#Solar mooc problem set 1 alternate exercise 1 solution.
053013 pv system site assessment (1)
1. PV System Site Assessment
#SolarMOOC
SolPowerPeople, Inc.
May 30, 2013
w/ Sarah Raymer
AKA Ms. MOOC
NABCEP Certified PV installation Professional
Certificate #: 042013-107
2. Solar Resource:
● What is the solar energy production
potential for the location?
● How does the specific site effect the
installation - production and installation
wise?
● Customer assessment: What does the
customer expect and want?
Solar Site Assessment
objectives:
3. ● Solar Resource:
○ Latitude
○ solar sun path charts
○ Altitude and Azimuth - sun and array positioning
● Site Specific Practical:
○ Shading - Solar Pathfinder or Suneye
○ Mounting methods and locations
○ Component locations and wire runs
○ Electrical service - new construction or retrofit
○ Roof or soil conditions
Solar Resource and Site
Analysis
5. Solar resource
Does the sun shine?
● What does data say for location?
○ Latitude, solar sun path charts
■ Azimuth - position relative to South
■ Altitude - how high in the sky
● What is the weather/air like?
○ wind patterns
○ rainfall
○ pollution
10. Austin, Texas:
84 days rainfall average
229 sunny days/year
30º Latitude
489 ft. Altitude
Frankfurt, Germany:
111 days rainfall average
1,586 hours sun/year
51ºN Latitude
364 Ft. Altitude
Latitude
Germany:
2011: 69,684
2012: 102,024
USA:
2011: 4,383
2012: 7,665
MWp Peak Power Capacity (installed, not resource)
11. Kenya:
13 - 71 days rainfall
3,579 Hours/year
0º Latitude
6000 Ft. Altitude
Sydney:
155 days rainfall
235 sunny days/year
39ºS Latitude
128 Ft. Altitude
Kenya:
Australia:
2011: 1,298
2012: 2,291
South Africa:
2011: 41
2012: NA
MWp Peak Power Capacity (installed, not resource)
Latitude
18. Solar and Wind Energy Resource Assessment:
http://maps.nrel.gov/swera
Other examples:
Indonesia is practically at the equator, yet the
solar resource is fairly poor because it rains
there SOO much.
20. Azimuth and altitude of the
sun and array dramatically
affect the ability to maximize
a locations natural solar
resource.
graphic from: astronomy21st.blogspot.com
** Note: mostly
using Northern
hemisphere for
examples.
22. A sun path chart is a graphic representation of the solar
window that gives precise data regarding the exact
location of the sun at all times of the year.
34. S
0º
E
90º
W
-90º
N
-/+ 180º
What is the azimuth angle of each array?
Which one will produce the most in the morning?
Which one will produce the most in the evening?
?
?
Array azimuth
36. S
0º
E
W
N
-/+ 180º
Which one will produce the most in the morning?
Which one will produce the most in the evening?
40ºW
or -40
50ºE
37. S
0º
E
W
N
-/+ 180º
Which one will produce the most in the morning?
Which one will produce the most in the evening?
40ºW
or -40
50ºE
Will do best in the AM, when Sun is in the Eastern sky
Will do best in the PM, when Sun is in the Western sky
Will most often do best of all
38. In an environment that experiences rain in
the morning fairly regularly, but that clears
up around noon with clear skies on into the
evening, what would be the ideal direction
(azimuth) relative to South for the array to
face?
39. In an environment that experiences rain in
the morning fairly regularly, but that clears
up around noon with clear skies on into the
evening, what would be the ideal direction
(azimuth) relative to South for the array to
face?
The sun rises in the E, and sets in the W.
The array should face towards an azimuth
that is slightly west of south.
This will allow for optimization of afternoon
sun, after the skies clear.
49. The angle of incidence is essentially the angle that
defines how far you are away from a direct line from
the sun.
The larger the incidence angle, the less solar
radiation/photons will strike the surface.
solar altitude angle
relative to roof
51. Incidence angle: It is best to face the
solar rays for most direct absorption
of photons.
Hence- arrays facing South, (Northern
Hemisphere), TILTED at latitude.
52. blog.civitasenergy.com
Module should be tilted so that the Incidence angle is at 90º
to the sun's rays (set at tilt angle equal to latitude).
If possible:
Winter- tilt up 15º (Latitude + 15) because of lower solar
altitude angle
Summer- tilt back 15º (Latitude - 15) because of greater
solar altitude angle
53. Incidence angle: It is best to face the solar rays
for most direct absorption of photons.
Hence- arrays facing South, (Northern
Hemisphere), TILTED at latitude.
56. Site specific details
○ Shading
○ Mounting methods and
locations
○ Roof or soil conditions
○ Component locations and
wire runs
○ Electrical service - new
construction or retrofit
62. There are many smartphone
apps for shading analysis as
well:
Sun Surveyor (android)
SunSeeker (iPhone)
(each app is about about $2 - $5)
SolarPro article:
iPhone Apps for Solar Geeks
64. Magnetic Declination
180 - (MD) = True S
MAGNETIC Declination is the
angle between the direction on
the compass and True South (or
North.
Compass needles is affected by
magnetic core of the Earth.
*GPS devices preconfigured!
*Change every few years,
slightly.
West Coast:
+15º
180º - (15º) = 165º
East Coast:
-15º
180º - (-15º) = 195º
65. West Coast-
western declination:
+15º
180º - (15º) = 165º
Compass tell you S is W of what it
really is.
East Coast-
eastern declination:
-15º
180º - (-15º) = 195º
Compass tell you S is E of what it
really is.
66. Mounting methods and locations:
● Consider latitude
● Consider tilt
● Consider shading
But also:
Electrical service, system integration,
placement of components
Options:
roof mount, ground mount, pole mount
69. What is their vision and ultimate desire?
● What is their motivation (selling points)
● Determine energy usage and
expected/desired offset (size/$)
● Do they want a roof or a ground mount
system?
● What are their preferences visually?
Customer Assessment:
70. Energy usage and offset
Energy Audit:
http://youtu.be/YolBP0-vkBU
Recommend reductions in use ( highest value
for customer / of system)
Consider adding EA to your skills set as an
installer/team or partnering with an AE
company (value to installer)
71. Location and Visuals:
Will primarily depend on availability of
shade-free area, but specific preferences
could play into decision.
● Shading
● Roof condition
● Safety and code
● Costs (and rebates)
● Architectural appearance, aesthetics and
color
72. Indiegogo Campaign:
Online Solar School Development
http://www.indiegogo.com/projects/online-
solar-school-development?c=home
http://www.indiegogo.com/projects/online-
solar-school-development?c=gallery