Solar active houses heat themselves using heat collectors and water tanks. However, no one had conducted an objective assessment of how efficiently they do so. Fraunhofer researchers put some of these solar houses to the test, identified where there was room for improvement and laid the scientific groundwork for this housing concept.
Nine solar houses scientifically monitored
It is this scientific groundwork that has now been completed as part of the “Heizsolar” project, conducted by researchers from the Fraunhofer Institute for Solar Energy Systems ISE in Freiburg, Germany, together with colleagues at Solar- und Wärmetechnik Stuttgart, the Technische Universität Ilmenau and the Sonnenhaus-Institut. “For Heizsolar, we monitored nine Solar-Active-Houses over multiple heating periods,” says Gerhard Stryi-Hipp, group manager at Fraunhofer ISE. “This gave us a foundation from which to optimize the houses and lower costs. We expect this will significantly enhance their importance in the future.” The project was supported by the Forschungszentrum Jülich and received 1.5 million euros in funding from the German Federal Ministries for the Environment, Nature Conservation, Building and Nuclear Safety, and for Economic Affairs and Energy.
So what options do Solar Active Houses offer? In theory, it’s possible to tap enough solar energy to cover a building’s entire heating needs. But 100-percent solar houses are still something of a rarity – they are expensive and require that a significant amount of space be given over to the necessary long-term heat storage unit, which can sometimes be large enough to hold up to 50,000 liters. “Solar Active -Houses which generate around 60 percent of the heat required using solar thermal collectors are a good and affordable compromise,” Stryi-Hipp explains. “During spring and fall, 40 square meters of solar thermal collectors and a 5000-liter tank are fully sufficient for a single-family home. From November through January, the additional 40 percent must come from a gas or wood-fired boiler.”
Up to now, the design of solar houses has relied mainly on the practical experience of individual experts. The researchers therefore decided to explore how to further optimize the Solar Active House and came up with a suitable simulation model to examine various aspects. For example, to what extent can the size of the tank be reduced in order to increase these houses’ popularity? “It’s possible to vary the ratio of tank size to collector surface area: In our 60-percent Solar Active House, we found we could reduce the tank volume from 6000 to 3000 liters as long as we also increased the area of solar heat collectors from 40 to 60 square meters.”
Solar houses still have their share of challenges to overcome. The researchers have concluded that several of these challenges can be easily solved with thorough planning. Take the heat emitted by the storage tank, for example. While this is welcome in winter, in summer no one wants to further heat up an already warm house. “If you install the tank in the stairwell, for instance, the waste heat isn’t wasted during heating season. And if you also install a window through which waste heat can be released, it won’t bother you in the summer,” says Stryi-Hipp. Other challenges call for further research, including how Solar Active Houses stack up against zero-energy or plus-energy houses. These are equipped with photovoltaic elements to generate electricity that is used in part to power heat pumps. The researchers plan to address this topic as part of a follow-up project so they can provide users with reliable assessment criteria.