SOLYS2 Pointeur Solaire

SOLYS2 Pointeur Solaire

Le SOLYS2 est un nouveau modèle de pointeur solaire Kipp & Zonen. Il bénéficie des niveaux de performance et de la fiabilité du « Baseline Surface Radiation Network » (BSRN). L’installation et le fonctionnement du SOLYS sont beaucoup plus simples que ceux de n’importe quel autre pointeur disponible sur le marché.

Grâce à la plaque de montage optionnelle qui est située sur la partie supérieure et à la monture pour l’ombrage, le SOLYS2 peut être configuré en tant que station de surveillance solaire complète pouvant totaliser trois radiomètres ventilés de Kipp & Zonen.

Le récepteur GPS intégré présente une particularité: il permet de configurer automatiquement les données de positionnement et les valeurs temporelles dès son installation. C’est le seul pointeur solaire entièrement automatique qui ne nécessite pas d’ordinateur ni de logiciel pour sa mise en service. Le nivellement est facilement réglé grâce au niveau à bulle intégré, installé en haut.

Le boîtier en fonte d’aluminium, robuste et distinctif, est doté d’un support à trois branches avec des pieds niveleurs, de verrous à sangles et d’un réglage en azimut. Une plaque latérale, prévoyant un réglage zénithal et des supports pour un pyrhéliomètre CH 1 de Kipp & Zonen, est incluse.

Le SOLYS2 ne subit aucune dérive de l’horloge interne étant donné que l’heure est régulièrement mise à jour via le récepteur GPS. Si le pointeur est correctement mis à niveau et ajusté, il continuera à pointer efficacement. Une sonde solaire optionnelle est disponible pour un pointage actif.

Le SOLYS2 peut fonctionner avec du courant alternatif ou continu (AC ou 24 VDC) ; les deux entrées sont disponibles. La gamme de températures de service s’échelonnant de - 20 °C à + 50 °C peut atteindre -40 °C grâce au climatiseur (AC uniquement) qui est inclus.

Le SOLYS2 donne une impulsion au marché des pointeurs solaires grâce à son design distinctif, ses caractéristiques innovatrices, sa performance, sa qualité supérieure et sa facilité d’utilisation sans précédent- tout ça à un prix incroyablement abordable.

La conception du pointeur solaire SOLYS2 se base sur un logiciel "open source".

Specifications

Downloads

Brochures

• Brochure - Sun Trackers - Russian
• Brochure - Sun Trackers - English
• Brochure - Sun Trackers - French
• Brochure - Solar Monitoring Stations
• Solar Energy Guide - Russian
• Solar Energy Guide - English
• Brochure of RaZON+ ALL-IN-ONE system

Newsletters

• Newsletter 08 - April 2009
• Newsletter 21 - July 2012
• Newsletter 20 - April 2012
• Newsletter 40 - April 2017
• Newsletter 39 - January 2017
• Newsletter 42 - October 2017
• Newsletter Special - Solar Radiation Measurement in Meteorology
• Newsletter 27 - January 2014
• Newsletter Special - Solar Monitoring Stations
• Newsletter 07 - January 2009
• Newsletter 02 - October 2007
• Newsletter 41 - July 2017
• Newsletter 31 - January 2015
• Newsletter 30 - October 2014
• Newsletter 33 - July 2015
• Newsletter 45 - July 2018
• Newsletter 44 - April 2018
• Newsletter 43 - January 2018
• Newsletter 38 - October 2016
• Newsletter 37 - July 2016
• Newsletter 36 - April 2016
• Newsletter 35 - January 2016
• Newsletter 34 - October 2015
• Newsletter 10 - October 2009

Manuals

• Manual - Sun Tracker - SOLYS
• Manual - Sun Tracker - SOLYS 2 - Spanish

Declarations

• Declaration of Conformity SOLYS2 Sun Tracker

STEP files

• SOLYS 2 + tripod- universal CAD drawing (STEP)
• SOLYS 2 + tripod + shading assembly - universal CAD drawing (STEP)

Software

• SOLYS Labview
• SOLYS Monitor software

Technical info

• Scientific Solar Monitoring Station - BSRN requirements

FAQ

• Why is the altitude limited to 2000 m?

  • The 2AP BD altitude specification (2000m) is limited by the CE and CSA (Canadian Standards Association) recommendation for main power board design. CSA recommends that AC boards have certain spacings between the board tracings for various elevation (pressures). As the pressure decreases there is more probability for arcing when the wires are close. Unfortunately there is not enough room internally, in the 2AP BD, to increase the size of this board (to make the spacings bigger).
    
    The best solution is to sell/quote a 2AP Gear Drive with 24VDC, as this would eliminate the altitude restrictions associated with high voltage AC.

    Is your question still unanswered? Contact Support
• Is there a way to fix a tracker via remote PC?

  • You can try the following:
    If you send the command “CO”, the 2AP will cold start. This means ignore all present settings and start without using any previous (possibly wrong) settings.
    
    If you then start the sun tracker program, it will start up with the message “”recovering from cold start””
    
    Then longitude and latitude etc. will be recovered from the .ini file, the time and date of course cannot be stored and has to be entered again. If no further error message is given, the 2AP is most likely operational again.

    This could solve the problem, if not please contact us and we will discuss further options.

    Is your question still unanswered? Contact Support
• Is compensation for pressure variations needed?

  • The air pressure that is required should be an average value for the site the instrument is operated. It does not need to be updated over time. The meaning of it is to correct for (a small) optical shift due to atmospheric pressure. A normal value depends of course on the heath of operation. A value of 1000 mBar is typical for sea level.
    

    Is your question still unanswered? Contact Support
• Is there a compensation for temperature drift?

  • The controller board has a temperature compensated oscillator module for the microprocessor. While power is applied the firmware keeps accurate time and updates the real time clock (which is not very accurate) every 8 hours.
    
    We enter a room temperature correction, which compensates for initial calibration of the oscillator module. The oscillator module can drift up to ±11 ppm over the 0 °C to 70 °C temperature range. The module can also drift up to ±2 ppm in a year.
    
    The temperature drift is different for each oscillator so cannot be compensated for in firmware.
    

    Is your question still unanswered? Contact Support
• What is the range of the temperature?

  • The temperature range for the 2AP tracker is:
    
    Standard temp range: 0 - 50 degrees Celsius
    With cold cover: -20 - 50 degrees Celsius
    With cold cover and heater -50 - 50 Degrees Celsius
    
    Normally the heater is built in, in the factory. However we can supply you with a kit plus instructions to do it yourself.
    

    Is your question still unanswered? Contact Support
• What is the accuracy of the 2AP tracker in combination with a sun sensor?

  • The 2AP has the following errors:

    • Time
    • Setup (leveling)
    • Calculation (algorithm according to Michailsky error max. is 0.025 degree)
    • Mechanical (BD = 0.09 and GD =0.045 degree max.)

    The first 2 are user controlled and the last 2 are fixed.
    
    Assuming that the leveling is done optimal the only error remaining that can be corrected is time. If we assume that the clock is reset every 1,000,000 seconds (11.5 days) there will be an expected error of 5 seconds. If we assume that the sun rotates 360 degrees in 24 hour then RMS 0.72 * 5 seconds = an actual time error of 3.6 seconds. For a period of 11.5 days the total time error contribution is 0.015 degrees (the diameter of the solar disk is 0.25 degrees). Per year this would result in 0.5 degree.
    
    If this time correction and the check on leveling are done on a regular interval there is no need for a sun sensor. If however this interval can or will not made, the sun sensor will correct for both (leveling and time).
    
    The sun sensor is normally used for first checking the tilt error. Assuming that there is sunshine for at least 2 full days over the full day. This information is stored in an internal log file and used to correct (in combination with PC). Over this period the user has to correct time. (if more than 2 weeks). After this initial run and correction for tilt, the sun sensor is used for time correction. This means that optimal accuracy is maintained without user (time) correction. This means that the 2AP is within specs the whole year without intervention.
    
    Please note that the sensors used on the 2AP also need maintenance on a regular base (drying cartridge and dirt on domes).
    
    Better than giving an error in percentage we would like to show the benefit of not having to correct to clock. The 2AP error in degrees can be calculated as percentage of 360 degrees, but the error in sensor reading depends on the type of sensor.

    Is your question still unanswered? Contact Support
• Why does the COM port of my Pentium not address the 2AP like my old 4.86?

  • The CMD and sun tracker software will work on COM1 or COM2 only, specified as the first parameter after the program name in the command line. Make sure the 2AP is connected to one of these two ports. Problems can also occur if another program has taken over the COM port and will not give it up. Also, some Compaq computers have non-standard COM ports, which the CMD and sun tracker programs cannot communicate through. The solution for this problem could be found in a simple add-on card with a standard extra serial port, if it can be set as COM 1 or 2.

    Is your question still unanswered? Contact Support
• Can the tracker be connected to a PC at 30 m distance?

  • To connect the 2AP with a PC for communication, a 3-wire cable is used (or 2 wires plus shield) as described on page 5 of the manual.
    Advised is a shielded cable, where the shield can be the ground connection.

    • On the 2AP side the wires are connected to the communication board.
    • On the PC side a 9 or 25 pin Sub D connector is used for the serial port.

    This cable length can be 30 meter. We can supply this cable, but it can be bought "around the corner".
    
    The communication software is included with the 2AP.
    

    Is your question still unanswered? Contact Support
• Does the 2AP work autonomously?

  • The 2AP works fully autonomously, after the setup. Setup is done in combination with a PC. (Entering Longitude, Latitude etc.) Indeed a data logger is needed to collect data from the sensors, but this logger has no (hardware) connection with the 2AP.

    Is your question still unanswered? Contact Support
• What power supply is needed when heaters are used?

  • The power use of the 2AP itself is about 1.5 A to 2 Amps. (Internal fuse is 3 Amps slow)
    
    Part number for the 24V heater kit is: 12136346.
    This kit contains two 50 Watt heaters.
    So the current for these heaters is 4.2 A (at 24V), fuse is 5 A slow blow.
    
    If we add up the total power we have:
    5A (heaters) + 3.15 (2AP)= 8.15 A
    
    Normal conditions:
    4.2 A (heaters) + 1.25A (2AP) = 5.5 A normal
    
    Therefore a 5 Amp power supply will not survive very long.
    We recommend to take a power supply that can deliver the 8.15 A. (when heaters are used)
    

    Is your question still unanswered? Contact Support
• How much power is needed for the 2AP?

  • The power use of the 2AP itself is about 1.5 A to 2 Amps. (internal fuse is 3 Amps slow)

    Is your question still unanswered? Contact Support
• Is it possible to mount 4 pyreliometers plus an extra sun sensor?

  • Yes. Normally 4 of these side-mounted sensors is the maximum, however we are able to make an extension on one pyrheliometer mount for the extra sun-sensor.

    Is your question still unanswered? Contact Support

Accessories

Relevant news items

8/5/2014 Important: Packing Instructions SOLYS 2 Sun Tracker

8/13/2012 PAGASA visits Delft to learn more about the SOLYS 2 sun tracker

1/11/2019 New weatherproof data and power hub for smart instruments

1/19/2015 SOLYS 2 Sun Tracker Instruction Video

4/5/2011 Measure tilted global and diffuse solar radiation

12/4/2008 New accessory for the SOLYS 2 sun tracker

12/20/2016 Infographic: the best sun trackers are Kipp & Zonen

8/18/2015 SOLYS 2 and SOLYS Gear Drive Communication with LabVIEW™

4/13/2015 The new SOLYS Gear Drive Sun Tracker – highest load, widest temperature range, best performance

10/18/2013 Reporting back from the NREL Pyrheliometer Comparison 2013

1/7/2014 What is a Solar Monitoring Station?

Application examples

2/17/2009 Sun Shines on JMSB building

2/20/2009 Solys 2 Sun Tracker in the Pyrenees

7/25/2014 BSRN

11/4/2014 Solar Radiation Station Monitors Pollutants in Taiwan

3/29/2014 Solar Monitoring Station for Moscow Environmental Protection Department

4/25/2018 China's second PV Pioneer Project

11/27/2017 Inside the Ruicheng PV Pioneer Project

7/31/2015 Monitoring Canada’s First Concentrating Solar Thermal Power Plant

3/28/2014 Solar Energy Challenges in the Gobi Desert

12/3/2013 Setting Up a SOLYS 2 in Brasov, Romania

9/19/2013 Solar Monitoring in Project PrédiSol

7/23/2013 Four SOLYS 2 sun trackers at ACCIONA’s twin CSP plants

8/16/2012 Solar Resource Assessments in South Africa for Concentrated Solar Power Developers

8/16/2012 SOLYS 2 Sun Tracker at CNIM’s Solar Concentrator Module

8/16/2012 The Kanzelhöhe Observatory in Austria

8/14/2012 Kogan Creek Solar Boost Project

8/13/2012 Chile, High Potential but Little Solar Data

7/28/2008 Solar Farms

7/28/2008 PV performance

6/2/2015 Encouraging Solar Energy in South Africa with SAURAN

6/1/2015 Tackling Solar Energy’s Dust Problem

6/1/2015 CMP 11 in Automatic Weather Stations in Mexico

12/3/2013 Energy Yield Studies and Optimisation of Solar Farms

5/28/2015 A Solar Atlas for Saudi Arabia

11/28/2008 Improving Photovoltaic Efficiency

1/15/2018 Measurement of UV radiation added to Antarctic site of the LES solar measurement network