Solar pool heating systems are one of the most cost efficient uses of solar thermal technology. The cost of heating the average residential pool using a gas or electric heater is approximately $2,000 per year, according to the US Department of Energy. The cost of the average solar pool heating system is between $2,000 and $4,000. Although solar pool heating systems are exempt from federal and most state incentives and rebates, the payback period is usually between one to two years. After the payback period, owners of solar pool heating systems can enjoy their solar heated pool for free!

Solar pool heating systems work much the same way as drainback solar domestic hot water systems. In the collector loop, the pool water is heated in the solar collectors. The pool pump will be turned on and the flow of the pool water will go through the panels when the collector temperature is greater than the measured pool temperature. A pool heating system generally doesn’t include a heat exchanger. When the pool panels are no longer hotter than the pool (or the maximum desired temperature is reached) the flow is no longer directed through the panels. The panels (with the assistance of a vacuum breaker) would then drain the fluid back into the pool. If a certain temperature is required then a back-up heater would be installed after the pool panels prior to the heated water reentering the pool.
If your home already is already utilizing a closed loop solar domestic hot water system, you may be able to integrate a solar pool heating system. A valve would be installed on the glycol mixture’s return line. This valve would be able to divert the heated glycol mixture to a second heat exchanger to heat pool water. A sensor and controller would be required to prioritize the two loads. The domestic hot water system would receive first priority. The heated glycol mixture would be diverted to the pool heating system, the second priority, only after the required temperature of the domestic hot water system had been met.
The above integration of a solar pool heating system into an existing http://www.solarhotusa.com/index.html may not be employed in an open loop system.

Solar water heating systems almost always require some kind of thermal storage for solar heated water. Tanks used in solar water heating systems are available in two basic types: pressurized and atmospheric.

Pressurized tanks, constructed of stainless steel or welded steel with a baked-on glass liner, are made to withstand city water pressure without rupturing. Polyurethane foam insulation is used in between the metal skin and interior tank to minimize heat loss. Pressure relief valves are included in the design of pressurized tanks. If the pressure builds up too high inside the tank, the relief valve opens and water is released. Pressurized tanks range from about $500 for an 80 gallon capacity to about $17,000 for a 1,000 gallon capacity. The life span of a pressurized tank around 13 years but can vary depending on local water conditions and tank maintenance (changing the anode rods regularly).

Atmospheric tanks are basically just non-pressurized containers to hold solar heated water. Since they are not completely sealed from the surrounding atmosphere, they should be well insulated. An atmospheric tank that is filled beyond its capacity will overflow. In addition, atmospheric tanks will lose water through evaporation. A variety of materials are used in the construction of atmospheric and include stainless steel, EPDM lined steel, EPDM lined wood, polypropylene and fiberglass. Tank costs and longevity vary with material selection.

A two tank solar water heating system consists of a solar storage tank (it can be atmospheric or pressurized) and a pressurized backup tank. A one tank solar water heating system uses a pressurized tank which serves both as the solar storage tank and the backup water heater.

Simply stated, when using an atmospheric solar storage tank in your design, heat from the collectors is delivered first to the atmospheric tank, then on to the pressurized tank. When no atmospheric tank is used in the
design, with only a pressurized tank, the solar heat can be sent directly to the one pressurized tank.

Should you incorporate an atmospheric solar storage tank in your solar thermal design? Your solar equipment manufacturer should be able to help you decide what is best for your individual needs. However, if your tank capacity needs to be over 240 gallons, it may make sense to include an atmospheric tank for economic reasons.

See upcoming blog article for more information regarding atmospheric tanks.

While solar site evaluation tools determine the best location for the solar collectors used in a solar heating or photovoltaic installation, solar simulation software provides the software tools to help design and simulate a solar energy installation and facilitates the design making process.

Three leading companies that offer solar simulation software packages to those in the renewable energy fields are RETScreen International, Vela Solaris AG and Valentin Energy Software.

At the onset of a new renewable energy project, each one of the three companies’ software package allows the user to input information regarding the site’s location and define the energy requirements for the project. The user may then select a template or configuration from the software’s database, and in addition, may select specific commercially available products to be used. The software will generate the simulation evaluation which will include financial feasibility and potential cost savings, calculation of weather data, energy production, expected energy savings and emission reductions of the project.

RETScreen International developed their Clean Energy Project Analysis Software with the input of experts from government, industry and academia from around the world. RETscreen is applicable to various categories of renewable energy, not just solar energy. The software consists of a series of worksheets to be filled in by the user, along with a comprehensive database that is the largest and most detailed of the three software packages. The user may omit any of the worksheets that do not apply to their project. It is suitable for large commercial and governmental projects, although it may also be used with smaller residential undertakings. RETscreen software may be downloaded free from their website.

Polysun Simulation Software was developed by Vela Solaris AG, a Swiss corporation. Polysun Simulation Software is a set of four software programs specifically created for the design of heat pumps, solar thermal, photovoltaic and cooling systems. Each software program is available separately or as a complete set of four. In addition, each program is offered in three user levels, light, professional and designer. The evaluation process provides detailed reports in PDF format, including colorful graphics, and is a significant feature of this software. A Polysun demo copy may be downloaded for examination on the Vela Solaris AG website. Polysun is also available for purchase on the site.

Valentin Energy Software, based in Berlin, Germany, offers two solar energy simulation programs. Their T’SOL software was conceived for solar thermal energy systems, while their PV’SOL is for used in the design of solar photovoltaic systems. Both programs are also available in three user levels, express, professional and expert. The company’s Meteonorm software, a global climate data database, is also available separately. Customized versions of T’SOL and PV’SOL may also be developed by Valentin for individual user objectives. Valentin Energy Software may be purchased through distributors or online on the company website.

What one of these is the best solar simulation software package? Our suggestion is to download the free copy of RETscreen and try it out. If RETscreen does not meet the needs of your applications, then download the demo copy of Polysun and determine if this software is a better choice for your company. In our evaluation of the T*Sol product we found that it didn’t compete effectively with the Polysun for a number of reasons. Most notably was the lack of SRCC certified collectors and standard U.S. components. If RETscreen or Polysun does not provide the requirements that you need, perhaps your company should consider a customized version of Polysun, T’SOL or PV’SOL.

Although the main objective of each of these software packages is to facilitate in the design process, the professional looking reports generated by them will also assist solar energy companies in the marketing of their products to potential customers.

Everyone that has looked into the details is impressed with the relative economic value of a solar water heating system compared with any other renewable energy source. Even if a potential customer is impressed with the economics of solar heating it doesn’t mean that they can necessarily pay for it. Many potential customers don’t have access to the cash so discussions of tax incentives and rebates fall on deaf ears if they don’t have the money up front.

One of the missing pieces in the solar heating equation has been the financing. This has been a hurdle at both the residential and commercial level. I am aware of a number of banks that offer different systems but one that came to mind recently that I thought had some merit was www.sameascashloans.com . The premise is that you can offer your customers a solar system and they can defer the first payment for anywhere between 3, 6, 12, or 18 months. This way the customer doesn’t have to be cash out of pocket until they are realizing the tax savings.

On the commercial side it is a little more like standard financing but the availability of financing makes this a strong option for growing your solar heating business.

With the cost of conventional energy ever increasing, consumers are becoming more interested in the use of solar energy. But which solar energy technology makes the most sense for the average consumer, solar heating or solar electric?

A solar heating system generally consists of solar collectors, a water storage tank, a pump and automatic controls. The estimated cost of a hot water solar heating system for a typical single family home is between $4,000 and $8,000, including installation. The system will replace approximately 80% of the energy used by a conventional hot water system, and represents a cost savings of $500 to $600 a year. The payback will average between 5 to 7 years after tax credits, meaning that after 5 to 7 years the total cost savings will have paid for the initial cash investment.

The components of a solar electric system are the photovoltaic solar collectors, an inverter, a charge controller and batteries. The projected cost of a grid-tied solar electric system for the same typical single family home is from $25,000 to $35,000 and will supply approximately 20-25% of the electricity usage of the home. The yearly savings would be between $500 and $600. The payback of the system is estimated at 15 to 25 years.

The initial costs of both of the solar hot water heating system and the solar electric system may be reduced by federal tax credits and state tax incentives. The cost savings per year and payback time for both systems will vary depending on the exact costs of the system components, actual current energy costs and future increases in energy costs.

Neither system is 100% efficient, since energy is lost due to conversion processes. Solar hot water heating systems are considered to be between 35% and 50% efficient, compared to solar electric systems which are 4% to 13% efficient.

In our opinion, because of the lesser initial expenditure, the quicker return of the investment and the higher rate of efficiency, the solar hot water heating system is the better, more cost effective choice.

When a customer has a solar heating system installed in their home they expect (and rightfully so) that their energy bill will drop pretty significantly. When a customer doesn’t see as much of a drop as they expect the question is why. One of the things that I encourage solar contractors to do is calibrate the expectations of their customers. Let them know what they should expect from their system. The best way to do that is to provide a simulation report . With this tool they can easily see what to expect from the system. Things keeps everybody on the same page about what the system should be producing.