Title: Photovoltaic Solar Systems
1Photovoltaic Solar Systems
- Dr. William J. Makofske
- August 2004
2What is a solar cell?
- Solid state device that converts incident solar
energy directly into electrical energy - Efficiencies from a few percent up to 20-30
- No moving parts
- No noise
- Lifetimes of 20-30 years or more
3Cross Section of Solar Cell
4How Does It Work?
- The junction of dissimilar materials (n and p
type silicon) creates a voltage - Energy from sunlight knocks out electrons,
creating a electron and a hole in the junction - Connecting both sides to an external circuit
causes current to flow - In essence, sunlight on a solar cell creates a
small battery with voltages typically 0.5 v. DC
5Combining Solar Cells
- Solar cells can be electrically connected in
series (voltages add) or in parallel (currents
add) to give any desired voltage and current (or
power) output since P I x V - Photovoltaic cells are typically sold in modules
(or panels) of 12 volts with power outputs of 50
to 100 watts. These are then combined into
arrays to give the desired power or watts.
6Cells, Modules, Arrays
7Rest of System Components
- While a major component and cost of a PV system
is the array, several other components are
typically needed. These include - The inverter DC to AC electricity
- DC and AC safety switches
- Batteries (optional depending on design)
- Monitor (optional but a good idea)
- Ordinary electrical meters work as net meters
8The Photovoltaic Array with its other electrical
components
9PV was developed for the space program in the
1960s
10PV Price and Quantity Manufactured Relationship
11The PV Market
- Solar Calculators
- REMOTE POWER
- Lighting
- Buoys
- Communications
- Signs
- Water Pumping
- Mountain Cabins
12Photovoltaic Array for Lighting
13Telecommunications Tower
14Remote Water Pumping in Utah
15Recreation Vehicle Outfitted with Solar Panels
16Solar Lanterns for Landscaping
17A Solar Driven Band
18The Market Expands
- As prices dropped, PV began to be used for
stand-alone home power. If you didnt have an
existing electrical line close to your property,
it was cheaper to have a PV system (including
batteries and a backup generator) than to connect
to the grid. As technology advanced,
grid-connected PV with net metering became
possible.
19NET METERING
- In net metering, when the PV system produces
excess electricity, it is sent to the grid
system, turning the meter backwards. If you are
using more power than is being produced, or it is
at night, the electricity is received from the
grid system and the meter turns forwards.
Depending on PV size and electrical consumption,
you may produce more or less than you actually
use. Individual houses may become power producers.
20Net Metering can be done with or without a
battery backup
21BATTERIES
- Batteries can be used to provide long-term or
short-term electrical supply in case of grid
failure. Many grid-connected houses choose to
have a small electrical battery system to provide
loads with power for half a day in case of
outage. Larger number of batteries are typically
used for remote grid-independent systems.
22Battery Sizing I
- If your load is 10 kw-hr per day, and you want to
battery to provide 2.5 days of storage, then it
needs to store 25 kw-hr of extractable electrical
energy. Since deep cycle batteries can be
discharged up to 80 of capacity without harm,
you need a battery with a storage of 25/0.8
31.25 kw-hr. A typical battery at 12 volts and
200 amp-hour capacity stores 2.4 kw-hr of
electrical energy.
23Battery Sizing II
- The relationship between energy in kw-hr and
battery capacity is - E(kw-hr) capacity(amp-hr) x voltage/1000
- E 200 amp-hr x 12 volts/1000 2.4 kw-hr
- So for 31.25 kw-hr of storage we need
- 31.25 kw-hr/2.4 kw-hr/battery 13 batteries
- If we are happy with one half day, we need only 2
or 3 batteries
242 KW PV on Roof with battery storage. Solar hot
water collectors and tank
25PV On Homes
- PV can be added to existing roofs. While south
tilted exposure is best, flat roofs do very well.
Even east or west facing roofs that do not have
steep slopes can work fairly well if you are
doing net metering since the summer sun is so
much higher and more intense than the winter sun.
The exact performance of any PV system in any
orientation is easily predictable.
26Photovoltaic Array on Roof and as an Overhang
27½ KW PV System Installed along Roof Ridge
28California Home PV Installation
29PV on House
302.4 KW System under Installation in New Hampshire
31PV Installed at Roofline on Building at Frost
Valley, NY
32PV Panels on Tile Roofs in Arizona
33PV on Roof in California
34Totally Inadequate Roof?
- If it is impossible or you dont want to put a PV
system on your existing roof, it is possible to
pole mount the arrays somewhere near the house as
long as the solar exposure is good. Pole mounted
solar arrays also have the potential to rotate to
follow the sun over the day. This provides a 30
or more boost to the performance.
35Pole Mount for Solarex Modules
36Pole Mounted PV
37Pole Mounted PV
38Roof Integrated PV
- If you are doing new construction or a reroofing
job, it is possible to make the roof itself a
solar PV collector. This saves the cost of the
roof itself, and offers a more aesthetic design.
The new roof can be shingled or look like metal
roofing. A few examples follow.
39Solar Roofing Shingles
40Roof Integrated Photovoltaics in Misawi, Japan
41Roof Integrated PV in Japan
42Roof Integrated PV in Maine
43Roof Integrated Photovoltaic System in Colorado
44Roof Integrated PV (objects below chimney are
solar hot water collectors)
45PV Installation in Planned Community in Germany
46Sizing a PV System
- Solar modules are typically sold by the peak
watt. That means that when the sun is at its peak
intensity (clear day around midday) of 1000 watts
per m2, a solar module rates at say 100 Wp (peak
watts) would put out 100 watts of power. The
climate data at a given site summarizes the solar
intensity data in terms of peak sun hours, the
effective number of hours that the sun is at that
peak intensity on an average day. If the average
peak sun hours is 4.1, it also means that a kw of
PV panels will provide 4.1 kw-hr a day.
47Thinking About Solar Energy
- When the sky is clear and it is around midday,
the solar intensity is about 1000 watts per m2 or
1 kw/m2 - In one hour, 1 square meter of the earths
surface facing the sun will intercept about 1
kw-hr of solar energy. - What you collect depends upon surface orientation
and collector efficiency
48Sizing a PV System to Consumption
- A PV system can be sized to provide part or
all of your electrical consumption. If you wanted
to produce 3600 kw-hr a year at a site that had
an average of 4.1 peak sun hours per day, - PV Size in KWp 3600 kw-hr
- 4.1 kw-hr/day x 365 days/yr x 0.9 x0.98
- 2.7 KWp
- Note the 0.9 is the inverter efficiency and the
0.98 represents the loss in the wiring.
49Thinking About Electrical Consumption
- 1 kW 1000 watts 1.34 hp (presumably the
maximum sustained output of a horse) - 1 kW-hr 3413 Btu is the consumption of a 1
kW device operated for an hour (EPxt) - Now think about a Sherpa mountain guide
carrying a 90 lb pack up Mount Everest, about
29,000 ft or 8,839 meters high, over a week, the
typical time for such a trip
50The Sherpa-Week
- Since we know that the energy in lifting is
given by mgh or 40.8 kg x 9.8 m/s2 x 8839m
3,539,000 joules or about 1 kw-hr, we can say
that roughly 1 kw-hr 1 Sherpa-week.
Typical U.S. household consumption is 600 kw-hr
per month or 20 kw-hr per day, or every day it is
like hiring 20 Sherpa to carry the 90 lb packs up
Mt. Everest. At the end of the week, we have 140
Sherpa climbing the slopes so the equivalent
power that we consume is like having 140 Sherpa
climbing Mt Everest continually. We might want to
consider reducing this number before adding PV to
our roof.
51How Much Area Is Needed?
- The actual area that you need depends on the
efficiency of the solar cells that you use.
Typical polycrystalline silicon with around 12
efficiency will require about 100 ft2 of area to
provide a peak kilowatt. Less efficient amorphous
silicon may need 200 ft2 to provide the same
output. Modules are sold in terms of peak wattage
and their areas are given so you can easily
determine the total roof area that is needed for
a given size array.
52Find the efficiency of a solar cell module given
its power rating and its area
- Assume it is a 100 Wp module and its area is
0.8 m2. Remember that the peak power rating is
based on an intensity of 1000 watts/m2. So the
maximum output with 100 efficiency is P I x A
1000 w/m2 x 0.8 m2 800 watts - The actual efficiency Pactual peak/Pmaximum
peak - 100 watts/800 watts 0.125 or 12.5
53Larger Scale PV
- Of course you dont have to stop with home based
PV systems. They make equally good sense for
businesses and corporations who want to reduce
their cost of electricity by reducing their peak
power consumption, or who want to emphasize their
greenness as part of their image, or who need to
operate in a grid failure.
54Rooftop Installation at Mauna Lani Resort, Hawaii
55Details of Roof Installation for Mauna Lani
Resort, Hawaii
56Solar CarportNavy Installation San Diego,
California
57BP Installation on their Gas Station
58Large 57 KW Rural Installation
59Solar Added to Flat Roofs(can upgrade the
insulation as well)
6059 KW Installation of 5600 ft2 in Greenpoint,
Brooklyn
61The Greenpoint, NY Building
62FALA Factory Roof InstallationFarmingdale, LI,
NYNote the number of other roofs
63Solar Cells Installed in Building Facade
64The sun is the primary energy source for almost
all energy flows on the planet. Its time we
started using it.
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