Wind/Solar Power?

2 ANSWERS

1. 
   

   solar power is easier and costs less than a windmill or other means of capturing wind, pluss, you have to be in a very windy location

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2. 
   

   Direct or indirect
   
   Solar power can be classified as direct or indirect.
   
   Direct solar power involves only one transformation into a usable form.
   
   Examples:
   
   Sunlight hits a photovoltaic cell creating electricity. (Photovoltaics are classified as direct although the electricity is usually converted to another form of energy such as light or mechanical energy before becoming useful.)
   
   Sunlight hits a dark surface and the surface warms when the light is converted to heat by interacting with matter. The heat is used to heat a room or water.
   
   Indirect solar power involves more than one transformation to reach a usable form.
   
   Example:
   
   Systems to close insulating shutters or move shades.
   
   Many other types of power generation are indirectly solar-powered. Plants use photosynthesis to convert solar energy to chemical energy, which can later be burned as fuel to generate electricity; oil and coal originated as plants. Hydroelectric dams and wind turbines are indirectly powered by the sun.
   
   Passive or active
   
   Solar power can also be classified as passive or active:
   
   Passive solar systems are systems that do not involve the input of any other forms of energy apart from the incoming sunlight.
   
   Active solar This usually refers to system which use additional mechanisms such as circulation pumps, air blowers or automatic systems which aim collectors at the sun.
   
   Types of solar power applications
   
   Most solar energy used today is harnessed as heat or electricity.
   
   Solar design in architecture
   
   Solar design is the use of architectural features to replace the use of grid electricity and fossil fuels with the use of solar energy and decrease the energy needed in a home or building with insulation and efficient lighting and appliances.
   
   Architectural features used in solar design:
   
   South-facing (for the Northern Hemisphere) or north-facing (for the Southern Hemisphere) windows with insulated glazing that has high ultraviolet transmitance.
   
   Thermal masses -- any masses such as walls or roofs that absorb and hold the sun's heat. Materials with high specific heat like stone, concrete, adobe or water work best. See Trombe walls.
   
   Insulating shutters for windows to be closed at night and on overcast days. These trap solar heat in the building.
   
   Fixed awnings positioned to create shade in the summer and exposure to the sun in the winter.
   
   Movable awnings to be repositioned seasonally.
   
   A well insulated and sealed building envelope.
   
   Exhaust fans in high humidity areas.
   
   Passive or active warm air solar panels. Pass air over black surfaces fixed behind a glass pane. The air is heated by the sun and flows into the building.
   
   Active solar panels using water or antifreeze solutions. These get hot in the sun and the hot liquid is used to heat the building or in a solar hot water system.
   
   Passive solar panels for preheating potable water.
   
   Photovoltaic systems to provide electricity.
   
   Solar chimneys for cooling.
   
   Solar hot water
   
   Solar hot water systems are quite common in some countries where a small flat panel collector is mounted on the roof and able to meet most of a household's hot water needs. Cheaper flat panel collectors are also often used to heat swimming pools, thereby extending their swimming seasons.
   
   Solar cooking
   
   A solar box cooker traps the sun's power in an insulated box; these have been successfully used for cooking, pasteurization and fruit canning. Solar cooking is helping many developing countries, both reducing the demands for local firewood and maintaining a cleaner environment for the cooks. The first known western solar oven is attributed to Horace de Saussure, a Swiss naturalist experimenting as early as 1767.
   
   Photovoltaic cells
   
   Solar cells (also referred to as photovoltaic cells) are devices or banks of devices that use the photoelectric effect of semiconductors to generate electricity directly from the sunlight. As their manufacturing costs have remained high during the twentieth century, their use has been limited to very low power devices such as calculators with >LCD displays or to generate electricity for isolated locations which could afford the technology. The most important use to date has been to power orbiting satellites and other spacecraft. As manufacturing costs decreased in the last decade of the twentieth century, solar power has become cost-effective for many remote low power applications such as roadside emergency telephones, remote sensing, and limited "off grid" home power applications. Though their cost is not yet competitive with conventional power and hydroelectricity, it has been declining steadily and is now within a factor of 2 in many areas.
   
   Solar power plants
   
   Solar power plants generally use reflectors to concentrate sunlight into a heat absorber.
   
   Heliostat mirror power plants use an array of flat moveable mirrors to focus the sun's rays upon a collector tower. A vast amount of energy is transported from the tower and stored by using a high temperature liquid like sodium. This in turn is used to heat water for use in stream turbines.
   
   A parabolic trough power plant is another type of solar thermal collector. It consists of a series of troughs rather like rainwater guttering with a hollow tube running its length. Sunlight is reflected by the mirror and concentrated on the tube. Heat transfer fluid runs through the tube to absorb heat from the concentrated sunlight and is used to power a steam turbine.
   
   A Parabolic reflector power plant is rather like a large satellite dish but with the inside surface made of mirror material. It focuses all the sun's energy to a single point and can achieve very high temperatures. They are often used with a stirling engine or steam engine to obtain mechanical power directly.
   
   A solar chimney is a power plant where air passes under a very large agricultural glass house (between 2-30 kilometres in diameter), is heated by the sun and channeled upwards towards a convection tower. It then rises naturally and is used to drive turbines, which generate electricity.
   
   Solar chemical
   
   There have been experiments to harness energy by absorbing sunlight in a chemical reaction in a way similar to photosynthesis without using living organisms but no practical process has yet emerged.
   
   Energy Storage
   
   For a stand-alone system, some means must be employed to store the collected energy for use during hours of darkness or cloud cover - either as electrochemically in batteries, or in some other form such as hydrogen (produced by electrolysis of water), flywheels in vacuum, or superconductors. Storage always has an extra stage of energy conversion, with consequent energy losses, greatly increasing capital costs. One way around this is to export excess power to the power grid, drawing it back when needed. This effectively uses the power grid as a battery.
   
   Deployment of Solar Power
   
   Deployment of solar power depends largely upon local conditions and requirements. But as all industrialised nations share a need for electricity, it is clear that solar power will increasingly be used to supply a cheap, reliable electricity supply.
   
   North America
   
   In some areas of the U.S., solar electric systems are already competitive with utility systems. As of 2002, there is a list of technical conditions: There must be many sunny days. The systems must sell power to the grid, avoiding battery costs. The solar systems must be inexpensively mass-purchased, which usually means they must be installed at the time of construction. Finally, the region must have high power prices. For example, Southern California has about 260 sunny days a year, making it an excellent venue. It yields about 9%/yr returns of investment when systems are installed at $9/watt (not cheap, but feasible), and utility prices are at $0.095 per kilowatt-hour (the current base rate). On-grid solar power can be especially feasible when combined with time-of-use net metering, since the time of maximum production is largely coincident with the time of highest pricing.
   
   Your welcome!

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