We installed solar on our 45-degree metal roof last year. We previously had problems with ice sheets that would shoot off and put bystanders in danger. The panels do not melt the snow, but seem to be advantageously working as snow and ice-guards. Interestingly we have noticed that the light passes right through the snow and we still get power. On a bright day it still seems to run just about full generation.
Use this worksheet to determine what size battery bank is required for your system. Battery size, or capacity, is measured in amp-hours. Battery voltage is determined by the number of "cells" in series. All lead-acid battery cells have a nominal output of 2 VDC. Actual cell voltage varies from about 1.7 VDC at full discharge to 2.4 VDC at full charge. 12 VDC lead-acid batteries are made of 6 separate cells in one case. 6 VDC batteries are made of 3 cells in one case. Putting battery cells in parallel increases amp-hour capacity, but does not change voltage.

With that in mind it makes a great deal of sense to use a tilt-up tower for your turbine. It makes maintenance and repairs much safer (on the ground) and cheaper. Crane fees, or having turbine installers hang off the top of a tower for long periods of time, tend to get very expensive. You should also budget for repairs, they will happen. Parts may be free under warranty, your installer’s time is not.
Several companies have begun embedding electronics into PV modules. This enables performing maximum power point tracking (MPPT) for each module individually, and the measurement of performance data for monitoring and fault detection at module level. Some of these solutions make use of power optimizers, a DC-to-DC converter technology developed to maximize the power harvest from solar photovoltaic systems. As of about 2010, such electronics can also compensate for shading effects, wherein a shadow falling across a section of a module causes the electrical output of one or more strings of cells in the module to fall to zero, but not having the output of the entire module fall to zero.
FEATURES: Made for both land and marine. Integrated automatic braking system to protect from sudden and high wind speed. Easy DIY installation methods with all materials provided. Can be used in conjunction with solar panels. MPPT Maximum power point tracking built into the wind turbine generator. Made with high quality Polypropylene and Glass Fiber material with a weather resistant seal.
Your goal is to expose the solar panel to as much sunlight as possible. First and foremost, this means you need to avoid shade - one panel in the shade can affect the efficiency of the entire system. Be sure to keep details in mind: Will the neighbor's big oak tree grow in the next ten years? Will something that's out of the way at this very second be casting a shadow later in the day? You also need to consider the qualities of your roof. In order to get the most direct sunlight, your panels should point towards the equator (South, in the Northern hemisphere) - will your roof accommodate this? And is the roof big enough to hold your panels? Another, more obscure consideration is your homeowner's association. Some people think solar panels are an eyesore (personally, I think they make your house look great) and may have banned them in your neighborhood.

Since the energy output to the loads must be balanced by the energy input from your solar panels and wind turbine, we need to calculate your daily charge requirement in amp hours as that number will come in handy later. Take your total daily watt hours x 20% (rule of thumb) to account for losses in inverter, circuits and wire transfer. Now divide by the system voltage you chose based on the previous section and write this number down. This is the charge in amp hours your solar panels will have to provide each day to meet your load requirements you have set. Example 5,000 watts daily load total X 20% = 6,000 watts / 48 volt system = 125 amp hours that will need to be generated. Example #2, 5,000 watts daily load total X 20% = 6,000 watts / 24 volt system = 250 amp hours that will need to be generated.


A typical home uses approximately 10,932 kilowatt-hours of electricity per year (about 911 kilowatt-hours per month). Depending on the average wind speed in the area, a wind turbine rated in the range of 5–15 kilowatts would be required to make a significant contribution to this demand. A 1.5-kilowatt wind turbine will meet the needs of a home requiring 300 kilowatt-hours per month in a location with a 14 mile-per-hour (6.26 meters-per-second) annual average wind speed.
In states that have retail competition for electricity service (e.g., your utility operates the local wires, but you have a choice of electricity provider), you may have to sign a separate agreement with each company. Usually these agreements are written by the utility or the electricity provider. In the case of private (investor-owned) utilities, the terms and conditions in these agreements must be reviewed and approved by state regulatory authorities.

Our DIY system is also Solaredge and has been in service for about one year now. With two electric clown cars, it really makes sense for us. By going DIY we were able to install the same size system (7.5kw) that we were quoted over $30k for by a full service solar company. Our returns (as you described well) are more than monetary, but the payback time will be around 63 months.
Go-anywhere rechargeable battery pack keeps your handheld gear Go-anywhere rechargeable battery pack keeps your handheld gear going strong. Charge AA/AAA batteries from the sun or any USB port then power your phone MP3 GPS or perk up your tablet in a pinch. Kit included Nomad 7m v2 Solar Panel and Guide 10 Plus power pack. This ultra-lightweight kit ...  More + Product Details Close
This is a substantial piece of equipment for the entire residential solar energy system. Why? This is how you get to use the solar energy you capture in the solar panels to power your home energy needs. As stated above, the solar inverter is what converts DC power to AC power – the type of power of your home appliances, computers, and other residential power runs off of.
"I came across Wholesale Solar's website and found out that we could purchase a system and install it ourselves. I researched their products and called several times with questions. Wil was readily available to answer every question, spent time looking at pictures that I sent of our property, and gave us several options that he felt would work well.
You start by monitoring your energy consumption. You need to have a good idea of how much energy you consume on the average day to determine how big of a solar energy system you’ll need. On top of that, you’ll also need to know how much money you have to spend – keeping in mind that the most expensive solar panels might not be the most cost effective for your needs.
Before choosing a wind system for your home, you should consider reducing your energy consumption by making your home or business more energy efficient. You can start by learning how electricity is used in U.S. homes. Reducing your energy consumption will significantly lower your utility bills and will reduce the size of the home-based renewable energy system you need. To achieve maximum energy efficiency, you should take a whole-building approach. View your home as an energy system with interrelated parts, all of which work synergistically to contribute to the efficiency of the system. From the insulation in your home's walls to the light bulbs in its fixtures, there are many ways to make your home more efficient.
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