JP3819334B2 - Sunshine / irradiometer - Google Patents

Description

【００２０】
演算装置１３は、電波時計１１から出力された日時に対応する角度ξを記憶装置１２から取得すると共に、当該角度ξと太陽電池２ａ，２ｂの照射量とを上記補正演算式（１）に代入することにより直達日射量に相当する補正電圧Ｅを算出する。この補正電圧Ｅ（すなわち直達日射量）は、記憶装置１２に登録データとして蓄積される。また、演算装置１３は、記憶装置１２に蓄積された複数の直達日射量から日照時間あるいは直達日射量の総和量等の測定量、つまり日照・日射に関する気象量を算出して通信装置１４に出力する。通信装置１４は、上記日照・日射に関する気象量を気象センターに送信するものである。
【００２１】
次に、このうように構成された日照・日射計の一動作例について、図５に沿って詳しく説明する。
【００２２】
演算装置１３は、例えば一定の時間間隔毎に電波時計１１から測定日時を取得し（ステップＳ１）、この測定日時の日が更新された場合（ステップＳ２）には、新しい日のファイルを開く。すなわち、演算装置１３は、午前０時を過ぎると新しいファイルを開く。なお、測定日時が更新されていない場合（ステップＳ２）には、新しいファイルを開くことなく次の処理に進む。そして、演算装置１３は、上記測定日時が記憶装置１２に予め記憶された当日の測定開始時刻を過ぎているかどうかを確認する（ステップＳ４）。そして、この測定日時が上記測定開始時刻を過ぎている場合、演算装置１３は、次の処理に進むが、過ぎていない場合には一定の時間間隔経過後、再び電波時計１１から測定日時を取得する（ステップＳ１）。つまり、当日の測定開始時刻が過ぎるまで演算装置１３は待機状態となる。
【００２３】
続いて、演算装置１３は、ＭＵＸ９を切り替えることによりＡ／Ｄ変換器１０を介して太陽電池２ａ，２ｂから照射量に相当する出力電圧Ｅa，Ｅb、太陽電池２ｃからは乱反射量に相当する出力電圧Ｅcを順次取得し（ステップＳ５）、また記憶装置１２から測定日時に対応する角度ξ（角度データ）を取得する（ステップＳ６）。そして、演算装置１３は、上記各出力電圧Ｅa〜Ｅc及び角度ξを補正演算式（１）に代入することにより補正電圧Ｅを算出し（ステップＳ７）、この出力電圧Ｅを直達日射量として記憶装置１２に登録する（ステップＳ８）。
【００２４】
そして、演算装置１３は、通信装置１４から通信指示が入力されているか否かを判断する（ステップＳ９）。ここで、通信指示がない場合には次の処理に進むが、通信指示がある場合には、その指示された内容の気象量を通信装置１４に出力する（ステップＳ１０）。
【００２５】
続いて、演算装置１３は、電波時計１１から取得した日時が記憶装置１２に予め記憶されている当日の測定終了時刻を過ぎているか判断する（ステップＳ１１）。ここで、過ぎている場合には次の処理に進むが、過ぎていない場合にはステップＳ１に戻って処理を繰り返す。つまり、記憶装置１２には、当日の測定終了時刻が過ぎるまでは一定の時間間隔で登録される直達日射量が順次蓄積されていく。
【００２６】
一方、このようにして測定終了時刻が過ぎた場合、演算装置１３は、ステップＳ３で開いたその日のファイルを閉じ（ステップＳ１２）、通信装置１４から通信指示が入力されているか否かを再び判断する（ステップＳ１３）。そして、通信指示が入力されている場合において、当該通信指示が日照時間及び直達日射量の総和量である場合には、記憶装置１３に蓄積された各直達日射量に基づいて日照時間及び直達日射量の総和量を算出し、通信装置１４に出力する（ステップＳ１４）。ここで、日照時間とは、直達日射量が所定のしきい値（例えば１２０Ｗ／ｍ²）を超えている時間の総和である。
【００２７】
なお、通信指示が日照時間及び直達日射量の総和量ではなく、日照時間のみである場合には、演算装置１３は、日照時間のみを算出して通信装置１４に出力する（ステップＳ１４）。さらに、通信指示が日照時間及び直達日射量の総和量でなく、また日照時間のみでもない場合には、演算装置１３は直達日射量の総和量のみを算出して通信装置１４に出力する（ステップＳ１４）。なお、通信指示がない場合には、演算装置１３は待機状態となる。
【００２８】
なお、本発明は上記実施形態に限定されるものではなく、例えば以下のような変形例が考えられる。
【００２９】
（１）上記実施形態では感光部Ａの構成要素である支柱２の形状を直角二等辺三角形（断面形状）としたが、図６に示すように上下底面が台形に形状設定された四角柱形状の支柱２’を採用することが考えられる。そして、この支柱２’において、上記台形の上底及び上底と下底を結ぶ２つの辺に対して垂直な３つの周面上に太陽電池２Ａ〜２Ｃ（光検出器）を各々１つずつ配置し、四角柱の上底面に太陽電池２Ｄ（背景光用光検出器）を配置する。このように構成された四角柱形状の支柱２’は、太陽電池２Ｄが配置された上底面が北を向き、また、周面と平行な中心線Ｌが地軸に対して平行になると共に上記台形の上底に対して垂直な面が正午に太陽から最も近くなるように姿勢設定される。
【００３０】
ここで、図７において、（ａ）は上記実施形態つまり三角柱形状の支柱２を用いた場合における各太陽電池２ａ，２ｂの合成指向特性を示し、（ｂ）は四角柱形状の支柱２’を用いた場合における各太陽電池２Ａ〜２Ｃの合成指向特性を示している。支柱２’を採用することにより、上記実施形態の場合よりもより均一な感度の部分のみを用いて太陽光の照射量を捉えることができるので、日照・日射に関する気象量をより正確に測定することが可能となる。
【００３１】
さらに、上記支柱２’を採用した場合には３つの太陽電池２Ａ〜２Ｃを用いることになるが、任意の個数すなわちｎ個の光検出器を用いる場合の補正演算式は下式（２）のようになる。ここでＥiは、i番目の太陽電池の出力電圧、Ｅpは乱反射量を測定する太陽電池の出力電圧、φiはi番目の太陽電池の受光面に鉛直な方向と照射光の照射方向とのなす角度である。
【００３２】
【数２】

【００３３】
（２）上記実施形態では、乱反射量を検出するための太陽電池を１つだけ設けたが、受光面の角度を異にして複数配置し、その平均値を取ることにより乱反射量を測定するようにしても良い。すなわち、受光面の角度を異にした複数の太陽電池で乱反射量を測定し、平均することでより正確な乱反射量を測定することができる。しかし、この場合、乱反射量を測定する太陽電池は全て照射光を直接受けない位置に配置する必要がある。
【００３４】
（３）上記実施形態では、太陽電池の受光面の垂直方向と照射光の照射方向との角度ξを記憶装置１２に記憶するようにした。しかし、角度ξをデータとして記憶するのではなく、測定日時に基づいて上記角度ξを算出するための角度演算式を記憶装置１２に記憶するようにしても良い。
【００３５】
（４）上記実施形態では、ＭＵＸ９を用いて太陽電池２ａ〜２ｃの各検出信号を選択してＡ／Ｄ変換器１０に入力するようにしたが、各々の太陽電池２ａ〜２ｃにＡ／Ｄ変換器１０を設けても良い。
【００３６】
（５）上記実施形態では、光検出器及び背景光用光検出器として太陽電池を用いたが、本発明はこれに限定されるものではない。
【００３７】
（６）上記実施形態では、気象量の出力に関して順序を設けて説明した。しかしながら、これにとらわれるものではなく、気象量の出力に関する形態は任意である。
【００３８】
【発明の効果】
以上説明したように、本発明によれば、太陽の照射光を所定の光検出器で検出することによって日照・日射に関する気象量を測定する日照・日射計であって、上記光検出器が検出する照射光の受光強度を所定の補正演算式を用いて光検出器の受光面に垂直な方向の受光強度に補正して日照・日射に関する気象量を測定するので、可動機構を備えることなく日照・日射に関する気象量を高精度に測定することが可能である。
【図面の簡単な説明】
【図１】 本発明の一実施形態に係わる日照・日射計における感光部Ａの構成図である。
【図２】 本発明の一実施形態に係わる感光部Ａの構成要素である三角柱形状の支柱２の斜視図である。
【図３】 本発明の一実施形態に係わる日照・日射計の電気的構成を示すブロック図である。
【図４】 本発明の一実施形態に係わる角度ξを説明するための図である。
【図５】 本発明の一実施形態に係わる日照・日射計の動作を示すフローチャートである。
【図６】 本発明の一実施形態の変形例に係わる支柱２’の斜視図である
【図７】 本発明の一実施形態における太陽電池の合成指向特性を示す模式図である。
【符号の説明】
１……支持具
２……支柱
２ａ，２ｂ，２Ａ〜２Ｃ……太陽電池（光検出器）
２ｃ，２Ｄ……太陽電池（背景光用光検出器）
３……遮光板
４……出力コネクタ
５……ガラスドーム
６……ホルダ
７……スタンド
８……取付台
９……ＭＵＸ（マルチプレクサ）
１０……Ａ／Ｄ変換器
１１……電波時計（計時手段）
１２……記憶装置（記憶手段）
１３……演算装置
１４……通信装置
Ａ……感光部
Ｌ……中心線[0001]
BACKGROUND OF THE INVENTION
The present invention is a sunshine / irradiometer for measuring a meteorological amount related to sunshine / irradiation.
[0002]
[Prior art and problems to be solved by the invention]
Conventionally, there are two types of sunshine / irradiometers: a fixed type and a tracking type. The fixed sunshine / irradiometer is fixedly installed in a predetermined posture, that is, by detecting the sun's irradiating light that changes from moment to moment with a photodetector in a fixed state, the sunshine duration, sunshine energy, etc. It measures the meteorological quantity. On the other hand, the tracking type sunshine / irradiometer tracks the sun, which is displaced every moment, so that the direct irradiation light from the sun is vertically incident on the light receiving surface of the photodetector.
[0003]
By the way, the direct solar radiation amount for measuring the meteorological amount related to sunshine and solar radiation is defined by WMO (World Meteorological Organization) as the received light intensity of the direct irradiation light perpendicularly incident on the light receiving surface. Therefore, the fixed sunshine / irradiometer does not always detect the direct irradiation light in the direction perpendicular to the light receiving surface, so the measurement accuracy is low. On the other hand, tracking sunshine / irradiometers have higher measurement accuracy than fixed sunshine / irradiometers, but a movable mechanism for tracking is essential, so they are not reliable and require relatively frequent maintenance. It must be done and cannot be run unattended.
[0004]
The present invention has been made in view of the above-described problems, and an object of the present invention is to measure a meteorological amount relating to sunshine and solar radiation with high accuracy without providing a movable mechanism for tracking.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, in the present invention, as a first means, there is a sunshine / irradiometer that measures the amount of weather related to sunshine / irradiation by detecting the irradiation light of the sun with a predetermined photodetector, A configuration in which the received light intensity of the irradiation light detected by the photodetector is corrected to a received light intensity in a direction perpendicular to the light receiving surface of the photodetector using a predetermined correction arithmetic expression, and a meteorological amount related to sunshine / sunshine is measured. adopt.
That is, according to the first means, the meteorological amount relating to sunshine and solar radiation is obtained by calculating the received light intensity of the irradiation light detected by the light detector in a direction perpendicular to the light receiving surface of the light detector using a predetermined correction formula. It is measured by correcting the received light intensity.
[0006]
As a second means, in the first means, a storage means for storing the angle between the vertical direction of the light receiving surface of the photodetector and the irradiation direction of the irradiation light as angle data corresponding to the measurement date and time, and giving the measurement date and time Obtaining specific angle data corresponding to the measurement date and time by searching the storage means based on the measurement date and time given from the time measurement means, and substituting the specific angle data into the correction formula Thus, a configuration is adopted in which the received light intensity of the irradiated light is corrected to the received light intensity in a direction perpendicular to the light receiving surface.
That is, according to the second means, the received light intensity of the irradiation light is stored in the storage means for storing the angle between the vertical direction of the light receiving surface of the photodetector and the irradiation direction of the irradiation light as angle data according to the measurement date and time. In a sunshine / pyrometer equipped with a timekeeping means for giving a measurement date and time, specific angle data corresponding to the measurement date and time is obtained by searching the storage means based on the measurement date and time given from the timekeeping means, and the identification Is corrected by substituting the angle data into the correction calculation formula.
[0007]
As a third means, the first or second means includes a plurality of light detectors set at different angles with respect to the irradiation direction of the irradiation light, and the irradiation light detected by the respective light detectors. A configuration is adopted in which the received light intensity is applied to a correction arithmetic expression for averaging and correcting the received light intensity.
That is, according to the third means, the received light intensity of the irradiation light detected by the plurality of photodetectors set at different angles with respect to the irradiation direction of the irradiation light is averaged and corrected by the correction arithmetic expression. .
[0008]
As a fourth means, in any one of the first to third means, a background light photodetector for detecting only the irregularly reflected light in the space included in the irradiation light is further provided, and the background light photodetector detects. A configuration is adopted in which the received light intensity of the irradiation light detected by the photodetector is corrected by the received light intensity of the irregularly reflected light in the space and applied to the correction calculation formula.
That is, according to the fourth means, the photodetector corrected by the received light intensity of the irregularly reflected light in the space detected by the photodetector for background light that detects only the irregularly reflected light in the space included in the irradiation light detects. The value of the received light intensity of the irradiation light is applied to the correction calculation formula.
[0009]
As a fifth means, in the fourth means, a plurality of background light detectors having light receiving surfaces set at different angles are provided, and the received light intensity of the irregularly reflected light in the space detected by each background light detector A configuration is adopted in which the received light intensity of the irradiation light detected by the photodetector is corrected by the average value.
That is, according to the fifth means, the received light intensity of the irradiation light detected by the photodetector is received by the irregularly reflected light in the space detected by the plurality of background light detectors whose light receiving surfaces are set at different angles. It is corrected by the average value of intensity.
[0010]
As a sixth means, in any one of the first to fifth means, a configuration is adopted in which the photodetector is a solar cell.
That is, according to the sixth means, the irradiation light is measured by the solar cell used for the photodetector.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of a sunshine / pyrometer according to the present invention will be described with reference to the drawings.
[0012]
FIG. 1 is a perspective view of a photosensitive portion A of a sunshine / pyrometer in the present embodiment. In this figure, reference numeral 1 is a support, 2 is a support, 2a is a solar cell (photodetector), 3 is a light shielding plate, 4 is an output connector, 5 is a glass dome, 6 is a holder, 7 is a stand, and 8 is an attachment. It is a stand. FIG. 2 is an enlarged perspective view of the support 2 in FIG. 1, and reference numerals 2a to 2c denote solar cells.
[0013]
The support 1 is a rod-like member that supports a rod-like support 2. As shown in FIG. 2, the support column 2 has a triangular prism shape set to a right isosceles triangle whose section is a base angle γ. The support column 2 is provided with solar cells 2a and 2b (light detectors), one on each of two surfaces perpendicular to the short sides of the right isosceles triangle, and the solar cell 2c (background light) on the upper bottom surface. Optical detector).
[0014]
The light shielding plate 3 is installed in order to prevent solar irradiation light from directly entering the upper bottom surface of the support column 2 on which the solar cell 2c is disposed. The output connector 4 is installed at the other end of the support 1. The glass dome 5 is made of glass and is provided so as to cover the support column 2 and the light shielding plate 3. The holder 6 supports the end of the support tool 1 and is connected to the stand 7 so that the support tool 1 can move in a vertical plane. The stand 7 is a rod-like member that connects the holder 6 and the mounting base 8 fixed to the ground.
[0015]
The photosensitive section A configured as described above has the mounting base 8 installed on a horizontal ground, the upper bottom surface of the support column 2 is directed to the north (in the direction of the North Star), and a center line L parallel to the peripheral surface is parallel to the ground axis. The posture is set so that the side shared by the surface on which the solar cell 2a is disposed and the surface on which the solar cell 2b is disposed faces the sun at noon. That is, by setting the posture of the photosensitive portion A in this way, one solar cell 2a provided on one surface of the support column 2 exclusively detects the amount of irradiation (intensity of irradiation light) in the morning, and the other solar cell. 2b exclusively detects the amount of irradiation in the afternoon. Moreover, the solar cell 2c detects only the amount of irregular reflection (the intensity of irregular reflection light in the space included in the irradiation light, that is, the intensity of background light).
[0016]
FIG. 3 is a block diagram showing the electrical configuration of the sunshine / irradiometer. In this figure, 2a to 2c are the solar cells described above, 9 is a MUX (multiplexer), 10 is an A / D converter, 11 is a radio clock (time measuring means), 12 is a storage device (storage means), and 13 is an arithmetic unit. , 14 are communication devices.
[0017]
The solar cells 2a to 2c are constituent elements of the photosensitive portion A, generate electric power by receiving irradiation light, and output as detection signals indicating the irradiation amount and the irregular reflection amount. The MUX 9 selectively selects the detection signals of the solar cells 2 a to 2 c based on the selection signal input from the arithmetic device 13 and outputs it to the A / D converter 10. The A / D converter 10 digitizes the detection signal (analog signal) input from the MUX 9 and outputs it to the arithmetic unit 13. The radio timepiece 11 receives the standard radio wave, measures the exact date and time, and outputs it to the arithmetic unit 13.
[0018]
The storage device 12 stores an angle ξ formed by the direction perpendicular to the light receiving surfaces of the solar cells 2a and 2b and the irradiation direction of the irradiation light as shown in FIG. (1) is also stored. This correction calculation formula (1) uses the above-mentioned angle ξ, the output voltage Ea of the solar cell 2a, the output voltage Eb of the solar cell 2b, and the output voltage Ec of the solar cell 2c as variables, and the amount of direct solar radiation (light reception of the solar cells 2a and 2b). The correction voltage E corresponding to the intensity of light received in the direction perpendicular to the surface is given.
[0019]
[Expression 1]

[0020]
The arithmetic device 13 acquires the angle ξ corresponding to the date and time output from the radio timepiece 11 from the storage device 12, and substitutes the angle ξ and the irradiation amount of the solar cells 2a and 2b into the correction arithmetic expression (1). Thus, the correction voltage E corresponding to the direct solar radiation amount is calculated. The correction voltage E (that is, the amount of direct solar radiation) is stored as registration data in the storage device 12. In addition, the arithmetic device 13 calculates a measurement amount such as the sunshine duration or the total amount of the direct solar radiation from the plurality of direct solar radiation amounts accumulated in the storage device 12, that is, a weather amount relating to the solar radiation and solar radiation, and outputs it to the communication device 14. To do. The communication apparatus 14 transmits the weather amount regarding the said sunshine and solar radiation to a weather center.
[0021]
Next, an example of the operation of the sunshine / pyrometer configured as described above will be described in detail with reference to FIG.
[0022]
For example, the arithmetic unit 13 acquires the measurement date and time from the radio clock 11 at regular time intervals (step S1), and when the date of the measurement date and time is updated (step S2), the new date file is opened. That is, the arithmetic unit 13 opens a new file after midnight. If the measurement date has not been updated (step S2), the process proceeds to the next process without opening a new file. Then, the arithmetic device 13 checks whether or not the measurement date and time has passed the measurement start time of the day stored in advance in the storage device 12 (step S4). If the measurement date / time has passed the measurement start time, the arithmetic unit 13 proceeds to the next process. If the measurement date / time has not passed, the calculation device 13 obtains the measurement date / time from the radio timepiece 11 again after a fixed time interval. (Step S1). That is, the arithmetic device 13 is in a standby state until the measurement start time on that day has passed.
[0023]
Subsequently, the arithmetic device 13 switches the MUX 9 to switch the output voltages Ea and Eb corresponding to the irradiation amount from the solar cells 2a and 2b via the A / D converter 10, and the output corresponding to the diffuse reflection amount from the solar cell 2c. The voltage Ec is sequentially acquired (step S5), and the angle ξ (angle data) corresponding to the measurement date and time is acquired from the storage device 12 (step S6). Then, the arithmetic unit 13 calculates the correction voltage E by substituting each of the output voltages Ea to Ec and the angle ξ into the correction arithmetic expression (1) (step S7), and stores this output voltage E as the direct solar radiation amount. Register in the device 12 (step S8).
[0024]
Then, the arithmetic device 13 determines whether or not a communication instruction is input from the communication device 14 (step S9). If there is no communication instruction, the process proceeds to the next process. If there is a communication instruction, the meteorological amount of the instructed content is output to the communication device 14 (step S10).
[0025]
Subsequently, the arithmetic device 13 determines whether or not the date and time acquired from the radio timepiece 11 has passed the measurement end time of the day stored in advance in the storage device 12 (step S11). If it has passed, the process proceeds to the next process. If not, the process returns to step S1 to repeat the process. That is, the amount of direct solar radiation that is registered at regular time intervals is sequentially stored in the storage device 12 until the measurement end time of the current day has passed.
[0026]
On the other hand, when the measurement end time has passed in this way, the arithmetic device 13 closes the file of the day opened in step S3 (step S12), and determines again whether or not a communication instruction is input from the communication device 14. (Step S13). If a communication instruction is input and the communication instruction is the total amount of sunshine hours and direct solar radiation, the sunshine hours and direct solar radiation are based on the direct solar radiation accumulated in the storage device 13. The total amount of the amounts is calculated and output to the communication device 14 (step S14). Here, the sunshine time is the total time during which the amount of direct solar radiation exceeds a predetermined threshold (for example, 120 W / m ² ).
[0027]
When the communication instruction is not only the total amount of the sunshine hours and the amount of direct solar radiation but only the sunshine hours, the arithmetic device 13 calculates only the sunshine hours and outputs them to the communication device 14 (step S14). Further, when the communication instruction is not the total amount of the sunshine time and the direct solar radiation amount, and is not only the sunshine time, the arithmetic device 13 calculates only the total amount of the direct solar radiation amount and outputs it to the communication device 14 (step). S14). When there is no communication instruction, the arithmetic device 13 enters a standby state.
[0028]
In addition, this invention is not limited to the said embodiment, For example, the following modifications can be considered.
[0029]
(1) In the above-described embodiment, the shape of the column 2 that is a constituent element of the photosensitive portion A is a right isosceles triangle (cross-sectional shape). However, as shown in FIG. It is conceivable to use the post 2 ′. And in this support | pillar 2 ', one solar cell 2A-2C (photodetector) is each on three surrounding surfaces perpendicular | vertical with respect to two sides which connect the upper base of the said trapezoid, and an upper base and a lower base. The solar cell 2D (background light photodetector) is disposed on the upper and bottom surfaces of the quadrangular prism. The quadrangular prism-shaped support column 2 ′ configured in this way has an upper bottom surface on which the solar cell 2D is disposed facing north, a center line L parallel to the peripheral surface is parallel to the ground axis, and the trapezoidal shape. The posture is set so that the plane perpendicular to the top base of the top is closest to the sun at noon.
[0030]
Here, in FIG. 7, (a) shows the combined directivity characteristics of the solar cells 2a and 2b when the above embodiment, that is, the triangular prism-shaped support column 2 is used, and (b) shows the square column-shaped support column 2 ′. The composite directivity characteristic of each solar cell 2A-2C in the case of using is shown. By adopting the column 2 ′, it is possible to capture the amount of sunlight irradiated using only the part with a more uniform sensitivity than in the case of the above-described embodiment, so that the amount of weather related to sunlight and solar radiation can be measured more accurately. It becomes possible.
[0031]
Further, when the support column 2 ′ is adopted, three solar cells 2A to 2C are used, but the correction calculation formula when using an arbitrary number, that is, n photodetectors is the following formula (2). It becomes like this. Here, Ei is the output voltage of the i-th solar cell, Ep is the output voltage of the solar cell that measures the amount of diffuse reflection, and φi is the direction perpendicular to the light-receiving surface of the i-th solar cell and the irradiation direction of the irradiation light Is an angle.
[0032]
[Expression 2]

[0033]
(2) In the above embodiment, only one solar cell for detecting the amount of irregular reflection is provided, but a plurality of light receiving surfaces are arranged at different angles, and the amount of irregular reflection is measured by taking an average value thereof. Anyway. That is, it is possible to measure the amount of irregular reflection more accurately by measuring the amount of irregular reflection with a plurality of solar cells with different angles of the light receiving surface and averaging them. However, in this case, it is necessary to arrange all the solar cells for measuring the amount of irregular reflection at positions where they do not directly receive irradiation light.
[0034]
(3) In the above embodiment, the angle ξ between the vertical direction of the light receiving surface of the solar cell and the irradiation direction of the irradiation light is stored in the storage device 12. However, the angle ξ for calculating the angle ξ based on the measurement date and time may be stored in the storage device 12 instead of storing the angle ξ as data.
[0035]
(4) In the above embodiment, each detection signal of the solar cells 2a to 2c is selected and input to the A / D converter 10 using the MUX 9, but the A / D is applied to each of the solar cells 2a to 2c. A converter 10 may be provided.
[0036]
(5) Although the solar cell is used as the photodetector and the photodetector for background light in the above embodiment, the present invention is not limited to this.
[0037]
(6) In the above-described embodiment, the description has been given with respect to the output of the weather amount. However, the present invention is not limited to this, and the form relating to the output of the weather amount is arbitrary.
[0038]
【The invention's effect】
As described above, according to the present invention, there is provided a sunshine / irradiometer that measures the amount of weather related to sunshine / irradiation by detecting the irradiation light of the sun with a predetermined photodetector, and the photodetector detects The light intensity of the irradiated light is corrected to the light intensity in the direction perpendicular to the light receiving surface of the photodetector using a predetermined correction formula, and the meteorological amount related to sunshine and solar radiation is measured.・ It is possible to measure the amount of weather related to solar radiation with high accuracy.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a photosensitive portion A in a sunshine / irradiometer according to an embodiment of the present invention.
FIG. 2 is a perspective view of a triangular pillar-shaped column 2 that is a component of a photosensitive section A according to an embodiment of the present invention.
FIG. 3 is a block diagram showing an electrical configuration of a sunshine / pyrometer according to an embodiment of the present invention.
FIG. 4 is a diagram for explaining an angle ξ according to an embodiment of the present invention.
FIG. 5 is a flowchart showing the operation of the sunshine / pyrometer according to the embodiment of the present invention.
FIG. 6 is a perspective view of a support column 2 ′ according to a modification of one embodiment of the present invention. FIG. 7 is a schematic diagram showing a combined directivity characteristic of a solar cell according to one embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Support tool 2 ... Support | pillar 2a, 2b, 2A-2C ... Solar cell (photodetector)
2c, 2D ... Solar cell (light detector for background light)
3 ... Light shielding plate 4 ... Output connector 5 ... Glass dome 6 ... Holder 7 ... Stand 8 ... Mount 9 ... MUX (Multiplexer)
10 …… A / D converter 11 …… Radio clock (time measuring means)
12 ... Storage device (storage means)
13 …… Computing device 14… Communication device A …… Photosensitive part L …… Center line

Claims (2)

A sunshine / irradiometer that measures the amount of weather related to sunshine / irradiation by detecting the sun's irradiation light with a predetermined photodetector,
Storage means for storing two photodetectors whose angles are set so that the light receiving surface is shifted by 90 °, and an angle ξ between the vertical direction of the light receiving surface of the photodetector and the irradiation direction of the irradiation light as angle data corresponding to the measurement date and time And a timing means for giving a measurement date and time, a background light detector for detecting only the irregularly reflected light in the space included in the irradiation light, and an arithmetic unit,
The arithmetic unit obtains specific angle data corresponding to the measurement date by searching the storage unit based on the measurement date given from the time measuring means, and the angle ξ indicated by the obtained angle data, one photodetector The direct solar radiation amount E is calculated by substituting the output voltage Ea of the other light detector, the output voltage Eb of the other photodetector, and the output voltage Ec of the background light photodetector into the following equation (1). A sunshine / irradiometer that measures the amount of weather related to sunshine / irradiation based on E.

    2. The sunshine / pyrometer according to claim 1, wherein the photodetector or / and the background light photodetector is a solar cell.

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