FAQs and Facts about solar energy
1. How do solar cells generate electricity? Answer: Photovoltaic or PV for short can be thought of as a direct current (DC) generator powered by the sun. When light photons of sufficient energy strike a solar cell, they knock electrons free in the silicon crystal structure forcing them through an external circuit (battery or direct DC load), and then returning them to the other side of the solar cell to start the process all over again. The voltage output from a single crystalline solar cell is about 0.5V with an amperage output that is directly proportional to cell's surface area (approximately 7A for a 150mm square multicrystalline solar cell). Typically 30-36 cells are wired in series (+ to -) in each solar module. This produces a solar module with a 12V nominal output (~17V at peak power) that can then be wired in series and/or parallel with other solar modules to form a complete solar array to charge a 12, 24 or 48 volt battery bank. 2. Grid-Tie Kits Answer: RMV Solar also offers pre-assembled Grid-Tie kits. Our popular systems have been installed by several of our customers with a great deal of success. This kit comes with all of the equipment you'd need, including product/installation manuals, mounting rails, and clamps for your panels. 3. What components do I need for a grid-tie system? Answer: Grid-tie systems are inherently simpler than either grid-tie with battery back-up or stand-alone solar systems. In fact, other than safety disconnects, mounting structures and wiring a grid-tie system is just solar modules and a grid-tie inverter! Today's sophisticated grid-tie inverters incorporate most of the components needed to convert the direct current form the modules to alternating current, track the maximum power point of the modules to operate the system at peak efficiencies and terminate the grid connection if grid power is interrupted from the utility. 4. What components do I need for a grid-tie system with battery back-up or OFF-grid? Answer: There are many components that make up a complete solar system, but the 4 main items are: solar modules, charge controller(s), batteries and inverter(s). The solar modules are physically mounted on a mount structure (see question 7) and the DC power they produce is wired through a charge controller before it goes on to the battery bank where it is stored. The two main functions of a charge controller are to prevent the battery from being overcharged and eliminate any reverse current flow from the batteries back to the solar modules at night. The battery bank stores the energy produced by the solar array during the day for use at any time of day or night. Batteries come in many sizes and grades. The inverter takes the DC energy stored in the battery bank and inverts it to 220 VAC to run your AC appliances. 5. Will solar work in my location? Answer: Solar is universal and will work virtually anywhere, however some locations are better than others. Irradiance is a measure of the sun's power available at the surface of the earth and it averages about 1000 watts per square meter. With typical crystalline solar cell efficiencies around 14-16%, that means we can expect to generate about 140-160W per square meter of solar cells placed in full sun. Insolation is a measure of the available energy from the sun and is expressed in terms of "full sun hours" (i.e. 4 full sun hours = 4 hours of sunlight at an irradiance level of 1000 watts per square meter). Obviously different parts of the world receive more sunlight from others, so they will have more "full sun hours" per day. 6. How can I find out the average sunlight hours I get where I live? Answer: Your average sunlight hours are fairly consistent based on where you live. (Click here to see map.) 7. How much will a system cost for my 2000 square foot home? Answer: Unfortunately there is no per square metre "average" since the cost of a system actually depends on your daily energy usage and how many full sun hours you receive per day in your area; and if you have other sources of electricity. To accurately size a system to meet your needs, we need to know how much energy you use, your costs of electricity usage, and the average peak sun hours in your area. The cost of the system will depend on the percentage of electricity you hope to gain for your energy needs. If your home is connected to the eskom grid, simply look at your monthly electric bill, and then call to speak to an Agent in your area. We're here to help you 'electrify a sustainable world!' 8. What is the cost? Answer: The cost varies, but you can estimate it with relative ease; all you need to know is what equipment you need and the labour cost. We've gone over the basic parts you'll need for your solar power array: the solar panels, a GFCI, a solar array breaker, an inverter, a grid disconnect, and an optional rail system. If you don't want to fuss with purchasing each of these components individually, you might be interested in purchasing a Solar Grid-Tie Kit. 9. Which type of system is right for me? Answer: The type of system you might want for your home or business depends on a number of variables, including geographic location, the amount of energy you need to produce, and the size of the investment you plan on making. For a better understanding of both off-grid and grid-tie systems, check out the guide. 10. What are the labour costs? Answer: Most solar power systems are assembled by the people who buy them. If you're uncomfortable installing a system, Affordable Solar can suggest a PV installer who can help with building your solar power system. Another consideration for labour costs: even if you're comfortable assembling your solar power system, we highly recommend consulting or hiring an electrician to connect your system to your AC system. 11. What's the bottom line? Answer: The GTS 3600 Watt system above sells for approximately R196,636.00. Shipping is approximately R4.538.00 to any location in South Africa. If you don't have a pitched roof (or would like to mount panels on the ground), UniRac tilt legs cost an additional R8,319.00. For installing a 3,600 watt system, you could expect an installation fee of R43,108.00 - R49,159.00. (Installation, if you choose to go that route, can generally be estimated at about R13.24/watt.) So for this system you could reasonably estimate the equipment and installation at about R245,795.00. 12. What's my incentive to invest in a solar power system? Answer: Most people associate solar energy with remote installations and off-grid implementations. In those cases the choice may be an easy one, but in towns and cities there are still reasons to turn to solar energy as a supplement and alternative to electrical utility grids. The best reason is the reduction in utility bills. Once your system is working, it requires no monthly fees and little or no maintenance (and most parts are warranted). While it runs, it also reduces your electrical bills. Eventually it will pay for itself and keep saving you money. Large systems may even make you money by giving you perpetual credit with your local electricity company. Not only is your investment going to save you money and pay for itself, but solar installations frequently raise property value in both industrial and residential settings. Adding a solar energy system to your home or business will also supplement the investment you've made in your property. Another great incentive--Eskom offer rebates and incentives for implementing solar power systems. Check out the Eskom which lists incentives. Finally, solar energy is a clean source of renewable energy. It reduces dependence on fossil fuels in a practical and effective way, and helps keep our environment clean. 13. But where do I begin? Answer: Getting started might seem like a daunting task, but it's not as complicated as it first seems. With only an electrical bill, you can determine the minimum system size you'll need. Once you've determined that, you can determine how many solar panels you'll need, and find compatible components from there. To begin, you'll need the average monthly electrical use--which you should be able to find on your electricity bill. This number will be in kWh (kilowatt-hours). (Click here to see example of electricity bill.) You can: 1.) Request a Quote and one of our Agents will call you to discuss an appropriate solution for your energy needs. 2.) Our System Sizing Estimator, which uses the formula below to determine a system for you. Will be returned to you. 3.) Fill out the formula below, which we use to help determine a system for you. Or you can just call one of our Agents in your area, who will be happy to help you. Below is a formula to help calculate the type of energy you hope to gain utilizing solar energy. Fill it out then call one of our Agents who will help you determine the type of system that will suit your needs and answer any questions you may have. Record average monthly kWh electrical use: __________kWH Multiply line 1 by the percentage you want the solar system to produce: __________kWH i.e.: 1000kWH X 50% = 500kWH Divide by 30 for the daily output from your solar power system: __________kW Divide by the daily average sun hours for your location: __________kW 6 in Sun Belt, 4in NE / NW Divide by 70% to compensate for system efficiency: __________kW 14. Can I use all of my normal 220 VAC appliances? Maybe. Answer: Many older homes were not designed or built with energy efficiency in mind. When you purchase and install a renewable energy system for your home, you become your own power company so every kWh of energy you use means more equipment (and hence more money) is required to meet your energy needs. Any appliances that operate at 220 VAC (such as electric water heaters, cook-stoves, furnaces and air conditioners) are impractical loads to run on solar. You should consider using alternatives such as LP or natural gas for water/space heating or cooking; evaporative cooling instead of compressor based AC units; and passive solar, versus active solar, design in your new home construction, if possible. Refrigeration and lighting are typically the largest 220 VAC energy consumers in a home (after electric heating loads) and these two areas should be looked at very carefully in terms of getting the most energy efficient units available. Great strides have been made in the past 5 years towards improving the efficiency of electric refrigerators/freezers. Compact fluorescent lights use a quarter to a third of the power of an incandescent light for the same lumen output and they last ten times longer. These fluorescent lights are now readily available at your local hardware or discount store. The rule of thumb in the renewable energy industry is that for every rand you spend replacing your inefficient appliances; you will save three rand in the cost of a renewable energy system to run them. So, you can see that energy conservation is crucial and can really pay off when considering a renewable energy system. 15. What type of solar module mounting structure should I use? Answer: There are four basic types of mount structures: roof, ground, top-of-pole, side-of-pole and tracking mounts, each having their own pros and cons. Roof mount structures typically keep the wire run distances between the solar array and battery bank to a minimum, which is good. But they also require roof penetrations in multiple locations (a potential source of leakage) and they require an expensive ground fault protection (GFP- device to satisfy article 690-5 of the National Electrical Code- NEC). On the other hand, ground mounted solar arrays require fairly precise foundation setup, are more susceptible to theft at the bottom of the array. Top-of-pole mounts which are relatively easy to install (you sink a 2-6 inch diameter SCH40 steel pipe up to 4-6 feet in the ground with concrete). Make sure that the pole is plumb and mount the solar modules and rack on top of the pole. Top-of-pole mounts reduce the risk of theft (as compared to a ground mount). They are also a better choice for cold climates because snow slides off easily. Side of pole mounts are easy to install, but are typically used for small numbers of solar modules (1-4) for remote lighting systems where there already is an existing pole to attach them to. Last but not least are the trackers, which increase the daily number of full sun hours and are used for solar water pumping applications. Trackers are extremely effective in the summer time when water is needed the most, typical home energy usage peaks in the winter where a tracker mount makes very little difference as compared to any type of fixed mount (roof, ground or top-of-pole). In this situation, having more modules on a less expensive fixed mount will serve you better in the winter than fewer modules on a tracker. However, your energy usage peaks in the summer, then a tracker may be beneficial to match the time of your highest energy consumption with a tracking solar array's maximum energy output. 16. Where should I mount the solar modules and what direction should I face them? Answer: If your site is in the Southern Hemisphere you need to aim your solar modules to the true north direction (the reverse is true for locations in the Northern Hemisphere) to maximize your daily energy output. For many locations there is quite a difference between magnetic south and true south, so please consult a declination map before you setup your mount structure. The solar modules should be tilted up from horizontal to get a better angle at the sun and help keep the modules clean by shedding rain. For best year round power output with the least amount of maintenance, you should set the solar array facing true north at a tilt angle equal to your latitude with respect to the horizontal position. If you plan to adjust your solar array tilt angle seasonally, a good rule of thumb to go by is latitude minus 15° in the summer, latitude in the spring/autum and latitude plus 15° in the winter. Most mount structures provide for a seasonal adjustment of the tilt angle from horizontal to 65°. To determine if your proposed array site will be shaded at any time of the day or year you should consider using a Solar Pathfinder 17. Should I set my system's battery bank up at 12, 24 or 48 VDC? Answer: The PV industry really began with the 12V recreational vehicle market. These systems were typically small (1-2 solar modules) and had all 12 VDC loads. As the solar industry matured and entered the home market, systems became much larger (16+ solar modules) and no longer used DC loads exclusively. Most home systems today are 24 or 48 VDC since the higher system voltage gives you a lot more flexibility as to how far away you can place your solar modules from the battery bank as compared to a 12V system. For a given power output, a higher system voltage reduces your amperage flow (but not your power) which allows you to use a smaller and less expensive gauge wire for your solar to battery and battery to inverter wire runs. Of course, if you already have a lot of 12VDC loads, that may be your deciding factor as to what voltage you set your system up at. Most grid-tied systems operate at 48 volts or higher. 18. Should I wire my home for AC or DC loads? It depends on the size of the system and what type of loads you want to run. DC appliances are usually more efficient than AC since you don't have to worry about the loss of power through the inverter, but DC loads are typically more expensive and harder to find than their AC counterparts. Small cabin and RV systems are typically wired DC while most home systems are wired for AC loads, exclusively. With improvements in inverter efficiency and reliability over the years, AC is the way to go for a home system. Another advantage AC has over DC is that the voltage drop for a 220VAC circuit is much less than a 12VDC circuit carrying the same power, which allows you to use smaller gauge wire. 19. Can I use PV to heat water or for space heating No. Answer: Photovoltaic converts the sun's energy into DC electricity at a relatively low efficiency level (14-16%), so trying to operate a high power electric heating element from PV would be very inefficient and expensive. Solar thermal (or passive solar) is the direct heating of air or water from the heat of the sun and is much more efficient for heating applications than photovoltaic. 20. What sort of Eskom Incentives am I eligible for? Answer: Based on the type and size of your system, you may be eligible for special energy rebates, which can help buy and improve your solar energy system. rebates and incentives, unlike the state incentives, are the same all across the country and are dependent on your particular system. For a list of qualifications and exemptions, click here. 21. Should I consider a hybrid system over a conventional solar grid-tie system? Answer: Hybrid systems can be more inexpensive than solar grid-tie systems. These systems, however, may not be efficient where you live. Wind systems require certain climate conditions, and wind generators tend to have many movable parts, which only increase the need for maintenance. 22. What sort of back-ups work best for an off-grid system? Answer: There are several kinds of back-ups, each of which works fairly well. Petrol and diesel generators are fairly cost-effective, but tend to be loud, vibrate and give off fumes. Wind generators work when there is no sun, but are like-wise constrained by the weather. For a more detailed comparison of back-ups, visit the battery basics page. |