Solar controller

In the context of solar hot water systems, a solar controller is an electronic device that harvests as much heat from the solar panels as possible and protects the system from overheating. The basic job of the controller is to turn the circulating pump on when there is heat available in the panels, moving the working fluid through the panels to the heat exchanger at the thermal store. Heat is available whenever the temperature of the solar panel is greater than the temperature of the water in the heat exchanger.

Most commercial controllers display the temperature of the hot water in the store and provide general status information about the system, including overall energy production.

The simplest solar controller circuit uses a comparator with two temperature inputs, one at the solar panel and one at the thermal store's heat exchanger, and an output to control the pump. Commercial controllers use a microprocessor usually with a LCD display and simple user interface with a few pushbuttons. Power for the controller and the pump can come from a mains electric supply or from a photovoltaic (PV) module.^{[citation needed]}

Its main function is to control when the solar panel's pump is switched on or off. The pump is usually switched off when the solar panel is colder than the bottom of the water store and it is switched on when the panel is hotter. Switching the pump on allows the heat in the panel to be transferred to the store. Switching it off prevents the export of bought-in energy. Every few seconds, the temperatures in the panel and the store are measured and compared in order to allow this on or off decision to happen.

In addition, certain fine tuning can take place, such as allowing an overrun time to ensure that heat energy is not left lying about underlivered in interconnecting pipes when the pump is turned from on to off. Another fine tuning is that of the on differential (which may be say 4-15 degrees Celsius) and the off differential which is usually a few degrees lower. The wider the difference between these differentials, the fewer pump on-off cycles will take place. These factors are usually set by the solar installer in relation to the particular installation. The controller may also control certain safety features such as by permitting heat export when the hot water exceed a preset temperature such as 65^oC. This is a process of allowing the solar panel to export excess heat if it is not being used when the panel is cool, when light levels fall towards the end of a sunny day and is used in a range of solar thermal technnologies such as solartwin.

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A photovoltaic (PV) powered solar controller uses solar electricity produced on-site to run the pump that delivers the solar-heated transfer fluid to the hot water store.

One claimed advantage of PV power is that it reduces the overall carbon emissions associated with operating the system since it avoids the need to supply this energy from fossil sources.^{[citation needed]} However, the energy required to operate the system is very small in comparison to the energy produced by the system and the carbon emissions reduction of adding PV power fractional.^{[citation needed]}

The most practical benefit of a PV powered controller is the resultant simplicity of the overall system. Rather than using complex algorithms based on store and panel temperatures, the pump is driven directly by the PV panel: when the sun shines, the pump runs. In practice this is as efficient a practical control algorithm as most others achieve and has obvious advantages for reduced system complexity.^{[original research?]}

A disadvantage to the PV powered approach is that the pump stops immediately after the sun is occluded. With vacuum tube and heat pipe solar panels, these can have an appreciable amount of energy stored in each tube at the moment the sun goes in. To avoid overheating the tubes it is necessary to either pump their circuits for a short time after the sun, or else to provide a large reservoir of fluid in the header tank above the panel. Neither of these options is really compatible with the simple direct-PV pump approach and so such systems are limited to using the less efficient flat panel collectors.^{[citation needed]}

A PV powered controller may contain a small electricity store to allow the controller to remain powered and display temperatures at night when there is no sunlight. This electricity store is usually in the form of supercapacitors, since these have a much longer life than batteries.^{[citation needed]}

The benefits of a PV powered solar controller comes at a cost in reduced system performance in the range of 1-10%.^[1] This is due to heat losses at times when the panel may be hotter than the water store but there is insufficient sunlight to power the pump. This happens mainly on hot days when hot water is likely to be in excess so the potential reduction is less significant than it would be at times when the store was cooler.^{[original research?]}

Currently (2007) PV powered controllers are a minor sub-technology within a minor technology; it is however possible that the global solar thermal industry will start to adopt PV powered controllers more widely in the future.^{[original research?]} This may happen if the terms of reference of solar thermal start to turn away from maximising component efficiency, which is usually regarded as efficiency per square metre of panel, and moves towards system sustainability.^{[original research?]} System sustainability may be assessed in a variety of terms, for example, operational carbon input/output ratio. This ratio is zero for a range of zero carbon solar technologies such as PV pumped solar, thermosiphon solar and integrated collector and store solar systems.^{[original research?]}

• Solar Twin Ltd (2007). "Request for EN 12975 solar thermal panel standard to be re-examined on the grounds that its durability test is no longer inclusive enough to facilitate a thriving innovative solar thermal market in Europe and the world." (PDF). Solar Twin Ltd. Retrieved on 2007-08-04.
• Martin C, Watson M (2002). "Further Testing of Solar Water Heating Systems" (PDF). United Kingdom Department of Trade and Industry. Retrieved on 2007-08-04.

• Solar cell phone charger
• Solar notebook
• Solar powered calculator
• Solar powered fountain
• Solar powered radio
• Solar powered flashlight
• Solar fan
• Solar street light

• The Solar Trade Association