CHAPTER 7
SOLAR PANEL
SYSTEM
Types of Solar Panels
There are two main types of solar panel
1. Solar electric panels
How PV Panels Work
PV panels collect energy from the sun and convert it into electricity PV systems convert sunlight directly into electricity. “Photo” refers to light and “voltaic” to electricity. A PV cell is made of a semiconductor material, usually crystalline silicon, which absorbs sunlight. You’ve seen PV cells at work in simple mechanisms like watches and calculators. You’ve probably even seen them for signs on the road. More complex PV systems produce solar electricity for houses and the utility grid. The utility grid is the power source available to your local electricity provider.
PV cells are typically combined into modules, or panels, containing about 40 cells. Roughly ten modules constitute a PV array, or grouping of panels.
Details on How PV Panels Work
Most PV panels contain a top protective layer, two specially treated layers of silicon with collecting circuitry attached to the top layer, and a polymer backing layer.
The top layer of silicon is treated to make it electrically negative; the back layer is treated it make it electrically positive. When sunlight knocks electrons loose from the silicon, electrons move up from the bottom layer of silicon and crowd the electrons in the top layer. The electrons freed from the top layer are collected by electrical contacts on the surface of the top layer and routed through an external circuit, thus providing power to the electrical system attached to the panels.
New technology, which we’ll get to in a later section, uses different, less expensive materials than silicon in PV panels to capture sunlight more affordably.
Where is PV Panels Installed?
Most PV panels go on solar south-facing roofs parallel to the roof’s slope in the northern hemisphere, and on solar north-facing roofs in the southern hemisphere. Some arrays can be mounted on poles or on the ground, but such placement could be prohibited by local regulations or homeowners’ association rules. An important consideration is how many peak sun hours your system will get. Will your solar panels get year-round unshaded sun exposure from 9 a.m. - 3 p.m. (the ideal)? Is your climate stormy, foggy, and dusty? The power of your system will vary depending on your geographical location. People in the northeastern US, for example, will need more solar panels on their roofs to provide the same amount of solar electricity as someone in Arizona.
What Happens at Night and on Cloudy Days?
Because solar electric systems only produce power when the sun is shining, many consumers also connect their solar system to a utility power grid that provides additional electricity when the solar panels are not producing enough. That type of solar system is called a grid-tied system.
Off-Grid vs. Grid-Tied Systems
Costs also vary depending on whether your solar energy system is grid-tied or off-grid. The cost of installing a typical off-grid PV system in a home ranges from $15,000-$20,000 per kilowatt hour. The cost lowers when the solar system is installed as part of the initial house construction, because it is easier and more cost-efficient to incorporate energy-saving design, PV panels and other equipment during construction than to add them after the house is already built.
Off-grid systems require batteries to store electricity and a charge regulator to make sure the batteries are not under- or overcharged. However, with the cost of extending power lines from the utility grid averaging from $20,00-$80,000 per mile, a PV system can be a wise investment for electricity in remote areas.
There are several varieties of off-grid systems:
Small stand-alone solar electricity systems are often used for RV power, lighting, cabins, back-up and portable power systems.
A complete stand-alone solar system provides independence from both fossil fuels and electric utility companies.
A typical complete stand-alone system uses two inverters to make sure power is available for large loads such as air conditioners, and one inverter can supply power when the other may not be working or needs servicing.
Such systems require sizable battery storage capacity so electricity is available when adverse weather diminishes solar power.
Batteries are an expensive component of stand-alone solar systems, initially costing between $80-$200 per kWh for residential use.
Hybrid systems combine PV panels with additional power sources such as fossil- fuel generators.
A hybrid system uses fewer solar panels than a typical stand-alone system, because a gasoline, propane or diesel generator produces power when solar panels are not producing enough.
Such systems can be used for cabins, remote homes and to power small medical facilities in third-world countries.
Off Grid advantages:
1. Freedom from electric bills
2. Independence of the public utility grid
3. Cost-effective for remote areas without power lines
1. Higher initial investment than grid-tied systems
2. Expense and maintenance of more system components such as batteries and charge regulators
3. Possibility of power outage in extended periods of adverse sun conditions
Grid Tied advantages:
1. Backup power if the solar system isn’t producing enough 2. Net metering if the solar system is producing too much power 3. Lower initial investment than for most off-grid systems
Grid Tied disadvantages:
1. Some dependence on the utility grid
2. May not be able to use solar system in the event of a grid power failure 3. Some incentives require that contractors demonstrate proper licensing and
capability in areas specific to grid-tied installation
What Happens if a Solar System Produces More Energy Than the Home Needs?
In a grid-tied system, homeowners can get credit when their system produces more solar electricity than the house itself needs. Many utility companies use “net metering” or “net billing” for customers with solar energy systems. The utility credits a homeowner’s account for excess solar electricity, which goes back to the utility grid, then applies the credit to other months when the system produces less electricity.
CASAnova
Data sheet
Geometry:
Length of north and south facade: 50.0 m Length of west and east facade: 27.3 m Height (without roof): 14.2 m Number of floors: 3 Height of roof: 1.0
Roof ridge: in north-south-direction Deviation from south direction (east positiv): -35.0 °
Ground area: 1365.0 m² Useful area: 3276.0 m² Volume total: 19383.0 m³ Air volume: 16052.4 m³ Facade north resp. south: 710.0 m² Facade east resp. west: 387.7 m² Surface-to-volume value: 0.2 1/m
Insulation:
U values of the walls:
north: 0.20 W/(m² K) south: 0.20 W/(m² K) east: 0.20 W/(m² K) west: 0.20 W/(m² K) Roof:
Towards: outside air U value: 0.20 W/(m² K) Lower floor:
Towards: non-heated cellar (with insulation) U value: 0.20 W/(m² K)
Door (north facade):
Area: 0.0 m²
U value: 1.50 W/(m² K)
Wärmebrücken: increase U-values of surrounding planes by 0.10 W/(m² K) (normal construction)
Building:
Interior temperature: 20.0 °C Limit of overheating: 36.0 °C Ventilation:
Natural ventilation (infiltration): 0.60 1/h Mechanical ventilation: 0.00 1/h
Heat recovery (only mech. ventilation): 0 %
Internal gains: 25.0 kWh/(m² a) Kind of indoor walls: medium construction Kind of outdoor walls: medium construction Walls towards another heated area: east, west
Climate:
Climate station: New Delhi (Bharat Ganarajya)
Windows:
North:
Windows area: 248.5 m² Fraction of windows area at the facade: 35.0 %
Kind of windows: heat protection double glazing (U = 1.4 W/(m² K)) U value glazing: 1.40 W/(m² K) U value frame: 1.50 W/(m² K) g value glazing: 0.58 Fraction of frame: 20.0 % Shading: 20.0 % South: Window area: 248.5 m² Fraction of windows area at the facade: 35.0 %
Kind of windows: heat protection double glazing (U = 1.4 W/(m² K)) U value glazing: 1.40 W/(m² K) U value frame: 1.50 W/(m² K) g value glazing: 0.58 Fraction of frame: 20.0 % Shading: 20.0 % East: Window area: 0.0 m² Fraction of windows area at the facade: 50.0 %
Kind of windows: heat protection double glazing (U = 1.4 W/(m² K)) U value glazing: 1.40 W/(m² K) U value frame: 1.50 W/(m² K) g value glazing: 0.58 Fraction of frame: 20.0 % Shading: 20.0 % West: Window area: 0.0 m² Fraction of windows area at the facade: 5.0 %
Kind of windows: heat protection double glazing (U = 1.4 W/(m² K)) U value glazing: 1.40 W/(m² K)
U value frame: 1.50 W/(m² K) g value glazing: 0.58
Fraction of frame: 20.0 % Shading: 20.0 %
Energy:
Heating system: low temperature burner, boiler and distribution
inside the thermal zone
Heat transfer / system temperature: radiators (outside walls), thermostatic valves (layout temperature: 1K), system temperature:
70/55°C
Source of energy: fuel oil