TW201816344A - Tilting solar tracking system used at low latitude - Google Patents

Tilting solar tracking system used at low latitude Download PDF

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TW201816344A
TW201816344A TW105135068A TW105135068A TW201816344A TW 201816344 A TW201816344 A TW 201816344A TW 105135068 A TW105135068 A TW 105135068A TW 105135068 A TW105135068 A TW 105135068A TW 201816344 A TW201816344 A TW 201816344A
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sun
angle
tilt
pointing device
solar
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TW105135068A
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TWI629440B (en
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任才俊
李聖文
胡晉嘉
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崑山科技大學
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Abstract

A tilting solar tracking system used at low latitude comprising a tilt base and a rotation means is provided. The tilt base has a tilt angle and face to high latitude. The rotation means be fixed on the tilt base, accordingly, the rotation means is not only tracking the sun but also can avoid the angular velocity rising intense.

Description

利用於低緯度的傾斜式追日系統Tilt-type chasing system for low latitude

本發明係關於一種追日系統,尤指利用於低緯度的傾斜式追日系統。The present invention relates to a sun-tracking system, and more particularly to a tilt-type sun-tracking system for use at low latitudes.

現今世界各國在努力振興經濟發展的狀況下,需兼顧能源安全與對抗氣候變遷,因此對於綠色能源漸漸重視,加速發展綠色經濟為各國共同的目標,在面對地球能源與資源逐漸耗竭的背景下,太陽光電、風力發電、氫能與燃料電池、生質能與其他新能源成為地球永續發展之重要議題。Nowadays, in an effort to revitalize economic development, countries around the world need to balance energy security with climate change. Therefore, green energy is gradually being paid attention to, and accelerating the development of a green economy is a common goal of all countries. In the context of the gradual depletion of the earth's energy and resources. Solar photovoltaic, wind power, hydrogen and fuel cells, biomass and other new energy sources have become important issues for the sustainable development of the planet.

太陽能基本上為取之不盡、用之不竭的乾淨能源,在光照充足無遮蔽的地區,在接受太陽的照射下,能量的供應將源源不斷,能源產生的過程不會產生環境污染,也不會導致溫室效應及排放廢水、廢氣的問題。Solar energy is basically an inexhaustible source of clean energy. In areas where there is sufficient light and no cover, the supply of energy will continue under the illumination of the sun, and the process of energy generation will not cause environmental pollution. It will not cause greenhouse effect and discharge of waste water and waste gas.

太陽能設施一般係立體式設施,將如太陽能板之太陽裝置架高,儘量的面向太陽,以吸收太陽光來轉換成電能供人們使用。太陽光的能量傳遞至太陽能板與其光線入射角有關,理論上愈接近垂直90度,光電轉換之能量愈高,為達此目的,近年將太陽能板的設計加上追日技術是一大趨勢,實際測試可提高太陽能發電效率達30%~50%。Solar installations are generally three-dimensional facilities, such as solar panels with solar panels, as far as possible facing the sun, to absorb sunlight to convert into electricity for people to use. The energy of sunlight is transmitted to the solar panel and its angle of incidence is relatively high. In theory, the closer to vertical 90 degrees, the higher the energy of photoelectric conversion. To achieve this goal, the design of solar panels and the pursuit of Japanese technology are a major trend in recent years. The actual test can increase the solar power generation efficiency by 30%~50%.

請參閱圖1,圖1係低緯度地區太陽路徑10之示意圖,此圖例特別是以台灣的台南地區來作為樣本採計,是以追日系統為圖式中心點,以360度視角觀看全景。但由於在低緯度地區,特別是在夏至時節的時候,太陽路徑10不繞經這種傳統式追日系統的天頂12位置,依圖式來看,整個太陽路徑10皆在靠近高緯度方向,從天頂12位置的北方直接繞過去。Please refer to FIG. 1. FIG. 1 is a schematic diagram of a solar path 10 in a low latitude region. The illustration is taken in the Tainan area of Taiwan as a sample, and the sun-tracking system is used as a center point of the drawing to view the panorama from a 360-degree angle. However, since in the low latitudes, especially in the summer solstice season, the solar path 10 does not follow the zenith 12 position of the traditional chasing system, according to the figure, the entire solar path 10 is close to the high latitude, from The northern part of the zenith 12 is directly bypassed.

如此,在接近中午時分的時候,追日系統的水平面旋轉狀態會由原本的順時鐘旋轉,迅速改為逆時針旋轉,水平轉動之角速度會有劇烈變化,雖然目前控制器的響應是能夠迅速反應的,也可以進行補償,以確保追蹤精度,但這將造成整體追日系統發生較多的能量損耗。In this way, when it is close to noon, the horizontal rotation of the chasing system will be rotated from the original clockwise, and it will quickly change to counterclockwise rotation. The angular velocity of the horizontal rotation will change drastically, although the response of the controller is fast. The reaction can also be compensated to ensure tracking accuracy, but this will cause more energy loss in the overall chasing system.

因此,本發明的主要目的在於提供一種利用於低緯度的傾斜式追日系統,以解決上述問題。Accordingly, it is a primary object of the present invention to provide a tilt-type chasing system for use at low latitudes to solve the above problems.

本發明之目的在提供一種利用於低緯度的傾斜式追日系統,不僅達到追日功效以得到最佳的太陽能轉換利用,更考慮低緯度地區太陽路徑於夏至時節未經天頂的問題,產生理想的追日系統固定傾斜角,據此,可讓追日系統在低緯度地區應用時更節能。The object of the present invention is to provide a tilt-type chasing system for low latitude, which not only achieves the effect of chasing the sun for optimal solar energy conversion, but also considers that the solar path in the low latitude region has no zenith problem in the summer solstice period, and the ideal is generated. The chase-day system has a fixed tilt angle, which allows the Chasing System to be more energy efficient when used in low latitudes.

本發明係關於一種利用於低緯度的傾斜式追日系統,係能使太陽裝置追蹤並指向太陽,所述太陽裝置例如可為太陽能板,傾斜式追日系統係包含傾斜基座、以及指向裝置。The present invention relates to a tilt-type chasing system for low latitude, which enables the solar device to track and point to the sun, the solar device can be, for example, a solar panel, and the tilt-type chasing system includes a tilting base and a pointing device. .

傾斜基座係朝向高緯度傾斜,並與水平面具有固定之傾斜角,其中傾斜角係為回歸線緯度減去傾斜式追日系統所在緯度,再加上偏離角度,而所述偏離角度係大於等於7度。指向裝置係裝設於傾斜基座上,太陽裝置裝設於指向裝置,指向裝置係包含平面旋轉模組、以及仰角控制模組。The inclined base is inclined toward a high latitude and has a fixed inclination angle with respect to the horizontal plane, wherein the inclination angle is a regression line latitude minus a latitude of the inclined day tracking system, plus an off angle, and the deviation angle is greater than or equal to 7 degrees. . The pointing device is mounted on the tilting base, and the sun device is mounted on the pointing device. The pointing device comprises a planar rotating module and an elevation control module.

平面旋轉模組係沿傾斜基座之平面以轉動,以控制太陽裝置於傾斜基座上之平面旋轉角。仰角控制模組係控制太陽裝置於傾斜基座上之俯仰角。The planar rotary module is rotated along the plane of the tilting base to control the planar rotation angle of the solar device on the tilting base. The elevation control module controls the pitch angle of the sun device on the tilt base.

進一步說明,傾斜式追日系統更包含控制器,係根據太陽之星曆資料,及根據傾斜角,轉化以得平面旋轉角與俯仰角。Further, the tilt-type sun-tracking system further includes a controller that converts the plane rotation angle and the elevation angle according to the sun's ephemeris data and according to the tilt angle.

此外,指向裝置更包含編碼器,編碼器用以偵測指向裝置實際之平面旋轉角以及俯仰角,藉以回校控制器。In addition, the pointing device further includes an encoder for detecting the actual plane rotation angle and the pitch angle of the pointing device, thereby returning to the controller.

指向裝置所在傾斜基座位置之法線高於指向裝置處稱為斜面天頂,藉由本發明所實施之傾斜式追日系統,太陽之移動軌跡於接近斜面天頂時,係可位於相較斜面天頂之較低緯度方向之位置。The normal line of the position of the tilting base of the pointing device is higher than that of the pointing device, which is called the inclined zenith. With the inclined sun-tracking system implemented by the present invention, when the moving track of the sun approaches the zenith of the inclined surface, it can be located at the zenith of the inclined surface. The position in the lower latitude direction.

因此,利用本發明所提供一種利用於低緯度的傾斜式追日系統,利用太陽之星曆資料的換算,不僅達到追日功效以得到最佳的太陽能轉換利用,更考慮低緯度地區太陽路徑於夏至時節未經天頂的問題,藉由傾斜基座產生理想的追日系統固定傾斜角,據此,可讓追日系統避免反轉所產生角速度劇烈變化,在低緯度地區應用時能更加節能。Therefore, the use of the tilt-type chasing system for low latitude according to the present invention, using the conversion of the solar ephemeris data, not only achieves the effect of chasing the sun to obtain the best solar energy conversion utilization, but also considers the solar path in the low latitude region. In the summer solstice period, without the problem of the zenith, the tilting pedestal produces an ideal tilt angle of the chasing system. According to this, the chasing system can avoid the sharp change of the angular velocity generated by the reversal, and it can be more energy-efficient when applied in low latitudes.

關於本發明之優點與精神可以藉由以下的發明詳述及所附圖式得到進一步的瞭解。The advantages and spirit of the present invention will be further understood from the following detailed description of the invention.

請參閱圖2,圖2係本發明傾斜式追日系統30之示意圖。本發明係關於一種利用於低緯度的傾斜式追日系統30,係能使如太陽能板的太陽裝置32追蹤並指向太陽,傾斜式追日系統30係包含傾斜基座34、以及指向裝置36。Please refer to FIG. 2. FIG. 2 is a schematic diagram of the inclined day chasing system 30 of the present invention. The present invention relates to a tilt-type chasing system 30 for use at low latitudes for enabling solar devices 32 such as solar panels to track and direct the sun. The tilt-type chasing system 30 includes a tilting base 34 and a pointing device 36.

傾斜基座34係朝向高緯度傾斜,並與水平面具有固定之傾斜角。指向裝置36係裝設於傾斜基座34上,太陽裝置32裝設於指向裝置36,指向裝置36係包含平面旋轉模組3602以及仰角控制模組3604。The tilt base 34 is inclined toward a high latitude and has a fixed inclination angle with respect to the horizontal plane. The pointing device 36 is mounted on the tilt base 34, and the sun device 32 is mounted on the pointing device 36. The pointing device 36 includes a planar rotation module 3602 and an elevation control module 3604.

平面旋轉模組3602係沿傾斜基座34之平面以轉動,以控制太陽裝置32於傾斜基座34上之平面旋轉角,仰角控制模組3604係控制太陽裝置32於傾斜基座34上之俯仰角。The planar rotation module 3602 is rotated along the plane of the tilt base 34 to control the planar rotation angle of the solar device 32 on the tilt base 34. The elevation control module 3604 controls the pitch of the solar device 32 on the tilt base 34. angle.

進一步參閱圖3,圖3係本發明傾斜基座34演算平面旋轉角β與俯仰角α之示意圖。傾斜基座34朝向高緯度傾斜,圖例係為設置在台灣台南地區之傾斜式追日系統30實施例,所以朝向北方傾斜,傾斜基座34具有一個傾斜面3402,此傾斜面3402並與水平面3404具有固定之傾斜角λ。Referring further to FIG. 3, FIG. 3 is a schematic diagram of the tilting base 34 of the present invention calculating the plane rotation angle β and the pitch angle α. The inclined base 34 is inclined toward a high latitude, and the illustration is an embodiment of the inclined sun-tracking system 30 installed in the Tainan area of Taiwan, so it is inclined toward the north, and the inclined base 34 has an inclined surface 3402 which has a horizontal plane 3404 and has a horizontal plane 3404. Fixed tilt angle λ.

傾斜式追日系統30更包含控制器(圖未示),係根據太陽之星曆資料,及根據傾斜角λ,轉化以得平面旋轉角β與俯仰角α。平面旋轉角β為指向太陽的移動過程,在傾斜面3402上平面的轉動幅度所形成計量的角度。俯仰角α為指向太陽的移動過程,自傾斜面3402改變俯仰度所形成計量的角度。The tilt-type chasing system 30 further includes a controller (not shown) that converts the plane rotation angle β and the pitch angle α according to the sun's ephemeris data and according to the tilt angle λ. The plane rotation angle β is a moving process directed to the sun, and the amplitude of the rotation of the plane on the inclined surface 3402 forms a metered angle. The pitch angle α is a moving process directed to the sun, and the angle of the metering formed by the pitch is changed from the inclined surface 3402.

假設太陽能板到其轉動軸接點的距離為長度D,我們建立一個三維座標系統,以正北為X軸,正東為Y軸,則藉由太陽之星曆資料,可由此時之日期知道以水平面3404為座標的水平面旋轉角θ與水平面俯仰角ψ,藉此我們可算出太陽指向的直角座標(X,Y,Z):X=cosψcosθ;Y=cosψsinθ;Z=sinψ。Assuming that the distance from the solar panel to the joint of its rotating shaft is the length D, we establish a three-dimensional coordinate system with the north as the X-axis and the east as the Y-axis, and the solar star calendar data can be known from the date. The horizontal plane rotation angle θ and the horizontal plane elevation angle 为 with the horizontal plane 3404 as the coordinates, by which we can calculate the right-angled coordinates (X, Y, Z) of the sun pointing: X = cos ψ cos θ; Y = cos ψ sin θ; Z = sin ψ.

接著,換算平面旋轉角β與俯仰角α:α=sin-1 (X*sinλ+Z*cosλ);β=sin-1 。如此,指向裝置36就可以依平面旋轉角β與俯仰角α來轉動太陽裝置32,使太陽裝置32達成指日並追日的目的。Next, the plane rotation angle β and the pitch angle α are converted: α=sin -1 (X*sinλ+Z*cosλ); β=sin -1 . Thus, the pointing device 36 can rotate the solar device 32 according to the plane rotation angle β and the pitch angle α, so that the solar device 32 can achieve the purpose of day-to-day and chasing the sun.

進一步,為做到系統回饋校正,指向裝置36更包含編碼器(圖未示),編碼器裝設在指向裝置36上,用以偵測指向裝置36實際之平面旋轉角α’以及俯仰角β’,藉由平面旋轉角α’以及俯仰角β’可算太陽指向的直角座標(X1,Y1,Z1):X1=D(cosα’cosβ’cosλ+sinα’sinλ);Y1 =D(cosα’sinβ’);Z1 =D(sinα’cosλ- cosα’cosβ’ sinλ)。Further, in order to perform system feedback correction, the pointing device 36 further includes an encoder (not shown), and the encoder is mounted on the pointing device 36 for detecting the actual plane rotation angle α' of the pointing device 36 and the pitch angle β. ', by the plane rotation angle α' and the elevation angle β' can be calculated as the right angle coordinates (X1, Y1, Z1) of the sun: X1 = D (cosα'cosβ'cosλ + sinα'sinλ); Y1 = D (cosα'sinβ '); Z1 = D(sinα'cosλ- cosα'cosβ' sinλ).

接著,可以算出實際的水平面旋轉角θ’與水平面俯仰角ψ’:θ’=cos-1 ;ψ’=tan-1 ,藉由比對實際的水平面旋轉角θ’與水平面俯仰角ψ’與前述所產生的水平面旋轉角θ與水平面俯仰角ψ,以其中之差值可以回校控制器。Next, the actual horizontal rotation angle θ' and the horizontal elevation angle ψ' can be calculated: θ' = cos -1 ;ψ'=tan -1 By comparing the actual horizontal plane rotation angle θ' with the horizontal plane elevation angle ψ' and the aforementioned horizontal plane rotation angle θ and the horizontal plane elevation angle ψ, the difference can be returned to the controller.

關於前述之傾斜角λ,本發明實用的算法可以採用:傾斜角λ等於回歸線緯度減去傾斜式追日系統30所在緯度,再加上偏離角度,其中經由反覆測試後,則偏離角度以大於等於7度,並且不要大於太多為佳。Regarding the aforementioned tilt angle λ, the practical algorithm of the present invention can adopt: the tilt angle λ is equal to the regression line latitude minus the latitude of the tilt type chasing system 30, plus the deviation angle, wherein after the repeated test, the deviation angle is greater than or equal to 7 degrees, and not more than too much is better.

請參閱圖4,圖4係本發明中太陽路徑40相對傾斜面3402之示意圖。圖1述在地平面上太陽路徑10無法通過天頂12,本發明中指向裝置36所在傾斜基座34傾斜面3402位置之法線,高於指向裝置36處稱為斜面天頂42,其中太陽之移動軌跡於接近斜面天頂42時,因為有傾斜角λ,移動軌跡就可位於相較斜面天頂42之較低緯度方向之位置。Please refer to FIG. 4. FIG. 4 is a schematic diagram of the sun path 40 relative to the inclined surface 3402 in the present invention. 1 shows that the sun path 10 cannot pass through the zenith 12 at the ground level. In the present invention, the normal position of the inclined surface 342 of the tilting base 34 of the pointing device 36 is higher than that of the pointing device 36, which is called the inclined zenith 42 where the sun moves. When the trajectory approaches the sloping apex 42, the trajectory can be located at a position lower than the latitude of the sloping apex 42 because of the inclination angle λ.

前述偏離角度的設計用意,就是在使太陽之移動軌跡如圖4越過斜面天頂42,也就是使移動軌跡跨到斜面天頂42的南方,如此,就不會有追日系統的旋轉狀態由順時鐘旋轉迅速改為逆時針旋轉,而使水平轉動之角速度發生劇烈變化的情形。The above-mentioned deviation angle design intention is to make the movement track of the sun cross the inclined zenith 42 as shown in FIG. 4, that is, to make the movement track cross to the south of the slanted zenith 42, so that there is no rotation state of the chasing system by clockwise The rotation is quickly changed to a counterclockwise rotation, and the angular velocity of the horizontal rotation is drastically changed.

因此,利用本發明所提供一種利用於低緯度的傾斜式追日系統30,利用太陽之星曆資料的換算,不僅達到追日功效以得到最佳的太陽能轉換利用,更考慮低緯度地區太陽路徑於夏至時節未經天頂的問題,藉由傾斜基座34產生理想的追日系統固定傾斜角λ,據此,可讓追日系統在低緯度地區應用時更節能。Therefore, the tilt-type chasing system 30 for low latitude is provided by the present invention, and the conversion of the solar ephemeris data is used to not only achieve the best of solar energy utilization, but also to optimize the solar energy utilization in the low latitude region. In the summer solstice, without the problem of the zenith, the tilting pedestal 34 produces an ideal chase angle λ of the chasing system, which makes the chasing system more energy efficient when applied in low latitudes.

藉由以上較佳具體實施例之詳述,係希望能更加清楚描述本發明之特徵與精神,而並非以上述所揭露的較佳具體實施例來對本發明之範疇加以限制。相反地,其目的是希望能涵蓋各種改變及具相等性的安排於本發明所欲申請之專利範圍的範疇內。The features and spirit of the present invention will be more apparent from the detailed description of the preferred embodiments. On the contrary, the intention is to cover various modifications and equivalents within the scope of the invention as claimed.

30‧‧‧傾斜式追日系統
32‧‧‧太陽裝置
34‧‧‧傾斜基座
3402‧‧‧傾斜面
3404‧‧‧水平面
36‧‧‧指向裝置
3602‧‧‧平面旋轉模組
3604‧‧‧仰角控制模組
40‧‧‧太陽路徑
42‧‧‧斜面天頂
λ‧‧‧傾斜角
β‧‧‧平面旋轉角
α‧‧‧俯仰角
θ‧‧‧水平面旋轉角
ψ‧‧‧水平面俯仰角
30‧‧‧ Tilt-type chasing system
32‧‧‧Solar device
34‧‧‧ tilt base
3402‧‧‧Sloping surface
3404‧‧‧ horizontal plane
36‧‧‧ pointing device
3602‧‧‧Flat Rotary Module
3604‧‧‧ elevation control module
40‧‧‧Sun Path
42‧‧‧Bevel zenith λ‧‧‧inclination angle β‧‧‧plane rotation angle α‧‧‧pitch angle θ‧‧‧water plane rotation angle ‧‧‧ horizontal plane elevation angle

圖1 係低緯度地區太陽路徑之示意圖; 圖2 係本發明傾斜式追日系統之示意圖; 圖3 係本發明傾斜基座演算平面旋轉角與俯仰角之示意圖;以及 圖4 係本發明中太陽路徑相對傾斜面之示意圖。1 is a schematic view of a solar path in a low latitude region; FIG. 2 is a schematic view of a tilting chasing system according to the present invention; FIG. 3 is a schematic view showing a plane rotation angle and a pitch angle of a tilting base of the present invention; and FIG. A schematic diagram of the path relative to the inclined surface.

Claims (7)

一種利用於低緯度的傾斜式追日系統,係能使一太陽裝置追蹤並指向太陽,該傾斜式追日系統係包含: 一傾斜基座,係朝向高緯度傾斜,並與水平面具有固定之傾斜角;以及 一指向裝置,係裝設於該傾斜基座上,該太陽裝置裝設於該指向裝置,該指向裝置係包含 一平面旋轉模組,係沿該傾斜基座之平面以轉動,以控制該太陽裝置於該傾斜基座上之平面旋轉角,及 一仰角控制模組,係控制該太陽裝置於該傾斜基座上之俯仰角。A tilt-type chasing system for low latitude enables a solar device to track and point to the sun. The tilt-type chasing system includes: a tilting base that is tilted toward a high latitude and has a fixed tilt angle with the horizontal plane. And a pointing device mounted on the tilting base, the sun device is mounted on the pointing device, the pointing device includes a planar rotating module, which is rotated along a plane of the tilting base to control The plane rotation angle of the solar device on the inclined base, and an elevation control module control the pitch angle of the solar device on the inclined base. 如申請專利範圍第1項所述之傾斜式追日系統,其中所述之太陽裝置係為一太陽能板。The inclined sun-tracking system according to claim 1, wherein the solar device is a solar panel. 如申請專利範圍第1項所述之傾斜式追日系統,其中該傾斜角係為回歸線緯度減去該傾斜式追日系統所在緯度,再加上一偏離角度。The inclined day chasing system according to claim 1, wherein the tilt angle is a regression line latitude minus a latitude of the tilt type chasing system, plus an off angle. 如申請專利範圍第3項所述之傾斜式追日系統,其中該偏離角度係大於等於7度。The inclined day chasing system according to claim 3, wherein the deviation angle is greater than or equal to 7 degrees. 如申請專利範圍第1項所述之傾斜式追日系統,該傾斜式追日系統更包含一控制器,係根據太陽之星曆資料,及根據該傾斜角,轉化以得該平面旋轉角與該俯仰角。The inclined sun-tracking system according to claim 1, wherein the tilt-type sun-tracking system further comprises a controller, which is converted according to the sun's ephemeris data and according to the tilt angle to obtain the plane rotation angle and The pitch angle. 如申請專利範圍第5項所述之傾斜式追日系統,其中該指向裝置更包含一編碼器,該編碼器用以偵測該指向裝置實際之平面旋轉角以及俯仰角,藉以回校該控制器。The slanting sun-tracking system of claim 5, wherein the pointing device further comprises an encoder for detecting an actual plane rotation angle and a pitch angle of the pointing device, thereby returning the controller . 如申請專利範圍第1項所述之傾斜式追日系統,該指向裝置所在該傾斜基座位置之法線高於該指向裝置處稱為一斜面天頂,其中該太陽之移動軌跡於接近該斜面天頂時,係位於相較該斜面天頂之較低緯度方向之位置。The inclined sun-tracking system according to claim 1, wherein the pointing device is located at a position higher than a normal of the tilting base, and is called a beveled zenith, wherein the moving track of the sun is close to the inclined surface. At the zenith, the system is located at a lower latitude than the zenith of the slope.
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