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From examining your current eletrical usage and costs to assisting with the correct financing plan, you will receive a custom designed solar energy plan which suits you and your family.
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- Fully licensed & insured installers
- Custom tailored solutions
- Free in home consultations
- Easy financing options
- 20 year warranty
- Transparent contracts
- State and federal incentives
- Roof repair if damaged during installation
- Customer service is our top priority
About Solar Energy
Solar power is energy from the sun that is transformed into thermal or electrical energy.
Solar energy is the cleanest and most abundant renewable resource source available, and the United States has some of the richest solar resources worldwide. Modern innovation can harness this energy for a variety of usages, consisting of producing electricity, supplying light or a comfortable interior environment, and heating water for domestic, commercial, or industrial usage.
Solar power makes it possible for house owners to utilize the sun to power daily life: running your air conditioning unit, washing clothes, viewing TELEVISION, cooking supper. All while lowering your carbon footprint, and without burning nonrenewable fuel sources or putting a strain on the electrical grid. And while the environmental advantages of solar power are considerable, lots of property owners find that the benefit, unique features, and expense savings of owning a solar power system are much more enticing.
Top 10 Advantages of Solar Energy
#1 Considerably reduce or even eliminate your electric costs
Whether you're a property owner, organization, or nonprofit, electrical energy expenses can comprise a large portion of your monthly expenditures. With a solar panel system, you'll produce free power for your system's whole 25+ year lifecycle. Even if you don't produce 100 percent of the energy you take in, solar will reduce your energy costs and you'll still save a great deal of cash.
#2 Make a terrific return on your financial investment
Photovoltaic panels aren't an expense-- they're one of the very best ways to invest, with returns equaling those of more conventional investments like stocks and bonds. Thanks to considerable electrical power expense cost savings, the typical American house owner settles their solar panel system in 7 to 8 years and sees an ROI of 20 percent or more.
#3 Safeguard versus rising energy costs
Among the most clear cut benefits of photovoltaic panels is the ability to hedge utility costs. In the past 10 years, domestic electrical power prices have actually gone up by approximately three percent annually. By buying a solar energy system now, you can repair your electrical power rate and secure against unforeseeable boosts in electrical energy costs. If you're a service or homeowner with changing capital, going solar also helps you better forecast and manage your costs.
#4 Boost your home value
Several research studies have actually discovered that houses geared up with solar energy systems have greater property worths and sell quicker than non-solar homes. Appraisers are progressively taking solar setups into factor to consider as they value houses at the time of a sale, and as homebuyers become more educated about solar, demand for homes equipped with solar panel systems will continue to grow.
#5 Increase U.S. energy independence
The sun is a near-infinite source of energy and a crucial component of attaining energy independence in the United States. By increasing our capacity to produce electrical energy from the sun, we can also insulate our country from price fluctuations in international energy markets.
#6 Create jobs and help your regional economy
Inning accordance with The Solar Foundation, the solar industry included jobs at a rate almost 12 times faster than the overall U.S. economy in 2015, representing 1.2 percent of all tasks in the country. This development is anticipated to continue. Due to the fact that solar-related jobs have the tendency to be higher paying and can not be outsourced, they are a significant contributor to the United States economy.
#7 Secure the environment
Solar is an excellent method to decrease your carbon footprint. Buildings are accountable for 38 percent of all carbon emissions in the United States, and going solar can significantly reduce that number. A normal residential solar panel system will remove three to 4 loads of carbon emissions each year-- the equivalent of planting over 100 trees each year.
#8 Demonstrate your commitment to sustainability
Sustainability and business social duty are very important parts of a company's culture and worths. They also produce bottom line results. Significantly, consumers and neighborhoods are acknowledging and rewarding services that decide to operate properly. Companies are discovering that "green" qualifications are a powerful motorist of customer purchasing decisions, developing goodwill and enhancing organisation outcomes.
#9 Start Saving from Day 1
Solar purchase power arrangements (PPAs) and solar leasing has actually made it possible for house owners to go solar for little or no money down.
Many homeowners opt to fund their photovoltaic panels with among the "pay-as-you-go" funding alternatives. This suggests that a third-party business-- the solar supplier-- owns the planetary system and looks after installation, maintenance, tracking and repair works. You merely pay the solar company for electrical energy-- less than you would've paid the utility company.
Since June 2013, 75% of all American homes have access to pay-as-you-go solar.
#10. Solar is a Secure Financial investment
The energy business are well-known for their changing and unreliable electricity prices. There is clearly an upward trend.
With photovoltaic panels and basic mathematics, we can compute how much electrical energy will be generated, and most importantly, at exactly what price, for a minimum of the next 20 years (repaired energy costs).
What are the various payment options?
We have many flexible purchasing agreements for customers who would like to install a new home solar system. There are three different payment options, making them a viable choice for customers of all budgets. The payment options include Lease, PPA, and Purchase.
- Low, fixed payments each month
- System insurance for 20 years, including maintenance
- Flexible end-of-term options, including system upgrade, lease extension, and free panel removal
Power Purchase Agreement (PPA)
- We own the solar panel system
- $0 down for installation
- Customers only pay for the solar energy that they use
- Customer pays for the system upfront and owns the system
- System monitoring and maintenance for 20 years
- Receive 30% federal tax credit
- See a return on investment within 7-10 years
What happens when the contract for my lease is finished?
We provide our customers with a few different options for when their lease contract is up. Customers can upgrade their equipment to the newest solar technology available, extend the agreement, or have the panels removed at no cost.
What is the warranty?
The Lease and PPA include a 20-year warranty during the lifetime of the system. This warranty exceeds that of most other solar installers’ warranties.
Frequently Asked Questions
Why Is Solar Energy Important To Us?
Please Help For Science Project!
ENERGY FROM THE SUN
The sun has produced energy for billions of years. Solar energy is the sun’s rays (solar radiation) that reach the earth.
Solar energy can be converted into other forms of energy, such as heat and electricity. In the 1830s, the British astronomer John Herschel used a solar thermal collector box (a device that absorbs sunlight to collect heat) to cook food during an expedition to Africa. Today, people use the sun's energy for lots of things.
Solar energy can be converted to thermal (or heat) energy and used to:
Heat water – for use in homes, buildings, or swimming pools.
Heat spaces – inside greenhouses, homes, and other buildings.
Solar energy can be converted to electricity in two ways:
Photovoltaic (PV devices) or “solar cells” – change sunlight directly into electricity. PV systems are often used in remote locations that are not connected to the electric grid. They are also used to power watches, calculators, and lighted road signs.
Solar Power Plants - indirectly generate electricity when the heat from solar thermal collectors is used to heat a fluid which produces steam that is used to power generator. Out of the 15 known solar electric generating units operating in the United States at the end of 2006, 10 of these are in California, and 5 in Arizona. No statistics are being collected on solar plants that produce less than 1 megawatt of electricity, so there may be smaller solar plants in a number of other states.
What Is Solar Energy,Light Energy, Electrical .Energy,Sound Energy,Chemical Energy,Nuclear Energy,Atomic Ene?
Solar Energy: All kind of energy (Wide range of EM Waves) coming out of Sun.
Light Energy: The EM Wave, which falls in visible range.
Electrical Energy: The electrical form (Batteries, Mains Power Supply, Lightening) of energy. I mean, where the energy is experienced due to flow of charges.
Sound Energy: A energy which lies within audible range (20-20kHz), and can travel freely in air.
Chemical Energy: A chemical process which can generate other usable form of energy.
Nuclear/Atomic Energy: A nuclear/atomic reaction process which can generate other usable form of energy.
What Would Solar Energy Come Under If You Were To Make A Facebook Page?
I Have To Make A Facebook Page For A Project To Do With Solar Energy. Would Anyone Know What Topic Would It Come Under.
Renewable energy, green, environment
Where Can I Learn How To Install And Use Solar Panels On My Home?
I'M Very Interested In Putting Solar Panels On My Roof Or In My Windows Because Of All The Sunlight I Get. Where Can I Find Information On How I Can Actually Hook Things Up To Use Solar Panels For Real Electricity From Start To Finsih?
this site should give you all the information that you need to learn about solar panels
this site is great for many of DIY environmentally sustainable projects
Can Someone Explain How Solar Energy Works?
This is a actual explanation of how it works.
Photovoltaic Cells: Converting Photons to Electrons
The solar cells that you see on calculators and satellites are photovoltaic cells or modules (modules are simply a group of cells electrically connected and packaged in one frame). Photovoltaics, as the word implies (photo = light, voltaic = electricity), convert sunlight directly into electricity. Once used almost exclusively in space, photovoltaics are used more and more in less exotic ways. They could even power your house. How do these devices work?
Photovoltaic (PV) cells are made of special materials called semiconductors such as silicon, which is currently the most commonly used. Basically, when light strikes the cell, a certain portion of it is absorbed within the semiconductor material. This means that the energy of the absorbed light is transferred to the semiconductor. The energy knocks electrons loose, allowing them to flow freely. PV cells also all have one or more electric fields that act to force electrons freed by light absorption to flow in a certain direction. This flow of electrons is a current, and by placing metal contacts on the top and bottom of the PV cell, we can draw that current off to use externally. For example, the current can power a calculator. This current, together with the cell's voltage (which is a result of its built-in electric field or fields), defines the power (or wattage) that the solar cell can produce.
That's the basic process, but there's really much more to it. Let's take a deeper look into one example of a PV cell: the single-crystal silicon cell.
How Silicon Makes a Solar Cell
Silicon has some special chemical properties, especially in its crystalline form. An atom of silicon has 14 electrons, arranged in three different shells. The first two shells, those closest to the center, are completely full. The outer shell, however, is only half full, having only four electrons. A silicon atom will always look for ways to fill up its last shell (which would like to have eight electrons). To do this, it will share electrons with four of its neighbor silicon atoms. It's like every atom holds hands with its neighbors, except that in this case, each atom has four hands joined to four neighbors. That's what forms the crystalline structure, and that structure turns out to be important to this type of PV cell.
We've now described pure, crystalline silicon. Pure silicon is a poor conductor of electricity because none of its electrons are free to move about, as electrons are in good conductors such as copper. Instead, the electrons are all locked in the crystalline structure. The silicon in a solar cell is modified slightly so that it will work as a solar cell.
A solar cell has silicon with impurities -- other atoms mixed in with the silicon atoms, changing the way things work a bit. We usually think of impurities as something undesirable, but in our case, our cell wouldn't work without them. These impurities are actually put there on purpose. Consider silicon with an atom of phosphorous here and there, maybe one for every million silicon atoms. Phosphorous has five electrons in its outer shell, not four. It still bonds with its silicon neighbor atoms, but in a sense, the phosphorous has one electron that doesn't have anyone to hold hands with. It doesn't form part of a bond, but there is a positive proton in the phosphorous nucleus holding it in place.
When energy is added to pure silicon, for example in the form of heat, it can cause a few electrons to break free of their bonds and leave their atoms. A hole is left behind in each case. These electrons then wander randomly around the crystalline lattice looking for another hole to fall into. These electrons are called free carriers, and can carry electrical current. There are so few of them in pure silicon, however, that they aren't very useful. Our impure silicon with phosphorous atoms mixed in is a different story. It turns out that it takes a lot less energy to knock loose one of our "extra" phosphorous electrons because they aren't tied up in a bond -- their neighbors aren't holding them back. As a result, most of these electrons do break free, and we have a lot more free carriers than we would have in pure silicon. The process of adding impurities on purpose is called doping, and when doped with phosphorous, the resulting silicon is called N-type ("n" for negative) because of the prevalence of free electrons. N-type doped silicon is a much better conductor than pure silicon is.
Actually, only part of our solar cell is N-type. The other part is doped with boron, which has only three electrons in its outer shell instead of four, to become P-type silicon. Instead of having free electrons, P-type silicon ("p" for positive) has free holes. Holes really are just the absence of electrons, so they carry the opposite (positive) charge. They move around just like electrons do.
The interesting part starts when you put N-type silicon together with P-type silicon. Remember that every PV cell has at least one electric field. Without an electric field, the cell wouldn't work, and this field forms when the N-type and P-type silicon are in contact. Suddenly, the free electrons in the N side, which have been looking all over for holes to fall into, see all the free holes on the P side, and there's a mad rush to fill them in.