value, and outputs a corrected power generation current value. This is a power generation measurement method.

  According to a fourth aspect of the present invention, there is provided a function of receiving a power generation current value from a solar cell module, a function of correcting the received power generation current value using an integrated value of the power generation current value, and a corrected power generation current value. This is a photovoltaic power generation measurement program that causes a computer to realize the function of transmitting to the outside.

  According to the present invention, even when the power generation amount changes abruptly or when the current power generation amount is unknown due to a short-term system failure, data representing an appropriate power generation amount can be displayed. .

It is a figure which shows the structure of the solar power generation measurement system which concerns on 1st embodiment of this invention. It is a figure which shows the structure of the measuring device which concerns on 1st embodiment of this invention. It is a figure which shows the timing of the data acquisition of the measuring device which concerns on 1st embodiment of this invention. It is a figure which shows operation | movement of the measuring device which concerns on 1st embodiment of this invention. It is a figure which shows the structure of the example of a change of the measuring device which concerns on 1st embodiment of this invention. It is a figure which shows the structure of the measuring device which concerns on 2nd embodiment of this invention.

Next, an embodiment of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, the drawings schematically show the configuration of the embodiment of the present invention. Furthermore, the embodiment of the present invention described below is an example, and can be appropriately changed within a range in which the essence is the same.
<First embodiment>
(Solar power system)
As shown in FIG. 1, the photovoltaic power generation system 100 according to the first embodiment includes a display device 101, a measurement device 102, a distribution board 103, a solar cell module 104, and a power conversion device 105.

  The solar cell module 104 generates DC power based on solar energy.

  The power conversion device 105 is an inverter device that converts DC power flowing from the solar cell module 104 (power source) into AC power. The power conversion device 105 has data (hereinafter, referred to as “current power generation value”) indicating the DC power value input from the solar cell module 104 in the current predetermined period (for example, 3 seconds before 3 seconds to the present). Measure). The power conversion device 105 calculates data representing an average power value per unit time obtained by sampling the current power generation value over a predetermined period (for example, 3 seconds) (hereinafter referred to as “power generation integrated value (KWh: kilowatt hour)”). To do.

  The distribution board 103 distributes the generated power received from the power converter 105 and the purchased power purchased from the power company to the power consuming side (for example, each room in the house). Distribution of electricity is performed according to purposes such as private consumption and sales. The distribution board 103 purchases commercial power when power is insufficient, and sells generated power when power is surplus.

  The measuring device 102 receives the current power generation value and the power generation integrated value of the solar cell module 104 from the power conversion device 105. The measuring device 102 determines whether or not the received power generation current value is an appropriate value, and corrects the power generation current value using the average value of the power generation integrated values when determining that the current value is not an appropriate value.

  Further, the measuring device 102 receives the current value, voltage value (for example, 100 V) of the breaker on the consuming side (home room, etc.), the current value of the power company, the current value of the power converter, and the like from the distribution board 103. The measuring device 102 calculates the instantaneous consumption value and the instantaneous trading value from these received values, current power generation values, and the like, and transmits the calculated values to the display device 101.

The display device 101 divides the value received from the measuring device 102 into items such as a current power generation value, a power generation integrated value, an instantaneous consumption value, an instantaneous sale value, etc., and a mode (numerical value, graph, etc.) that is easy for the user to identify Is displayed.
(Measurement device)
Next, the measuring apparatus 102 will be described in detail. As shown in FIG. 2, the measuring apparatus 102 includes a conversion data receiving unit 201, a data correction unit 202, a data calculation unit 203, a distribution data receiving unit 204, a data conversion unit 205, a data transmission unit 206, and a data storage unit 207. Prepare.

  The data storage unit 207 stores a history of the power generation current value and the power generation integrated value acquired from the power conversion device 105.

  The conversion data receiving unit 201 receives the power generation current value and the power generation integrated value from the power conversion device 105.

  The data correction unit 202 corrects the newly acquired power generation current value. The data correction unit 202 corrects the newly acquired power generation current value based on the power generation current value or power generation integrated value acquired last time acquired from the data storage unit 207.

  The distribution data receiving unit 204 receives data indicating the current value, voltage value (for example, 100 V) of the consumption breaker, the current value of the power company, the current value of the power converter, and the like from the distribution board 103. These data are received as, for example, current waveform data of a commercial power system. In this case, the data conversion unit 205 converts the current waveform data received by the distribution data reception unit 204 into numerical data.

  The data calculation unit 203 calculates an instantaneous consumption value and an instantaneous sale value based on each numerical value converted by the data conversion unit 205, the corrected power generation current value, and the power generation integrated value.

  The data transmission unit 206 transmits the instantaneous consumption value and the instantaneous sale value calculated by the data calculation unit 203, and the corrected power generation current value and power generation integrated value to the display device 101.

Each unit in the measurement apparatus 102 described above may be realized by a hardware circuit or a program. When implemented by a program, each unit in the measurement apparatus 102 represents a program in units of functional blocks. These are actually stored in a CPU (Central Processing Unit) of a computer (not shown), a ROM (Read Only Memory) (not shown), a RAM (Random Access Memory) (not shown), and the like. These functions are executed by a CPU (not shown) appropriately processing these programs.
(Time difference in power data measurement timing)
Next, the measurement timing of each power data will be described. In general, if the generated power is surplus and sold as surplus power, “(power generation) = (power sales) + (consumption)”, and if power is not enough, “(power generation Amount) = (consumption)-(amount of electricity purchased). This is true when the current power generation value, power generation integrated value, instantaneous consumption value, and instantaneous trading value are measured simultaneously or substantially simultaneously. However, there are actually time differences in the measurement of the current power generation value, the power generation integrated value, the instantaneous consumption value, and the instantaneous trading value.

  An example of the time difference in the measurement timing of the power data of the measurement apparatus 102 will be described with reference to the flowchart of FIG. In the figure, the downward arrow on the left indicates the passage of time (t). In this description, it is assumed that the measurement apparatus 102 performs measurement processing every 3 seconds as an example.

The power conversion device 105 acquires the current power generation value from the solar cell module 104 every 3 seconds and transmits it to the measurement device 102. Output from the power converter 105, the power generation amount data representing the power generation current value is transmitted to the measuring apparatus 102 at the time d _1. The next power generation amount data acquisition is performed at time point d ₂ after “d ₁ +3 seconds”.

The distribution board 103 transmits measured values of commercial power data (trade power, power consumption, etc.) to the measuring device 102 at regular intervals (for example, every second). The first second data is transmitted at time point b ₁ , the second second data is transmitted at time point b ₂ , and the third second data is transmitted at time point b ₃ . Further calculates the average value for each of these 3 seconds data, transmitted in time B ₁ to the measuring apparatus 102.

Measuring device 102, the current value generated by the time k _1, power integration value, transmits the instantaneous value and trading instantaneous value on the display device 101 consumed, and displays these values. The next display is performed at time k ₂ after “k ₁ +3 seconds”.

  As in this example, the data transmission timings from the power conversion device 105 to the measurement device 102 and from the distribution board 103 to the measurement device 102 are different. Data transmission from the power conversion device 105 to the measurement device 102 is performed the same number of times as the number of data transmissions from the measurement device 102 to the display device 101. Each data transmission timing is different, but the transmission interval is the same every 3 seconds. However, since data transmission from the power conversion device 105 to the measurement device 102 is measured only once every 3 seconds, data reliability is low.

  On the other hand, data transmission from the distribution board 103 to the measuring device 102 is performed at very fine intervals by a microcomputer (not shown). For example, data is transmitted 100 times every 250 seconds, and an average value of four times of this processing result is an average of one second. This is repeated three times in 3 seconds. Therefore, the electric power measured by the distribution board 103 is a value obtained by averaging an average value every second that fluctuates by an alternating current (50 Hz (Hertz) or 60 Hz) every three seconds, and thus is highly reliable data.

The measuring device 102 measures power in consideration of the timing difference in data reception from the power converter 105 and the distribution board 103.
(Measurement device operation)
Next, the operation of the measuring apparatus 102 will be described with reference to the flowchart of FIG.

  First, in step S <b> 101, the conversion data receiving unit 201 of the measurement device 102 receives at least one of the current power generation value and the power generation integrated value from the power conversion device 105.

  In step S102, the data correction unit 202 determines whether the received data includes the current power generation value. In step S103, the data correction unit 202 determines whether the received data includes a power generation integrated value. When both the current power generation value and the power generation integrated value are included, in step S104, the data correction unit 202 does not use the current power generation value as it is, but uses the average value of the power generation integrated value for a predetermined time (predetermined period) as the current power generation value. calculate. This is to prevent displaying data different from the actual state in a short time by using the current power generation value as it is. The data calculation unit 203 uses the calculated current power generation value to calculate the instantaneous consumption value and the instantaneous trading value for display on the display device 101.

  If only the current power generation value is included in the data received in step S103, the current power generation value is corrected in step S105. This is based on whether or not the power generation current value acquired last time stored in the data storage unit 207 and the current power generation value acquired this time are within the range of the allowance for change (for example, within 25% of the previous acquired value). to decide. If it falls outside the standard, it can be determined that there has been a sudden change in weather or some data acquisition error. More specifically, for example, when a threshold value is used as a reference, it may be determined whether the range of the threshold value (for example, within 25% of the previous acquired value) is satisfied or not satisfied (exceeded). Therefore, the data correction unit 202 retrieves the current power generation value acquired last time from the data storage unit 207 and transmits it to the data calculation unit 203. The data calculation unit 203 calculates the instantaneous consumption value and the instantaneous trading value displayed on the display device 101 using the transmitted values.

  In step S102, if the received power generation value is not included in the received data, the process proceeds to step S106. In step S106, it is determined whether the received data includes a power generation integrated value. If it is determined that the power generation integrated value is included, the process proceeds to step S107, and the data calculation unit 203 calculates the consumption instantaneous value and the trading instantaneous value displayed by the data calculation unit 203 using the received power generation integrated value. To do.

  If the received power generation value is not included in the data received in step S106, that is, if neither the appropriately measured power generation current value nor the power generation integration value is included, it is determined in step S108 that some measurement error has occurred. it can. Therefore, the data calculation unit 203 calculates the instantaneous consumption value and the instantaneous sale / purchase value using the power generation current value and the power generation integrated value acquired last time stored in the data storage unit 207. This prevents the measurement result from becoming “none”.

  Finally, in step S109, the calculation results of the current power generation value, the power generation integrated value, the instantaneous consumption value, and the instantaneous trading value are transmitted to the display device 101 and prompted to display the result data.

As described above, according to the first embodiment of the present invention, since the electric energy is calculated after correcting the current power generation value, the current power generation value and the power generation integrated value are obtained even immediately after a sudden change in the current power generation value. It is possible to correct a power amount display error that occurs due to a difference between the acquisition timing and the acquisition timing from the distribution board. Thereby, a more appropriate value can be displayed to the user.
<Example of change>
The example of a change of the solar power generation system 100 in 1st embodiment is shown in FIG. As shown in FIG. 5, another power generation equipment module 106 or power storage equipment module 107 can be installed to be able to be connected to the distribution board 103. Also in this case, it is conceivable that a difference occurs in data acquisition timing from each device, and similarly, the amount of power different from the actual state is calculated. However, even in this case, it is possible to display the amount of electric power close to the actual state to the user by making each instantaneous value averaged by the data correction unit 202.
<Second Embodiment>
The measuring device 12 for measuring the power generation of the solar cell module shown in FIG. 6 corrects the current power generation value received from the solar cell module using the integrated value of the current power generation value, and the corrected current power generation value is externally applied. Output to.

  The measuring device 12 according to the second embodiment of the present invention corrects the current power generation value using the integrated value of the current power generation value. This corrects a display error that occurs due to a difference in the acquisition timing of data representing the power generation amount. According to such a measuring device 12, a more appropriate value can be displayed to the user.

12 measurement device 100 solar power generation system 101 display device 102 measurement device 103 distribution board 104 solar cell module 105 power conversion device 106 power generation equipment module 107 power storage equipment module 201 conversion data reception unit 202 data correction reception unit 203 data calculation unit 204 minutes Electric data receiver 205 Data converter 206 Data transmitter

Claims (10)

Data correction means for correcting the current power generation value received from the solar cell module using the integrated value of the current power generation value ;
Data storage means for storing at least one of the history of the current power generation value or the history of the integrated value,
The data correction means can acquire at least one of the current power generation value or the integrated value,
When the power generation current value and the integrated value are acquired, an average value of the integrated value for a predetermined period is calculated as the power generation current value based on the history of the integrated value stored in the data storage unit,
A measurement device that corrects the current power generation value when the current power generation value is acquired and the integrated value is not acquired . In the correction of the current power generation value, the data correction means,
When the current power generation value to be acquired is within the range of the change allowable reference, calculate the value to be output to the outside using the acquired current power generation value,
The value to be output to the outside is calculated using the power generation current value acquired last time stored in the data storage means when the power generation current value to be acquired is outside the range of the change allowable reference. The measuring device described in 1. Wherein the data correction means, if the does not get the power generation current value acquired the integrated value, the measuring device according to claim 1 or 2 for calculating the value to be output to the outside by using the integrated value obtained. A power conversion device that calculates the current power generation value and the integrated value, and transmits the calculated values to the measurement device;
A photovoltaic power generation system comprising the measuring device according to any one of claims 1 to 3. The power generation current value received from the solar cell module, comprising the corrected using the integrated value of the generator current value,
The amendment is
Obtaining at least one of the current power generation value or the integrated value;
When the current power generation value and the integrated value are acquired, the integrated value is calculated based on the integrated value history stored in data storage means for storing at least one of the current generation value history or the integrated value history. Calculate the average value for a given period as the current power generation value,
When the current power generation value is acquired and the integrated value is not acquired, the current power generation value is corrected.
A photovoltaic power generation measurement method comprising the above. The correction is performed in the correction of the current power generation value.
When the current power generation value to be acquired is within the range of the change allowable reference, calculate the value to be output to the outside using the acquired current power generation value,
When the current power generation value to be acquired is outside the range of the change allowable reference, the value to be output to the outside is calculated using the power generation current value acquired last time stored in the data storage means
The solar power generation measuring method of Claim 5 provided with this . The solar power generation measurement according to claim 5 or 6, wherein in the correction, when the current power generation value is not acquired but the integrated value is acquired, a value to be output to the outside is calculated using the acquired integrated value. Method. The power generation current value received from the solar cell module, comprising the corrected using the integrated value of the generator current value,
The amendment is
Obtaining at least one of the current power generation value or the integrated value;
When the current power generation value and the integrated value are acquired, the integrated value is calculated based on the integrated value history stored in data storage means for storing at least one of the current generation value history or the integrated value history. Calculate the average value for a given period as the current power generation value,
When the current power generation value is acquired and the integrated value is not acquired, the current power generation value is corrected.
Solar power measurement program for implementing a call to the computer. The correction is performed in the correction of the current power generation value.
When the current power generation value to be acquired is within the range of the change allowable reference, calculate the value to be output to the outside using the acquired current power generation value,
When the current power generation value to be acquired is outside the range of the change allowable reference, the value to be output to the outside is calculated using the power generation current value acquired last time stored in the data storage means
Photovoltaic measuring program according to claim 8, further comprising a call. In the correction, when the current value of power generation is not acquired but the integrated value is acquired, a value to be output to the outside is calculated using the acquired integrated value.
Further photovoltaic measuring program according to claim 8 or 9 comprising the.

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