Villa Åkarp is a positive net energy house being built outside of Malmo, Sweden. The house, brainchild of doctor of building physics, Karin Adalberth, will generate more energy on an annual basis than it consumes by combining energy conservation, energy recovery and energy generation technologies, an amazing feat given that Sweden is hardly known for gratuitous solar energy. Improvising to find a solution, the designer created a partnership with local ‘green’ utility company, E.On, so that the house can purchase energy in the long dark winter months and sell electricity back to the grid during sunny (energy intense) summer months, maintaining a positive net energy ratio with the grid. The project illustrates distributed energy production and individual building energy efficiencies’ potential to revolutionize the energy industry.
The villa uses a variety of strategies to achieve excellent energy performance, but it must be noted that the design is as dependent on time-tested, traditional building, strategies as it is on high-end technological or material solutions. Dr. Adalberth lists eight strategies on the project website: 1) insulation, 2) ventilation with heat recovery, 3) low infiltration, 4) collect heat, 5) collect electricity, 6) guarantee heat generation in the wintertime, 7) install water saving devices and fixtures, 8 ) install electricity efficient devices and systems. You will notice that the project parameters are particular to a Scandinavian climate as it puts the strong emphasis on heating and none cooling. Adapting this project to a more temperate climate would mean changing some of the strategies, but the basic strategies of energy conservation, recovery and generation would still hold true regardless of location.
The integrity of the building envelope is a crucial design element in Villa Akarp. The walls and roof have a total of 5.5 decimeters of insulation with an overall U-value of 0.08 w/m2. Karin notes that in Sweden a badly insulated wall with only 1 decimeter of insulation has a U-value of 0.5 w/m2 and that the difference could save a family 75% in energy costs for a typical house. Roxull mineral wool fiber was used throughout the house, inserted between wood framing members, because of its excellent insulation and fire resistance properties. In addition insulation, a continuous infiltration barrier was installed to prevent energy transfer due to air movement. The result is a well insulated, tight envelope that does not unnecessarily
The continuity of the envelope was maintained well beyond the fundamental wall assembly. Windows and doors were designed to reduce energy transfer and air leakage. The front door uses a vestibule to control the air as occupants enter or leave the dwelling. A special slues system on the door prevents air from exchanging with the exterior. Windows are high U-value triple glazed units which are deployed sparingly to bring in the maximum amount of natural light without compromising the efficiency of the envelope.
The foundation is also well insulated as can be seen in the sketch below. The reinforced concrete slab is insulated by expanded foam insulation to the tune of 4 decimeters below and 2.5 decimeters on the perimeter.
The house is based on the concepts of Passiv Haus and so can generate much of its heating from energy that is already being generated in the house itself. Bodyheat, lighting, refrigerators, computers and many other things generate heat within the house and can go a long way to preconditioning the house before designers need to bring true ‘heating’ systems online to cover the difference. The heating system itself includes an 18 m2 solarthermal collector, an accumulator tank (the heart of the building – a big circle in the first floor plan), and traditional radiators. The solar thermal system both heats the house and (pre)heats the domestic hot water. The 2,000 liter accumulator tank (storage tank) retains enough heat for use during the evening and mornings while a connected fuel pellet heater is used to heat the house’s radiator and domestic hot water during the winter or any other time the solar thermal system cannot meet demand.
A particularly innovative system uses the tempered sanitary lines exiting the house to preheat the incoming water lines to help reduce the amount of energy needed to bring the cold exterior water up to usable temperatures.
32 square meters of solar panels are used to produce energy for the house. Of course, because this is Sweden, the solar panels are used primarly between April and October. The calculated energy balance is 4,000 kwh sold back to the grid and 2,600 kwh purchased annually, leaving a net positive energy balance. The extra energy purchased is ‘green’ so the house also has a minimal carbon footprint.
Villa Åkarp is a terrific example to architects, clients and builders out there about what can be done to increase energy efficiency, improve occupant comfort, and reduce green house gas emissions. The house cost is estimated to be almost $100,000 more than a traditional home, (amount of that costs is going to pay for solar panels), an item that should be seeing significant cost reductions in the future as production becomes more efficient. The basic strategy of using energy conservation, energy recovery and energy generation technologies applies to all buildings. Congratulations to the team and especially Karin Adalberth for challenging the rest of the design community to make better buildings.
– from greenlineblog.com