For as long as our planet has spun 'round the sun, there's been solar energy cascading down on the earth, and, for a long time -- since the 7th century B.C., when glass was used to magnify it -- humans have been working to harness it. These days, technology is a bit better, providing electricity, heating, lighting, and even flight, but the point is the same: use the sun's warm glowing warming glow for our benefit.
Solar energy vs. solar power: what's the difference?
Often used synonymously with solar energy, solar power is what you've got once the sun's energy has been converted to electricity. This can be done one of two ways: heating a liquid to produce steam and spin a generator, or through photovolatics (but that's another post). For now, we'll concentrate on how to use the massive and largely untapped potential that exists with solar energy. But first, some basics.
Photo credit: Getty Images
What is solar energy?
Short answer: the light and heat provided by the sun. A slightly longer answer: after running the gauntlet from an average of 93 million miles away, through the various layers of atmosphere and atmospheric conditions (clouds, pollutants, dust and the like), about half of the solar energy is absorbed by water and land, with the other half reflected and re-radiated back into space. The half that makes it is absorbed by oceans, land masses and plants; in the ocean, the energy drives heat and wind-driven currents (like the Gulf Stream); on land, the energy is absorbed and creates heat, and the little bit that's left is absorbed by plants and converted to chemical energy through a process we all know as photosynthesis.
The word solar stems from the Roman word for the god of the sun, Sol. Therefore, the word solar refers to the Sun and “solar power” is power from the Sun.
When we say something is solar powered, we mean that the energy it uses for power came directly from solar energy or sunlight energy. The sun provides Earth with 2 major forms of energy, heat and light. Some solar powered systems utilize the heat energy for heating while others transform the light energy into electrical energy (electricity).
There are many practical applications for solar power that are in use today. Passive solar home designs utilize heat energy. By slanting windows in a house and facing them to the south you can control the heat energy that enters the house. During the winter when the Sun is low in the sky it shines into the window to warm and illuminate the house. During the summer when the Sun is high in the sky the slant of the windows keeps the sunshine out so that the house stays cooler.
There are vehicles that run on solar power. Some have PV panels as a direct power source that convert light energy into electricity to power their motors. Since those cars will not run when the sun is not available it is more practical to have a car powered by batteries that can be recharged with solar energy.
In countries and locations where traditional power sources are not available it is more economical to power a house with solar energy. To these people, solar is not an alternative energy; it is their primary energy source.
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| (‘klir · ‘drI · ad-hE-siv) n.
A mounting adhesive that uses water to activate and form a chemical bond between the glass and film, adhering the film to the glass during installation. This adhesive offers a strong bond, film clarity and longevity. |  |
| (dA’-lIt · in’- ste-lA-shen) n.
A common method for installing solar and safety window film. Window film is precut slightly larger than the framed glass pane, then trimmed up to 1/8 inch of the glass edge. |  |
| (du-el · ri –‘flek-tiv) adj.
Dual reflective window films offer reduced interior reflectance, maintaining your view though the glazing system. |  |
| (e-me–‘si–ve–tE) n.
A measurement of a surface’s ability to absorb or reflect radiant energy. The lower the emissivity rating, the better the insulation characteristic of the glazing system in regard to heat loss. For windows with film, emissivity refers to the heat reflected back into the room. When using film performance data, lower emissivity ratings are preferred to minimize interior heat loss. |  |
| ('lO · e-me–‘si–ve–tE) n.
Low-Emissivity, or Low-E, refers to a coating on glass or window film that reduces heat loss through the window film. The lower the emissivity rating, the better the insulation characteristic of the glazing system in regard to heat loss. Solar Gard Silver Ag 25 is an excellent low-emissivity film. |  |
| (mi - ‘ka - ni - kul · e-tach’-ment · sis’tem) n.
This method is used for enhanced glass retention, anchoring 8 Mil or thicker safety film to the window frame with a metal batten system. The safety film is installed to the glass, overlapping the window frame by approximately 1 inch. A metal batten system is placed over the overlapped film and screwed into the existing window frame, securely attaching the window film to the frame. Depending on the type of glass retention needed, the mechanical system can be attached as a one-sided (top), two-sided or four-sided installation. |  |
| (me-tal-Iz-d) adj.
A process where metals are applied onto a clear, polyester film as an even layer. Different metals produce different hues and performance capabilities to meet the varying consumer needs. |
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| (‘mil) n.
Unit of length for 1/1000 of an inch (.001”). Used in expressing thickness of films. 1 MIL = 25 microns. |
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| Nano Ceramics Ceramics are tough and stable materials used in space shuttles, integrated circuit components and industrial cutting tools. Nano-Ceramics are atomic-fine, equivalent to 0.000000001m discrete optical coatings which are deposited through reactive plasma processes.
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| (‘pre-shur · sens-e-tev · ad-hE-siv) n.
A film mounting adhesive that uses pressure to form a mechanical bond between the film and glass, adhering the film to the glass during installation. Pressure sensitive adhesive is tacky to the touch. All automotive window films and safety window films incorporate PSA |  |
| (saf’te · film) n.
Safety film is composed of incredibly strong, optical-quality clear or metallized polyester, high-grade ultraviolet inhibitors, special laminating and mounting adhesives, and scratch-resistant coating. The product is retrofit to interior glass surfaces for glass breakage protection. When events such as natural disasters, vandalism or bomb blasts cause glass to break, the film’s flexible construction and pressure-sensitive mounting adhesive help hold the shards on the film. This reduces the potential for personal injury and property damage. Safety film is also referred to as anti-shatter film, glass fragment retention film, blast mitigation film and Mylar.
Bekaert’s safety film is available in thickness ranging from 4 Mil (.004”) to 14 Mil (.014”) – with thicker films offering greater protection. Armorcoat is available in all thickness, offered as either a clear or metallized safety film. Select Panorama films are offered as a 4 Mil and 8 Mil upgrade. |  |
| (shA-dEn · kO-e-‘fi–shent) n.
The ratio of solar heat gain passing through a glazing system to the solar heat gain that occurs under the same conditions if the window was made of clear, unshaded double strength glass. The lower the SC number, the better the solar control efficiency of the glazing system. |  |
| (sO-ler • ab-‘zorp–tens) n.
The amount of solar energy (visible, infrared and ultraviolet,) that is absorbed by the glazing system, expressed as percent.
When sunlight strikes glass, solar energy is either transmitted through the glass, absorbed by the glass or reflected away from the glass. The type of glass and window film applied causes varying absorptance results, expressed as a percent – this is the amount of solar energy that the glass and film retains. Always refer to a manufacturer’s film-to-glass installation recommendation.
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| (sO–ler · e-ner–jE) n.
Energy from the sun that is represented by visible light (glare), infrared radiation (heat) and ultraviolet radiation (fading and health hazards). Each form of energy is differentiated by its wavelength. |  |
| (sO-ler · hEt · ‘gAn · kO-e–‘fi–shent) n.
The percentage of solar energy directly transmitted or absorbed and re-radiated into a building. The lower the SHGC, the better the solar control properties of the film. | 
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| (sO-ler • ri- ‘flek–tans) n.
The amount of solar energy (visible, infrared and ultraviolet) that is reflected by the glazing system, expressed as a percent. When sunlight strikes glass solar energy is either transmitted through the pane of glass, absorbed by the glass or reflected away from the glass. The type of glass and window film applied causes varying reflectance results, shown as a percent – this is the amount of solar energy that the glass and film rejects away.
For maximum heat rejection, look for films with a high solar energy reflectance rating. Always refer to a manufacturer’s film-to-glass installation recommendation. |  |
| (sO–ler ·tranz–‘mi-tens) n.
The amount of solar energy (visible, infrared and ultraviolet) that passes through a glazing system, expressed as a percent. When sunlight strikes glass, solar energy is either transmitted through the pane of glass, absorbed by the glass or reflected away from the glass. The type of glass and window film applied causes varying transmittance results, shown as a percent – this is the amount of solar energy that entered through the glass and film. Always refer to a manufacturer’s film-to-glass installation recommendation. | 
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| (‘spek-tral-lE · se-‘lek-tiv) adj.
Spectrally selective window films block only select wavelengths of radiation while maintaining a high amount of visible light transmittance. These premium films keep out the heat you don’t want and let in the natural light you love. The Panorama Hilite and Sterling series allow for a luminous interior, while ensuring a comfortable and temperate environment. These films are the most subtle, practically invisible when installed - ideal for maintaining a perfect view, and comfortable. even climate. |  |
| (‘spu-tur-ing) v.
A process that imbeds metal particles such as silver, stainless steel, copper, gold, titanium and chromium onto polyester film. Rolls of film are unwound and passed over target materials, depositing atoms evenly on the surface of the film through ion bombardment. This ensures long-lasting color and excellent solar performance. BSF was the first in the industry to sputter-coat window film. |
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| (to-tel · sO-ler · e-ner-jE · ri– ‘jekt–ed) n.
Measures the window film’s ability to reject solar energy in the form of visible light, infrared radiation and ultraviolet light. The higher the TSER number, the more solar energy is rejected way from the window. |  |
| (‘yU–‘val–‘yU) n.
A measurement of heat transfer through film due to outdoor/indoor temperature differences. The lower the U-value, the less heat transfers. When using performance data, a lower U-value is desirable for heat management. | 
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| (‘ul–tra–‘vI–yo-let · ‘lIt) n.
Invisible, powerful wavelengths (shorter than light but longer than X rays) emitted by the sun separated into three types, UV-A, UV-B and UV-C. UV-B causes sunburn, and prolonged exposure can cause skin cancer. Window films block nearly 100% of ultraviolet light from passing through glass. The Panorama window films are approved products of the Skin Cancer Foundation. | 
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| (‘vi-ze-bel · lIt · ab-‘zorp–tens) n
The amount of visible light that is absorbed by the glazing system, expressed as a percent. |
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| (‘vi-ze-bel · lIt · ri- ‘flek–tans ) n
The amount of visible light that is reflected by the glazing system, expressed as a percent. A higher VLR rating offers better glare control. Films with higher ratings tend to be more reflective and/or darker. |
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| (‘vi-ze-bel · lIt · tranz–‘mi-tens) n.
The amount of visible light that passes through the glazing system, expressed as a percent. A lower VLT rating tends to be better for glare control, while a higher rating is preferred for maintaining natural light. |
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