• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A shadow band assembly includes a platform and an arcuate shadow arm extending upward from the platform and terminating in a free end above the platform. A sun sensor mounting location is located below the free end of the shadow arm. The arm is preferably further supported by a vertical strut. According to other embodiments, the arm is hollow and contains a fluid conduit and/or an electrical cable. A sun sensor may be mounted on top of the free end of the arm and a fluid nozzle may be mounted under the free end. A shadow band pyranometer includes the shadow band assembly, a sun sensor mounted at the mounting location and a motor drive coupled to the platform for azimuth tracking. Additional sensors with zenith tracking may also be provided.
    公开号:NL2006209A
    申请号:NL2006209
    申请日:2011-02-16
    公开日:2011-08-18
    发明作者:Robert Dolce
    申请人:Robert Dolce;
    IPC主号:
    专利说明:

    SHADOW BAND ASSEMBLY FOR USE WITH A PYRANOMETER AND A SHADOW BAND PYRANOMETER INCORPORATING SAME BACKGROUND OF THE INVENTION
    FIELD OF THE INVENTION
    This invention relates broadly to pyranomctcrs. More particularly, this invention relates to shadow band pyranometers for measuring diffuse solar radiation throughout the course of a day.
    STATE OF THE ART
    Pyranometers are a class of actinometers that measure the combined intensity of solar radiation. Pyranometers are used largely in research, particularly meteorological research. However, they are also used in agricultural and solar energy applications.
    A shadow band pyranomctcr is a conventional pyranometer to which a shadow band has been attached at such an angle that the shadow band blocks out the direct solar radiation throughout the course of a day. A state of the art shadow band pyranometer (available from The Eppley Laboratory Inc., Newport, RI) is shown in prior art Fig. 1. The shadow band 1 prevents direct solar radiation from reaching the pyranometer 2. If used in conjunction with a second pyranometer without a shadow band, direct radiation can be calculated by finding the difference between the two pyranometer measurements.
    The shadow band 1 is constructed of black anodized aluminum, weighs approximately twenty-four pounds, and uses a three inch wide circular or semi-circular band approximately twenty-five inches in diameter to shade the pyranometer 2. A platform 3 at the center supports the pyranometer 2 in a level position. The height and tilt settings of the shadow band 1 must be adjusted regularly (typically every two days) to compensate for the change in solar declination angle, due to the ongoing orbital and axial change of the Earth. Various setting screws and holes 4 are provided to make this adjustment.
    Another type of shadow pyranometer, shown in prior art Fig. 2, uses “shading balls” 5 rather than a band. Such an apparatus is the “Two Axis Sun Tracker” available from Kipp & Zonen USA Inc., Bohemia, NY. The Sun Tracker includes a motor drive 6 which can be programmed to track the movement of the sun from east to west during the course of the day. This is tracking on the azimuth axis. The motor drive can also be programmed to track on a second axis, the zenith axis. This second axis tracking automatically repositions the shading balls 5 to compensate for the changing elevation angle of the sun throughout the day. However, the apparatus is extremely complicated and costly.
    SUMMARY OF THE INVENTION
    It is therefore an object of the invention to provide an improved shadow band pyranometer.
    In accord with these objects, which will be discussed in detail below, a shadow band pyranometer according to the present invention includes a motor driven platform having a centrally located sun sensor. The platform is preferably arranged to be parallel to the ground on which the pyranometer rests. A generally vertical and arcuate shade arm extends upward from and substantially perpendicular to the platform at a distance away from the sensor. The arm traverses an arc of approximately 90 degrees and terminates approximately directly above the sensor. According to the presently preferred embodiment, a vertical strut supports the arm close to its free end. The arm is advantageously hollow and includes space for a fluid conduit and an electrical cable. In the presently preferred embodiment, an additional sun sensor is mounted on the top outer surface of the free end of the arm and is coupled to an electrical cable which runs through the hollow of the arm to appropriate circuitry. Further according to the presently preferred embodiment, a fluid dispensing nozzle is mounted on the bottom of the free end of the arm, approximately opposite to the second sun sensor. The nozzle is fluidly coupled to a fluid conduit (e.g., flexible tube) which extends through the hollow of the arm to a source of cleaning fluid.
    It will be appreciated that the shadow arm of the present invention does not need to be adjusted to compensate for the changing declination of the sun. Moreover, the shadow arm of the invention does not cast any shadow on the second sun sensor. Furthermore, the location of the cleaning nozzle allows the first sun sensor to be easily cleaned by injecting cleaning fluid through the nozzle down onto the first sun sensor.
    In an exemplary embodiment, a second pair of sensors are mounted via a second tracking motor to the platform and the second tracking motor tracks the zenith movement of the sun with respect to the second unshaded pair of sensors.
    According to a presently preferred embodiment, “bird whiskers” are mounted around the second sun sensor to deter birds from perching on the sensor.
    The shadow band assembly of the present invention may be retrofitted to existing equipment. As such, the shadow band may be supplied coupled to a platform defining a sun sensor mounting location and having a vertical strut further supporting the shadow band. The shadow band assembly may be supplied with or without sensors and with or without a fluid nozzle.
    Certain of the foregoing and related objects are readily attained according to the present invention by the provision of a shadow band assembly, comprising a platform having a sun sensor mounting location defined on said platform, and an arcuate shadow band having a first end and a second end, said first end mounted on said platform at a distance from said sun sensor mounting location, said shadow band extending generally vertically from and perpendicular to said platform with said second end of said shadow band lying above said sun sensor mounting location. Preferably, said arcuate shadow band extends through an arc of approximately 90 degrees, and most advantageously, 92.5 degrees from said first end to said second end.
    In a preferred embodiment, said shadow band defines a hollow cavity extending from said first end to said second end. Desirably, a fluid conduit extending through said hollow cavity and, most desirably, a fluid nozzle is coupled to said second end and in fluid communication with said fluid conduit. Most advantageously, an electrical cable extends through said hollow cavity and a sun sensor is mounted on said second end and coupled to said electrical cable.
    In a particularly preferred embodiment, a stmt stabilizer is provided extending from said platform at a point between said first end and said sun sensor mounting location to said band at a point between said first and second ends. The stmt is substantially perpendicular to said platform.
    Certain of the foregoing and related objects are also attained in a shadow band pyranometer embodying the present invention, comprising a platform, a first sun sensor mounted on said platform, and an arcuate shadow band having a first end and a second end, said first end mounted on said platform at a distance from said first sun sensor, said shadow band extending generally vertically from and perpendicular to said platform with said second end of said shadow band lying above said first sun sensor. Preferably, a motor drive is coupled to said platform, said motor drive being programmable for azimuth tracking of said platform. Desirably, an unshaded sensor assembly is coupled to said motor drive, said motor drive being programmable for zenith tracking of said unshaded sensor assembly.
    Other preferred features of the shadow band pyranometer are described above in relation to the shadow band assembly.
    Additional objects and advantages of the invention will become apparent to those skilled in the art upon reference to the detailed description taken in conjunction with the provided figures.
    BRIEF DESCRIPTION OF THE DRAWINGS
    FIG. 1 is a perspective view of a prior art shadow band pyranometer; FIG. 2 is a perspective view of a prior art sun tracker with a pyranometer shading ball arrangement; FIG. 3 is a perspective view of a shadow band pyranometer according to the invention; FIG. 4 is a broken perspective view of the free end of the shadow band of the invention; FIG. 5 is a side elevation view of a shadow band assembly of the invention with three sensors and a nozzle attached; FIG. 6 is a sectional view of the shadow band taken along line 6-6 of Fig. 5; FIG. 7 is an end elevation view of the components shown in Fig. 5; and FIG. 8 is a view similar to Fig. 4 showing optional “bird whiskers” surrounding the second sun sensor.
    DETAIFED DESCRIPTION
    Turning now to Fig. 3, a shadow band pyranometer 10 according to the present invention includes a motor driven platform 12 having a centrally located sun sensor 14. The platform 12 is mounted on a motor drive unit 13 and is preferably arranged to be parallel to the ground on which the pyranometer rests. A generally vertical and arcuate shade arm (shadow band) 16 extends upward from and substantially perpendicular to the platform 12 at a distance away from the sensor 14. The arm 16 traverses an arc of approximately 90 degrees (preferably 92.5 degrees) and terminates approximately directly above the sensor 14.
    According to the presently preferred embodiment, a vertical stabilizer strut 18 supports the arm 16 close to its free end 20 to provide added rigidity to the structure, especially in areas where there are high winds. As seen best in Fig. 6, the arm 16 is advantageously hollow and includes a generally upwardly-opening U-shaped channel defined by the base 17 and sidewalls 19 of the band 16. As shown in Fig. 3, the open U-shaped channel is normally covered by a band- or strip-like cover 21 affixed by screws 23 at both the top end 20 (Fig. 4) and base end 25 of the band 16 (Fig. 3).
    The channel has sufficient space for a fluid conduit 22 and an electrical cable 24. In the presently preferred embodiment, an additional sun sensor 26 is mounted on the top outer surface of the upper free end 20 of the arm 16 (see also Fig. 4) and is coupled to an electrical cable 24 which runs through the hollow of the arm to appropriate circuitry (not shown).
    Further according to the presently preferred embodiment, a fluid nozzle 28 is mounted on the bottom of the free end 20 of the arm 16, approximately opposite to the second sun sensor 26. The nozzle 28 is fluidly coupled to a fluid conduit 22 (e.g., flexible tube) which extends through the hollow or channel of the arm 16 to a source of cleaning fluid which, e.g., may be in liquid form (e.g., water preferably with an alcohol-based or an anti-freeze ingredient like those used in window washing fluids for cars) or gaseous form (e.g., compressed air).
    According to the illustrated embodiment of Fig. 3, additional sensors 30, 32, and 34 are provided. Sensor 30 is a conventional solid state 3-axis digital compass with heading and pitch and roll motion detection which is mounted on the same platform 12 as the sensor 14. Sensor 30 is used for determining real-time shadow band azimuthal position relative to true North, and shadow band horizontal level detection. If measured compass heading (0 - 360°) deviates from calculated solar azimuthal position, or if a shadow band mounting plate (12) level error is detected, as may occur due to ground shifting, a user alarm may be generated and/or a system software correction routine implemented to correct for shadow band heading and/or tilt mechanical offset. Sensors 32 and 34 are unshaded and mounted on a separately driven assembly 36 coupled to the motor drive unit 13. The drive unit 13 can be programmed to move the platform 12 through azimuth tracking and the sensor assembly 36 through zenith tracking, either separately or simultaneously.
    It will be appreciated that the shadow arm 16 of the present invention does not need to be adjusted to compensate for the changing declination of the sun. Moreover, the shadow arm of the invention does not cast any shadow on the second sun sensor 26 or on the sensors 32 and 34. Furthermore, the location of the fluid nozzle 28 allows the first sun sensor 14 to be easily cleaned by injecting cleaning fluid through the nozzle 28 down onto the first sun sensor 14.
    Referring now to Figs. 6-8, a shadow band assembly 100 according to the invention is shown together with some optional components. The shadow band assembly 100 is a subcombination of the components described in reference to the shadow band pyranometer 10 described above. The assembly can be retrofitted to existing equipment. Generally, the assembly includes the platform 12, the shadow arm 16, and the vertical stabilizer strut 18. The sensors 14, 26, 30, conduit 22, cable 24, and nozzle 28 are options that may be supplied with the assembly or supplied by the end user depending on the application. Those skilled in the art will appreciate that without the options, the platform 12 is preferably predrilled with mounting locations for the sensor 14 and one or mounting holes 38 for mounting the platform 12 on a drive unit.
    As an additional option, shown in Fig. 8, the free end 20 of the shadow arm 16 may be provided with conventional metal spikes or so-called “bird whiskers” 40 to deter birds from perching on the end of the arm.
    According to the presently preferred embodiment, the shadow arm 16 has a radius of approximately thirteen inches and extends through an arc of 92.5 degrees. An arc of 92.5 degrees is ideal for applications in the tropics where the sun can be directly overhead. The “extra” coverage is needed to block out the entire sun via the shadow band. As a practical matter, the band preferably covers an arc of 92.5 degrees + 5 degrees. The horizontal flat portion of top end 20 of band 16 upon which the nozzle 26 is mounted represents about 10 degrees of the 90 degree arc. The arm 16 has a generally rectangular cross section of about lxl to 1.25x1.25 inches. The platform 12 has an overall length of approximately twenty inches and a width of approximately five inches at its widest part. The part where the arm 16 is mounted may be as narrow as the arm itself. The parts where the sensors 14, 20 are mounted are preferably as wide as the diameters of the sensor lens optics.
    There have been described and illustrated herein several embodiments of a shadow band assembly and a shadow band pyranometer incorporating the same. While particular embodiments of the invention have been described, it is not intended that the invention be limited thereto, as it is intended that the invention be as broad in scope as the art will allow and that the specification be read likewise. It will therefore be appreciated by those skilled in the art that yet other modifications could be made to the provided invention without deviating from its spirit and scope as claimed.
    权利要求:
    Claims (22)
    [1]
    A shadow band assembly comprising: a platform that has a sun sensor mounting location defined on the platform; and an arcuate shadow band having a first end and a second end, the first end being mounted on the platform at a distance from the sun sensor mounting location, the shadow band generally extending vertically from and perpendicular to the platform with the second end of the shadow band is above the sun sensor mounting location.
    [2]
    The shadow band assembly of claim 1, wherein: the arcuate shadow band extends over an arc of about 90 degrees from the first end to the second end.
    [3]
    The shadow band assembly of claim 1, wherein: the arcuate shadow band extends over an arc of about 92.5 degrees from the first end to the second end.
    [4]
    The shadow band assembly of claim 1, wherein: the shadow band defines a cavity that extends from the first end to the second end.
    [5]
    The shadow band assembly of claim 4, further comprising: a fluid conduit extending through the cavity.
    [6]
    The shadow band assembly of claim 5, further comprising: a fluid nozzle that is coupled to the second end and is in fluid communication with the fluid conduit.
    [7]
    The shadow band assembly of claim 4, further comprising: an electrical cable extending through the cavity.
    [8]
    The shadow band assembly of claim 7, further comprising: a sun sensor mounted on the second end and coupled to the electrical cable.
    [9]
    The shadow band assembly of claim 1, further comprising: a stabilizer support beam extending from the platform at a point between the first end and the sun sensor mounting location to the band at a point between the first and second ends.
    [10]
    The shadow band assembly of claim 8, wherein: the support beam is substantially perpendicular to the platform.
    [11]
    A shadow band pyranometer comprising: a platform; a first sun sensor mounted on the platform; and an arcuate shadow band having a first end and a second end, the first end being mounted on the platform at a distance from the first sun sensor, the shadow band generally extending vertically from and perpendicular to the platform, the second end of the shadow band is above the first sun sensor.
    [12]
    The shadow band pyranometer of claim 11, wherein: the arcuate shadow band extends over an arc of about 90 degrees from the first end to the second end.
    [13]
    The shadow band pyranometer of claim 11, wherein: the arcuate shadow band extends over an arc of about 92.5 degrees from the first end to the second end.
    [14]
    The shadow band pyranometer of claim 11, wherein: the shadow band defines a cavity that extends from the first end to the second end.
    [15]
    The shadow band pyranometer of claim 14, further comprising: a fluid conduit extending through the cavity.
    [16]
    The shadow band pyranometer of claim 15, further comprising: a fluid nozzle coupled to the second end and in fluid communication with the fluid conduit.
    [17]
    The shadow band pyranometer of claim 13, further comprising: an electrical cable extending through the cavity.
    [18]
    The shadow band pyranometer of claim 17, further comprising: a second sun sensor mounted on the second end and coupled to the electrical cable.
    [19]
    The shadow band pyranometer of claim 11, further comprising: a vertical support beam extending from the platform at a point between the first end and the sun sensor mounting location to a point between the first and second ends.
    [20]
    The shadow band pyranometer of claim 19, wherein: the support beam is substantially perpendicular to the platform.
    [21]
    The shadow band pyranometer of claim 11, further comprising: a motor drive coupled to the platform, the motor drive being programmable for azimuth tracking of the platform.
    [22]
    The shadow band pyranometer of claim 21, further comprising: an unshaded sensor assembly coupled to the motor drive, wherein the motor drive can be programmed to monitor the unshaded sensor assembly.
    类似技术:
    公开号 | 公开日 | 专利标题
    NL2006209C2|2012-11-20|SHADOW BAND ASSEMBLY FOR USE WITH A PYRANOMETER AND A SHADOW BAND PYRANOMETER INCORPORATING SAME BACKGROUND OF THE INVENTION.
    US9243747B2|2016-01-26|Shade structure
    US9027545B2|2015-05-12|Solar collector positioning apparatus
    ES2791419T3|2020-11-04|Predictive piloting procedure for the orientation of a solar tracker
    US8592738B1|2013-11-26|Alignment device for use with a solar tracking photovoltaic array
    US4491388A|1985-01-01|Support carriage for a solar concentrator
    KR20100043049A|2010-04-27|Variable tilt tracker for photovoltaic arrays
    ES2785926T3|2020-10-08|Procedure for piloting the orientation of a solar tracker based on cartographic models
    ES2828349T3|2021-05-26|Procedure for piloting the orientation of a solar module with two photoactive faces
    US7887188B2|2011-02-15|Spherical heliostat
    US20110017276A1|2011-01-27|Sun tracker device
    KR101820129B1|2018-01-18|Precision digital map making system through the synthesis of geographic information and coordinate information
    CA2815909C|2015-12-29|Radiation compensated thermometer
    CN108267402B|2019-08-20|A kind of portable manual multi-angle observation device
    US20160370451A1|2016-12-22|Sunlight tracking sensor
    ES2738907B2|2020-12-30|PROCEDURE FOR CHARACTERIZING REFLECTIVE ELEMENTS FROM THE BEAMS OF LIGHT REFLECTED THROUGH THEM
    ES2423906A1|2013-09-25|System for positioning a reflective surface in relation to the sun, using a solar sensor and the reflected light
    JP4640091B2|2011-03-02|Antenna device
    FR2973985A1|2012-10-19|HELIOTROPID SWIVEL IRONING DEVICE HAVING A PHOTOVOLTAIC SURFACE
    FR2958732A3|2011-10-14|System for anchoring photovoltaic panels on cables stretched above covering surface in open grown area, has cables stretched by pair between posts and above covering surface by forming cable netting that supports photovoltaic panels
    KR101948702B1|2019-02-15|How to drive the sun tracking device
    Lukin et al.2006|Modified correlation tracker algorithm for tip-tilt correction system and project ANGARA on the Big Solar Vacuum Telescope
    ES2726474B2|2020-02-10|SYSTEM FOR MEASURING CONCENTRATED SOLAR RADIATION AND UNTRIPULATED AIR VEHICLE UNDERSTANDING
    SE1430143A1|2015-04-18|COUPLING FOR A SHADE STRUCTURE, SHADE STRUCTURE HAVING A COUPLED MAST; UMBRELLA
    CN113340281A|2021-09-03|Method for passively measuring earth orbit eccentricity by using microwave radiometer
    同族专利:
    公开号 | 公开日
    US9329256B2|2016-05-03|
    US20110198480A1|2011-08-18|
    US8648286B2|2014-02-11|
    US20130277532A1|2013-10-24|
    US8481905B2|2013-07-09|
    US20140034805A1|2014-02-06|
    NL2006209C2|2012-11-20|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US8481905B2|2010-02-17|2013-07-09|Accuflux Inc.|Shadow band assembly for use with a pyranometer and a shadow band pyranometer incorporating same|US4107521A|1976-10-14|1978-08-15|Gordon Robert Winders|Solar sensor and tracker apparatus|
    US4481562A|1983-03-28|1984-11-06|T & L Electronics, Inc.|Solar power station|
    US4672191A|1984-06-19|1987-06-09|Dennis Cofield|Shadow solar tracking device and system|
    SU1578503A1|1988-02-04|1990-07-15|Пятигорский научно-исследовательский институт курортологии и физиотерапии|Ultraviolet photometric installation|
    IT1239806B|1990-02-28|1993-11-15|Consiglio Nazionale Ricerche|An automatic-band device for measuring diffused solar radiation|
    JPH1183622A|1997-09-12|1999-03-26|Toshiba Lighting & Technol Corp|Sunshine sensor|
    US6849842B2|2002-06-29|2005-02-01|Rwe Schott Solar, Inc.|Rotating shadowband pyranometer|
    US20070033828A1|2005-08-09|2007-02-15|Solar Roast Coffee Llc|Method and apparatus for roasting coffee beans by means of concentrated solar thermal energy|
    US20080001059A1|2006-06-29|2008-01-03|Chin-Wen Wang|Solar Energy Current Collection Mechanism|
    US8469023B2|2006-09-27|2013-06-25|Airlight Energy Ip Sa|Radiation collector|
    US20090314280A1|2008-06-24|2009-12-24|Rajarshi Banerjee| Apparatus and A Method for Solar Tracking and Concentration af Incident Solar Radiation for Power Generation|
    US8481905B2|2010-02-17|2013-07-09|Accuflux Inc.|Shadow band assembly for use with a pyranometer and a shadow band pyranometer incorporating same|
    US8981272B2|2011-08-04|2015-03-17|Masdar Institute Of Science And Technology|Radiometers having an opaque, elongated member rotationally obstructing a light path to a light detector for measuring circumsolar profiles|US9686122B2|2010-05-10|2017-06-20|Locus Energy, Inc.|Methods for orientation and tilt identification of photovoltaic systems and solar irradiance sensors|
    US20140293858A1|2011-11-15|2014-10-02|Kyocera Corporation|Node detection in a cellular communication network|
    US10004022B2|2011-11-15|2018-06-19|Kyocera Corporation|Handover signaling using an MBSFN channel in a cellular communication system|
    US9655221B2|2013-08-19|2017-05-16|Eagle Harbor Technologies, Inc.|High frequency, repetitive, compact toroid-generation for radiation production|
    EP3069445A4|2013-11-14|2017-12-06|Eagle Harbor Technologies, Inc.|High voltage nanosecond pulser|
    US10020800B2|2013-11-14|2018-07-10|Eagle Harbor Technologies, Inc.|High voltage nanosecond pulser with variable pulse width and pulse repetition frequency|
    WO2015131199A1|2014-02-28|2015-09-03|Eagle Harbor Technologies, Inc.|Galvanically isolated output variable pulse generator disclosure|
    US10978955B2|2014-02-28|2021-04-13|Eagle Harbor Technologies, Inc.|Nanosecond pulser bias compensation|
    US10483089B2|2014-02-28|2019-11-19|Eagle Harbor Technologies, Inc.|High voltage resistive output stage circuit|
    ES2562720B2|2014-09-05|2016-08-04|Universidad De Burgos|Diffuse radiation measuring device and its use procedure|
    DE102014019588A1|2014-12-30|2016-06-30|erfis GmbH|CSP tracking|
    NL2014385B1|2015-03-03|2016-10-14|Hukseflux Holding B V|Thermal sensor with forced airflow.|
    USD847668S1|2015-09-30|2019-05-07|Eko Instruments Co., Ltd.|Pyranometer|
    EP3580841A4|2017-02-07|2020-12-16|Eagle Harbor Technologies, Inc.|Transformer resonant converter|
    ES2656737A1|2017-07-04|2018-02-28|Centro De Investigaciones Energéticas, Medioambientales Y Tecnológicas |AUTONOMOUS SYSTEM TO REGISTER SOLAR IRRADIANCE |
    US10892140B2|2018-07-27|2021-01-12|Eagle Harbor Technologies, Inc.|Nanosecond pulser bias compensation|
    US11222767B2|2018-07-27|2022-01-11|Eagle Harbor Technologies, Inc.|Nanosecond pulser bias compensation|
    US10903047B2|2018-07-27|2021-01-26|Eagle Harbor Technologies, Inc.|Precise plasma control system|
    KR20210041608A|2018-08-10|2021-04-15|이글 하버 테크놀로지스, 인코포레이티드|Plasma sheath control for RF plasma reactor|
    US10607814B2|2018-08-10|2020-03-31|Eagle Harbor Technologies, Inc.|High voltage switch with isolated power|
    US11004660B2|2018-11-30|2021-05-11|Eagle Harbor Technologies, Inc.|Variable output impedance RF generator|
    US10796887B2|2019-01-08|2020-10-06|Eagle Harbor Technologies, Inc.|Efficient nanosecond pulser with source and sink capability for plasma control applications|
    US11175371B2|2019-10-14|2021-11-16|Imam Abdulrahman Bin Faisal University|Rotatable shadowband|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    US70691910|2010-02-17|
    US12/706,919|US8481905B2|2010-02-17|2010-02-17|Shadow band assembly for use with a pyranometer and a shadow band pyranometer incorporating same|
    [返回顶部]