Arab Region Progress in Sustainable Energy Challenges and Opportunities
07 suri sma_amman_final
1. Solar Atlas for the Mediterranean
- User Interface
- PV simulator
Workshop Under the Patronage of His Excellency Alaa Batayneh,
Minister of Energy and Mineral Resources of Jordan
Date: 4 Dec 2012
Venue: Sheraton Amman Al Nabil Hotel, Amman, Jordan
Marcel Suri
GeoModel Solar
marcel.suri@geomodel.eu
http://www.solar-med-atlas.org/
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 1
2. Solar Atlas for the Mediterranean: User Interface
• Standardized access to the data and tools
• Data download
• Easy geographic navigation
• Easy to understand also for non-experts
• Based on previous experience and other web systems:
PVGIS, SolarGIS, SWERA, national and other Atlases
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 2
3. Solar-Med-Atlas – about
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 3
4. Solar Med Atlas – how it works
solar radiation air temperature terrain
SoDa/SOLEMI SolarGIS SolarGIS
distributed
databases
REN212
Reegle
Word Bank
web services Solar data PV electricity Hot water Socio-economic info
web applications User access through web interface
(Language versions: EN, FR, AR)
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 4
5. Solar-Med-Atlas – entry point
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 5
6. Map window – search location
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 6
7. Global Horizontal Irradiation Map
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 7
8. Direct Normal Irradiation map
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 8
9. Solar and temperature data
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 9
10. Solar data
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 10
11. Solar data
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 11
12. Solar data
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 12
13. Solar data
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 13
14. Solar data
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 14
15. Simulation of a Photovoltaic (PV) system
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 15
16. Simulation of a Photovoltaic (PV) system – French version
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 16
17. Simulation of a Photovoltaic (PV) system
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 17
18. Simulation of a Photovoltaic (PV) system
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 18
19. PV simulator
solar radiation air temperature terrain
PV
configuration
PV simulation models
PV models
Web interface
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 19
20. PV simulator - input data and features
Functionality:
• PV technologies:
• Amorphous and crystalline silicon
• CIS/CIGS
• Fixed mounting
• Free-standing or roof-mounted
Input data - monthly averaged hourly values (12x24 values):
• Global irradiation
• Diffuse irradiation
• Air Temperature
+ Terrain elevation (and horizon)
Ouput data (12 monthly + 1 annual values)
• Solar electricity
• Performance Ratio
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 20
21. PV simulator - models
• Klucher’s model for calculating Global Tilted (in-plane) Irradiation
• Module temperature calculation for PV panels
• Ruiz-Martinez model for angular reflectivity
• King’s updated model for PV power conversion in DC modules
PV model is based on averaged hourly values
=> simplified approach, with higher uncertainty
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 21
22. PV simulation chain PV performance in Standard Test Conditions: 2308 kWh/kWp
example Cairo
LOSSES
Air temperature
Global irradiation
(module surface)
-0.0%
Shading by terrain Irradiation
received by
-2.6%
Angular reflectivity PV modules
Dirt, dust and soiling -2.5%
Losses in the conversion of -11.7%
irradiance into DC in modules
DC power
Inter-row shading losses in PV modules -1.2%
Mismatch and cable losses -2.0%
Losses in the inverters -2.5%
Conversion
to AC, transformation
Losses in transformers and AC and feed to 22 kV -1.5%
Technical availability -1.0%
PV annual output: 1782 kWh/kWp, losses 22.8% (Performance ratio=77.2%)
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 22
23. PV simulation chain PV performance in Standard Test Conditions: 2308 kWh/kWp
example Cairo
LOSSES UNCERTAINTY
Air temperature
Global irradiation ±5%
(module surface)
-0.0% ±0.0%
Shading by terrain Irradiation
received by
-2.6% ±0.5%
Angular reflectivity PV modules
Dirt, dust and soiling -3.0% ±2.0%
Losses in the conversion of -11.7% ±3.0%
irradiance into DC in modules
DC power
Inter-row shading losses in PV modules -1.2% ±0.7%
Mismatch and cable losses -2.0% ±0.8%
Losses in the inverters -2.5% ±0.6%
Conversion
to AC, transformation
Transformers and AC losses and feed to 22 kV -1.5% ±0.5%
Technical availability -1.0% ±0.7%
PV annual output: 1782 kWh/kWp, losses 22.8% (PR=77.2%), uncertainty: 6.5%
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 23
24. PV simulator – typical settings
Size of a PV system in kWp
Type of installation (roof integrated/free standing)
Type of modules (cSi, aSi, CIS/CIGS)
Inverter Euro efficiency (typical 91 to 97%)
System losses (typical 5 to 12 %)
Azimuth (orientation of PV modules) in degrees
Slope/tilt of Pvmodules in degrees
Uncertainty of annual estimate ±7% to ±9%
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 24
25. PV simulator – typical system losses
Roof-top PV system Free standing PV system
Surface polution of modules 2.5 to 5% 2.5 to 4%
Inter-row shading - 0.5 to 2%
Mismatch and cable losses 1 to 3% 1 to 2%
Transformer and AC losses - 1 to 2%
Losses due to limited availability 1.5 to 3% 1 to 2%
Summary of system losses 5 to 11% 6 to 12%
Typical inverter efficiency 91 to 95% 93 to 97%
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 25
26. Simulation of a hot-water system
More in the presentation
by Armines/Transvalor
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 26
27. Socio-economic data
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 27
28. Thank you for your attention!
Marcel Suri
GeoModel Solar
http://www.solar-med-atlas.org/
Solar Atlas for the Mediterranean, Final Workshop, Amman, Jordan, 4 Dec 2012, www.solar-med-atlas.org 28