Going Solar Is Now Affordable
Our Experienced Solar Consultants Help You Design The Perfect Solution
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.
What Our Customers are Saying
Ready To Go Solar?
- 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 resident to use the sun to power daily life: running your a/c, cleaning clothing, seeing TV, cooking supper. All while reducing your carbon footprint, and without burning fossil fuels or putting a strain on the electrical grid. And while the ecological advantages of solar power are considerable, numerous residents find that the benefit, special features, and expense savings of owning a solar power system are a lot more attractive.
Leading Benefits of Solar Energy
#1 Dramatically minimize or perhaps remove your electrical expenses
Whether you're a homeowner, business, or nonprofit, electrical power costs can make up a big part of your monthly expenses. With a photovoltaic panel system, you'll create 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 minimize your energy bills and you'll still save a lot of cash.
#2 Earn an excellent return on your investment
Solar panels aren't an expenditure-- they are among the very best methods to invest, with returns rivaling those of more standard financial investments like stocks and bonds. Thanks to significant electrical energy expense savings, the average American homeowner pays off their photovoltaic panel system in 7 to eight years and sees an ROI of 20 percent or more.
#3 Protect against increasing energy expenses
One of the most clear cut advantages of photovoltaic panels is the capability to hedge utility costs. In the previous 10 years, residential electrical power prices have actually increased by approximately 3 percent yearly. By investing in a solar energy system now, you can fix your electricity rate and secure against unforeseeable boosts in electrical energy costs. If you're a business or house owner with rising and falling capital, going solar also assists you better forecast and handle your expenses.
#4 Increase your home value
Multiple research studies have discovered that houses equipped with solar energy systems have greater residential or commercial property worths and sell more quickly than non-solar homes. Appraisers are progressively taking solar setups into consideration as they value houses at the time of a sale, and as property buyers end up being more informed about solar, need for homes geared up 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 accomplishing energy independence in the United States. By increasing our capability to generate electrical power from the sun, we can also insulate our nation from rate changes in global energy markets.
#6 Create jobs and assist your regional economy
According to The Solar Structure, the solar industry added jobs at a rate almost 12 times faster than the total U.S. economy in 2015, representing 1.2 percent of all jobs in the country. This development is anticipated to continue. Because solar-related tasks tend to be greater paying and can not be contracted out, they are a significant factor to the United States economy.
#7 Protect the environment
Solar is a terrific way to decrease your carbon footprint. Buildings are responsible for 38 percent of all carbon emissions in the U.S., and going solar can significantly reduce that number. A common domestic solar panel system will remove 3 to 4 lots of carbon emissions each year-- the equivalent of planting over 100 trees each year.
#8 Demonstrate your commitment to sustainability
Sustainability and corporate social obligation are very important parts of a company's culture and values. They likewise produce bottom line outcomes. Increasingly, customers and communities are recognizing and rewarding organisations that decide to run responsibly. Services are discovering that "green" qualifications are an effective chauffeur of consumer acquiring choices, creating goodwill and improving business results.
#9 Start Conserving from Day 1
Solar purchase power contracts (PPAs) and solar leasing has made it possible for property owners to go solar for little or no money down.
Many property owners decide to finance their solar panels with among the "pay-as-you-go" funding alternatives. This suggests that a third-party company-- the solar service provider-- owns the planetary system and looks after setup, upkeep, monitoring and repair works. You just pay the solar provider for electrical power-- less than you would've paid the utility business.
As of June 2013, 75% of all American houses have access to pay-as-you-go solar.
#10. Solar is a Secure Investment
The energy business are infamous for their fluctuating and unreliable electrical power prices. There is plainly an upward trend.
With photovoltaic panels and simple math, we can compute how much electricity will be produced, and most notably, at what price, for a minimum of the next Twenty Years (fixed 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
Can I Connect A Solar Panel Charger To My Car Battery Without Interfering With The Alternator?
Would Like To Add A Solar Panel To Help Charge My Car Battery. Will This Affect/Hurt My Alternator? Do I Need To Switch From Alternator To Solar.
I Was Hoping To Leave The Panel Attached To The Car During Operation.
I'd Like It As Easy As Possible.
High wattage High temperature Diodes is your answer.
One on wire from solar panel charger to battery's positive.
Another on wire from alternator to battery's positive.
Current will only from solar panel charger and alternator to battery.
Both solar panel charger and alternator can charge battery simultaneously.
Convenient - no switching needed.
Pollutants And Pollutions..?
The Sizes Distribution Of Particles Emitted From Coal-Fired Power Plants Is Bimodal? What Are Some Of The Properties Of The Smaller Fraction In Term Of Potential Environmental Implications?
Global warming is the increase in the average temperature of the Earth's near-surface air and oceans since the mid-20th century and its projected continuation. Global surface temperature increased 0.74 ± 0.18 °C (1.33 ± 0.32 °F) during the last century.The Intergovernmental Panel on Climate Change (IPCC) concludes that increasing greenhouse gas concentrations resulting from human activity such as fossil fuel burning and deforestation caused most of the observed temperature increase since the middle of the 20th century.The IPCC also concludes that variations in natural phenomena such as solar radiation and volcanoes produced most of the warming from pre-industrial times to 1950 and had a small cooling effect afterward.These basic conclusions have been endorsed by more than 45 scientific societies and academies of science,including all of the national academies of science of the major industrialized countries.A small number of scientists dispute the consensus view.Climate model projections summarized in the latest IPCC report indicate that the global surface temperature will probably rise a further 1.1 to 6.4 °C (2.0 to 11.5 °F) during the twenty-first century.The uncertainty in this estimate arises from the use of models with differing sensitivity to greenhouse gas concentrations and the use of differing estimates of future greenhouse gas emissions. Some other uncertainties include how warming and related changes will vary from region to region around the globe. Most studies focus on the period up to the year 2100. However, warming is expected to continue beyond 2100 even if emissions stop, because of the large heat capacity of the oceans and the long lifetime of carbon dioxide in the atmosphere.An increase in global temperature will cause sea levels to rise and will change the amount and pattern of precipitation, probably including expansion of subtropical deserts.The continuing retreat of glaciers, permafrost and sea ice is expected, with warming being strongest in the Arctic. Other likely effects include increases in the intensity of extreme weather events, species extinctions, and changes in agricultural yields.Political and public debate continues regarding climate change, and what actions (if any) to take in response. The available options are mitigation to reduce further emissions; adaptation to reduce the damage caused by warming; and, more speculatively, geoengineering to reverse global warming. Most national governments have signed and ratified the Kyoto Protocol aimed at reducing greenhouse gas emissions.
The main tools for projecting future climate changes are computer models of the climate. These models are based on physical principles including fluid dynamics and radiative transfer. Although they attempt to include as many processes as possible, simplifications of the actual climate system are inevitable because of the constraints of available computer power and limitations in knowledge of the climate system. All modern climate models are in fact combinations of models for different parts of the Earth that are coupled to one another. These include an atmospheric model for air movement, temperature, clouds, and other atmospheric properties; an ocean model that predicts temperature, salt content, and circulation of ocean waters; models for ice cover on land and sea; and a model of heat and moisture transfer from soil and vegetation to the atmosphere. Some models also include treatments of chemical and biological processes.Climate models project a warmer climate due to increasing levels of greenhouse gases.Although much of the variation in model outcomes depends on the greenhouse gas emissions used as inputs, the temperature effect of a specific greenhouse gas concentration (climate sensitivity) varies depending on the model used. The representation of clouds is one of the main sources of uncertainty in present-generation models.Global climate model projections of future climate most often have used estimates of greenhouse gas emissions from the IPCC Special Report on Emissions Scenarios (SRES). In addition to human-caused emissions, some models also include a simulation of the carbon cycle; this generally shows a positive feedback, though this response is uncertain. Some observational studies also show a positive feedback.Including uncertainties in future greenhouse gas concentrations and climate sensitivity, the IPCC anticipates a warming of 1.1 °C to 6.4 °C (2.0 °F to 11.5 °F) by the end of the 21st century, relative to 1980–1999. A 2008 paper predicts that the global temperature may not increase during the next decade because short-term natural fluctuations may temporarily outweigh greenhouse gas-induced warming.Models are also used to help investigate the causes of recent climate change by comparing the observed changes to those that the models project from various natural and human-derived causes. Although these models do not unambiguously attribute the warming that occurred from approximat
How Is Solar Energy Produced And Used?
Solar energy can be produced from solar radiation. Sunlight travels through the upper parts of the earth's atmosphere. Once this sunlight reaches the surface of the earth, it must be captured so it can be turned into an usable energy source. At the earth's surface, it is called infrared radiation where it is captured through the aid of photovoltaic or solar cells.Once captured, the sunlight is absorbed into these photovoltaic/solar cells. These photovoltaic/solar cells are then used to convert the sun's energy into electrical energy. These cells are non-mechanical devices that are made from silicon alloys. Most of the solar collectors resemble black, flat boxes that sit on building rooftops. In the most common design, pipes in the box carry liquids that transfer the heat from the box into the building. This heated liquid then heats the water in a tank or is passed through radiators to heat the air. Below are the common usage of Solar Energy:
The number of PV installations on buildings connected to the electricity grid has grown in recent years. Government subsidy programs (particularly in Germany and Japan) and green pricing policies of utilities or electricity service providers have stimulated demand. Demand is also driven by the desire of individuals or companies to obtain their electricity from a clean, non-polluting, renewable source. These consumers are usually willing to pay only a small premium for renewable energy. Increasingly, the incentive is an attractive financial return on the investment through the sale of solar electricity at premium feed-in tariff rates.
In solar systems connected to the electricity grid, the PV system supplies electricity to the building, and any daytime excess may be exported to the grid. Batteries are not required because the grid supplies any extra demand. However, to be independent of the grid supply, battery storage is needed to provide power at night.
Holiday or vacation homes without access to the electricity grid can use solar systems more cost-effectively than if the grid was extended to reach the location. Remote homes in sunny locations can obtain reliable electricity to meet basic needs with a simple system comprising of a PV panel, a rechargeable battery to store the energy captured during daylight hours, a regulator (or charge controller), and the necessary wiring and switches. Such systems are often called solar home systems (SHS).
On an office building, roof areas can be covered with glass PV modules, which can be semi-transparent to provide shaded light. On a factory or warehouse, large roof areas are the best location for solar modules. If the roof is flat, then arrays can be mounted using techniques that do not breach the weatherproofed roof membrane. Also, skylights can be partially covered with PV.
The vertical walls of office buildings provide several opportunities for PV incorporation, as well as sunshades or balconies incorporating a PV system. Sunshades may have the PV system mounted externally to the building, or have PV cells specially mounted between glass sheets comprising the window.
For many years, solar energy has been the power supply choice for industrial applications, especially where power is required at remote locations. Because solar systems are highly reliable and require little maintenance, they are ideal in distant or isolated places.
Solar energy is also frequently used for transportation signaling, such as offshore navigation buoys, lighthouses, aircraft warning light structures, and increasingly in road traffic warning signals. Solar is used to power environmental monitoring equipment and corrosion protection systems for pipelines, well-heads, bridges, and other structures. For larger electrical loads, it can be cost-effective to configure a hybrid power system that links the PV with a small diesel generator.
Remote buildings, such as schools, community halls, and clinics, can benefit from solar energy. In developing regions, central power plants can provide electricity to homes via a local wired network, or act as a battery charging station where members of the community can bring batteries to be recharged.
PV systems can be used to pump water in remote areas as part of a portable water supply system. Specialized solar water pumps are designed for submersible use or to float on open water. Large-scale desalination plants can also be PV powered using an array of PV modules with battery storage.
PV systems are sometimes best configured with a small diesel generator in order to meet heavy power requirements in off-grid locations. With a small diesel generator, the PV system does not have to be sized to cope with the worst sunlight conditions during the year. The diesel generator can provide back-up power that is minimized during the sunniest part of the year by the PV system. This keeps fuel and maintenance costs low.
How To Harness Solar Energy Captured By Plant-Based Structures?
Most of the fuel based energy we use today is originally solar energy captured by plants and then chemically changed over time. This includes coal, oil, gas, the bio fuels: ethanol and bio diesel.
Photosynthesis is only about 5% efficient. The typical solar photovoltaic collector is 8 to 20% efficient while some 41% efficient models have been developed in the lab. Solar thermal panels can be even better at 60 to 80% efficient. There have been some experiments to make a photosynthesis based solar photovoltaic collector, but I think more success has been achieved through the processing of bio fuels. Bio fuels that use sugars created in plants through the energy gained from photosynthesis are used to create ethanol. Bio fuels that use the plant oils made from the energy of photosynthesis are processed into bio diesel.
Also for thousands of years we have been using the energy in plant based structures as our food and medicine. There are people who put plants in their environment only to clean the air of harmful chemicals. There are many industrial products made from plants. To some extent these also might be attributed to photosynthesis.
What Is The Current Situation Concerning Solar Powered Steam/Sterling Engines?
I Found Myself Fascinated By The Idea That Every Household In The Us...Nay, They World Could Have Basic Energy Needs Covered By Solar Powered Engines, However, I Am Not Finding Any New Information. Since This Is Such An Interesting And Seemingly Flawless Possibility For 'Green' Energy; I Am At A Loss At To Why More People Aren'T Interested.
Anyone Have Some Superb Information To Share? I Would Be Thankful.
Using solar heat energy a synthetic oil is heated up to very high temperatures(800c-1500c) and using this oil steam is produced by heating water. In turn this steam drives the generator through turbines.
Solar heat is concentrated by using crescent moon shaped mirrors which are focused to same common point where oil is heated.
But now recently a new technology called molten salt is used for heating purpose even at night conditions.