Passive house (German: Passivhaus) is a voluntary standard for energy efficiency in a building, which reduces the building's ecological footprint. It results in ultra-low energy buildings that require little energy for space heating or cooling. A similar standard, MINERGIE-P, is used in Switzerland. The standard is not confined to residential properties; several office buildings, schools, kindergartens and a supermarket have also been constructed to the standard. Passive design is not an attachment or supplement to architectural design, but a design process that integrates with architectural design. Although it is principally applied to new buildings, it has also been used for refurbishments.
By late 2008, estimates of the number of Passivhaus buildings around the world ranged from 15,000 to 20,000 structures. As of August 2010, there were approximately 25,000 such certified structures of all types in Europe. The vast majority of passive structures have been built in German-speaking countries and Scandinavia.
- 1 History
- 2 Standards
- 3 Construction costs
- 4 Design and construction
- 5 Traits of passive houses
- 6 International comparisons
- 7 Comparison with zero energy buildings
- 8 Tropical climate needs
- 9 See also
- 10 References
- 11 Further reading
- 12 External links
The Passivhaus standard originated from a conversation in May 1988 between Bo Adamson of Lund University, Sweden, and Wolfgang Feist of the Institut für Wohnen und Umwelt (Institute for Housing and the Environment, Darmstadt, Germany). Later, their concept was further developed through a number of research projects, aided by financial assistance from the German state of Hessen.
Much of the early 'Passive Houses' were based on research and the experience of North American builders during the 1970s, who—in response to the oil embargo—sought to build homes that used very little or no energy. These designs often utilized the sun as a heat source and the term 'passive house' was possibly derived from the passive solar features of these houses, such as the Saskatchewan Conservation House and the Leger House in Pepperell, Massachusetts. An early book explaining the concepts was The Passive Solar Energy Book by Edward Mazria in 1979.
The eventual construction of four row houses (terraced houses or town homes) was designed for four private clients by the architectural firm Bott, Ridder and Westermeyer. The first Passivhaus residences were built in Darmstadt in 1990, and occupied by the clients the following year.
Further implementation and councils
In September 1996, the Passivhaus-Institut was founded in Darmstadt to promote and control Passivhaus standards. As of 2010 an estimated 25,000+ Passivhaus structures have been built. Most are located in Germany and Austria, others in various countries worldwide.
In 1996, after the concept had been validated at the Institute in Darmstadt, with space heating at 90% less than that required for a standard new building at the time, the Economical Passive Houses Working Group was created. This group developed the planning package and initiated the production of the innovative components that had been used, notably the windows and the high-efficiency ventilation systems. Meanwhile, further passive houses were built in Stuttgart (1993), Naumburg, Hesse, Wiesbaden, and Cologne (1997).
Products, which had been developed for the Passivhaus standard were further commercialized during and following the European Union sponsored CEPHEUS project, which proved the concept in five European countries in the winter of 2000–2001. The first to be certified was built in 2006 near Bemidji, Minnesota in Camp Waldsee of the German Concordia Language Villages. The first US passive retrofit project, the remodeled craftsman O'Neill house in Sonoma, California  was certified in July 2010.
In the United States, the concept of passive design was first implemented by Katrin Klingenberg in 2003 when she built a passive home prototype named "The Smith House" in Urbana, Illinois. From here, she and builder Mike Kernagis co-founded the e-cological Construction Laboratory (e-colab) in 2004 to further explore the feasibility of affordable passive design. This eventually lead to the inception of the Passive House Institute United States (PHIUS) in 2007. Since then, the PHIUS has released their PHIUS + 2015 Building Standard and has certified over 1,200 projects and 1.1 million square feet (100,000 m2) across the United States. In 2019, Park Avenue Green, a low-income housing building in New York, became the largest certified Passive House in North America.
The world's first standardised passive prefabricated house was built in Ireland in 2005 by Scandinavian Homes, a Swedish company, that has since built more passive houses in England and Poland.
The first certified passive house in the Antwerpen region of Belgium was built in 2010. In 2011 the city of Heidelberg in Germany initiated the Bahnstadt project, which was seen as the world's largest passive house building area. A company in Qatar was planning the country's first Passive House in 2013, the first in the region.
The world's tallest passive-house is located in the Bolueta neighborhood in Bilbao, Spain. At 289 feet (88 m), it is the world's tallest building certified under the standard in 2018. The $14.5 million, 171-unit development (including a nine-story companion to the high-rise) consists entirely of social housing.
Gaobeidian, China hosted the 23rd International Passive House Conference in 2019, and is home to Gaobeidian Railway City apartment complex is the world's largest passive house project. China is taking a leadership role in passive house construction, with "73 different companies making windows to Passive House standards."
While some techniques and technologies were specifically developed for the Passive House standard, others, such as superinsulation, already existed, and the concept of passive solar building design dates back to antiquity. There was other previous experience with low-energy building standards, notably the German Niedrigenergiehaus (low-energy house) standard, as well as from buildings constructed to the demanding energy codes of Sweden and Denmark.
International Passivhaus Standard
- Use up to 15 kWh/m2 (4,755 BTU/sq ft; 5.017 MJ/sq ft) per year for heating and cooling as calculated by the Passivhaus Planning Package, or a peak heat load of 10 W/m2 (1.2 hp/1000 sq ft), based on local climate data.
- Use up to 60 kWh/m2 (19,020 BTU/sq ft; 20.07 MJ/sq ft) per year primary energy (for heating, hot water and electricity).
- Leak air up to 0.6 times the house volume per hour (n50 ≤ 0.6 / hour) at 50 Pa (0.0073 psi) as tested by a blower door; or up to 0.05 cubic feet per minute (1.4 l/min) per square foot of the surface area of the enclosure.
These standards are much higher than houses built to most normal building codes. For comparisons, see the international comparisons section below.
National partners within the 'consortium for the Promotion of European Passive Houses' are thought to have some flexibility to adapt these limits locally.
Space heating requirement
If a building meets the Passivhaus standards, it does not need conventional heating systems, though some heating will still be required and most Passivhaus buildings include supplemental space heating. This is normally distributed through the low-volume heat recovery ventilation system that is required to maintain air quality, rather than by a conventional hydronic or high-volume forced-air heating system, as described in the space heating section below.
Passive House Institute US Standard
The PHIUS + 2015 Standard primarily focuses on reducing negative effects of building operations, for any type of building. This standard also uses climate data sets to determine specific building performance criteria for different regions. Such information is determined using metrics that represent a space where significant carbon and energy reduction overlap with cost-effectiveness. Overall, the PHIUS database includes more than 1000 climate data sets for North America. The Institute believes that this approach to the Standard is essential, as North America has variety of different climates and different passive measures may be more effective than others.
The standard is based on five principles: airtightness, ventilation, waterproofing, heating and cooling, and electrical loads. Within these principles, projects must pass building specified blower door, ventilation airflow, overall airflow, and electrical load tests; buildings must also achieve other measures such as low-emission materials, renewable energy systems, moisture control, outdoor ventilation, and energy efficient ventilation and space conditioning equipment. All buildings must also pass a quality assurance and quality control test - this is implemented to ensure that the building continues to adhere to the regional criteria set forth by the PHIUS’ climate data. These tests and analyses of operative conditions are performed by PHIUS raters or verifiers. These are accredited professionals from the PHIUS that are able to perform on-site testing and inspections to ensure that the newly constructed building is adhering to the construction plans, created energy models, and desired operating conditions.
In Passivhaus buildings, the cost savings from dispensing with the conventional heating system can be used to fund the upgrade of the building envelope and the heat recovery ventilation system. With careful design and increasing competition in the supply of the specifically designed Passivhaus building products, in Germany it is now possible to construct buildings for the same cost as those built to normal German building standards, as was done with the Passivhaus apartments at Vauban, Freiburg. On average passive houses are reported to be more expensive upfront than conventional buildings – 5% to 8% in Germany, 8% to 10% in UK and 5% to 10% in USA.
Evaluations have indicated that while it is technically possible, the costs of meeting the Passivhaus standard increase significantly when building in Northern Europe above 60° latitude. European cities at approximately 60° include Helsinki in Finland and Bergen in Norway. London is at 51°; Moscow is at 55°.
Design and construction
Achieving the major decrease in heating energy consumption required by the standard involves a shift in approach to building design and construction. Design may be assisted by use of the 'Passivhaus Planning Package' (PHPP), which uses specifically designed computer simulations.
Below are the techniques used to achieve the standard.
Passive solar design and landscape
Passive solar building design and energy-efficient landscaping support the Passive house energy conservation and can integrate them into a neighborhood and environment. Following passive solar building techniques, where possible buildings are compact in shape to reduce their surface area, with principal windows oriented towards the equator - south in the northern hemisphere and north in the southern hemisphere - to maximize passive solar gain. However, the use of solar gain, especially in temperate climate regions, is secondary to minimizing the overall house energy requirements. In climates and regions needing to reduce excessive summer passive solar heat gain, whether from direct or reflected sources, brise soleil, trees, attached pergolas with vines, vertical gardens, green roofs, and other techniques are implemented.
Passive houses can be constructed from dense or lightweight materials, but some internal thermal mass is normally incorporated to reduce summer peak temperatures, maintain stable winter temperatures, and prevent possible overheating in spring or autumn before the higher sun angle "shades" mid-day wall exposure and window penetration. Exterior wall color, when the surface allows choice, for reflection or absorption insolation qualities depends on the predominant year-round ambient outdoor temperature. The use of deciduous trees and wall trellised or self attaching vines can assist in climates not at the temperature extremes.
Passivhaus buildings employ superinsulation to significantly reduce the heat transfer through the walls, roof and floor compared to conventional buildings. A wide range of thermal insulation materials can be used to provide the required high R-values (low U-values, typically in the 0.10 to 0.15 W/(m²·K) range). Special attention is given to eliminating thermal bridges.
A disadvantage resulting from the thickness of wall insulation required is that, unless the external dimensions of the building can be enlarged to compensate, the internal floor area of the building may be less compared to traditional construction.
In Sweden, to achieve passive house standards, the insulation thickness would be 33.5 centimetres (13.2 in) (0.10 W/(m²·K)) and the roof 50 centimetres (20 in) (U-value 0.066 W/(m²·K)).
Advanced window technology
To meet the requirements of the Passivhaus standard, windows are manufactured with exceptionally high R-values (low U-values, typically 0.85 to 0.70 W/(m²·K) for the entire window including the frame). These normally combine triple-pane insulated glazing (with a good solar heat-gain coefficient, low-emissivity coatings, sealed argon or krypton gas filled inter-pane voids, and 'warm edge' insulating glass spacers) with air-seals and specially developed thermal break window frames.
Building envelopes under the Passivhaus standard are required to be extremely airtight compared to conventional construction. They are required to meet either 0.60 ACH50 (air changes per hour at 50 pascals) based on the building's volume, or 0.05 CFM50/sf (cubic feet per minute at 50 pascals, per square foot of building enclosure surface area). In order to achieve these metrics, recommended best practice is to test the building air barrier enclosure with a blower door at mid-construction if possible.
Passive house is designed so that most of the air exchange with exterior is done by controlled ventilation through a heat-exchanger in order to minimize heat loss (or gain, depending on climate), so uncontrolled air leaks are best avoided. Another reason is the passive house standard makes extensive use of insulation which usually requires a careful management of moisture and dew points. This is achieved through air barriers, careful sealing of every construction joint in the building envelope, and sealing of all service penetrations.
Use of passive natural ventilation is an integral component of passive house design where ambient temperature is conducive — either by singular or cross ventilation, by a simple opening or enhanced by the stack effect from smaller ingress with larger egress windows and/or clerestory-operable skylight.
When ambient climate is not conducive, mechanical heat recovery ventilation systems, with a heat recovery rate of over 80% and high-efficiency electronically commutated motors (ECM), are employed to maintain air quality, and to recover sufficient heat to dispense with a conventional central heating system. Since passively designed buildings are essentially air-tight, the rate of air change can be optimized and carefully controlled at about 0.4 air changes per hour. All ventilation ducts are insulated and sealed against leakage.
Some Passivhaus builders promote the use of earth warming tubes. These are typically around 200 millimetres (7.9 in) in diameter, 40 metres (130 ft) long at a depth of about 1.5 metres (4.9 ft). These are buried in the soil to act as earth-to-air heat exchangers and pre-heat (or pre-cool) the intake air for the ventilation system. In cold weather, the warmed air also prevents ice formation in the heat recovery system's heat exchanger. Concerns about this technique have arisen in some climates due to problems with condensation and mold.
Alternatively, an earth to air heat exchanger can use a liquid circuit instead of an air circuit, with a heat exchanger (battery) on the supply air.
In addition to using passive solar gain, Passivhaus buildings make extensive use of their intrinsic heat from internal sources—such as waste heat from lighting, white goods (major appliances) and other electrical devices (but not dedicated heaters)—as well as body heat from the people and other animals inside the building. This is due to the fact that people, on average, emit heat equivalent to 100 watts each of radiated thermal energy.
Together with the comprehensive energy conservation measures taken, this means that a conventional central heating system is not necessary, although they are sometimes installed due to client skepticism.
Instead, Passive houses sometimes have a dual purpose 800 to 1,500 watt heating and/or cooling element integrated with the supply air duct of the ventilation system, for use during the coldest days. It is fundamental to the design that all the heat required can be transported by the normal low air volume required for ventilation. A maximum air temperature of 50 °C (122 °F) is applied, to prevent any possible smell of scorching from dust that escapes the filters in the system.
The air-heating element can be heated by a small heat pump, by direct solar thermal energy, annualized geothermal solar, or simply by a natural gas or oil burner. In some cases a micro-heat pump is used to extract additional heat from the exhaust ventilation air, using it to heat either the incoming air or the hot water storage tank. Small wood-burning stoves can also be used to heat the water tank, although care is required to ensure that the room in which stove is located does not overheat.
Beyond the recovery of heat by the heat recovery ventilation unit, a well designed Passive house in the European climate should not need any supplemental heat source if the heating load is kept under 10 W/m².
Because the heating capacity and the heating energy required by a passive house both are very low, the particular energy source selected has fewer financial implications than in a traditional building, although renewable energy sources are well suited to such low loads.
The Passive house standards in Europe determine a space heating and cooling energy demand of 15 kWh/m2 (4,750 BTU/sq ft) pear year, and 10 W/m2 (3.2 Btu/h/sq ft) peak demand. In addition, the total energy to be used in the building operations including heating, cooling, lighting, equipment, hot water, plug loads, etc. is limited to 120 kWh/m2 (38,000 BTU/sq ft) of treated floor area per year.
Lighting and electrical appliances
To minimize the total primary energy consumption, the many passive and active daylighting techniques are the first daytime solution to employ. For low-light days, non-daylighted spaces, and nighttime, the use of creative-sustainable lighting design using low-energy sources can be used. Low-energy sources include 'standard voltage' compact fluorescent lamps, solid-state lighting with LED lamps, organic light-emitting diodes, PLED - polymer light-emitting diodes, 'low voltage' electrical filament-Incandescent light bulbs, compact Metal halide, Xenon, and Halogen lamps.
Solar powered exterior circulation, security, and landscape lighting - with photovoltaic cells on each fixture or connecting to a central Solar panel system, are available for gardens and outdoor needs. Low voltage systems can be used for more controlled or independent illumination, while still using less electricity than conventional fixtures and lamps. Timers, motion detection and natural light operation sensors reduce energy consumption, and light pollution even further for a Passivhaus setting.
Appliance consumer products meeting independent energy efficiency testing and receiving Ecolabel certification marks for reduced electrical-'natural-gas' consumption and product manufacturing carbon emission labels are preferred for use in Passive houses. The ecolabel certification marks of Energy Star and EKOenergy are examples.
Traits of passive houses
Typically, passive houses feature:
- Fresh, clean air: Note that for the parameters tested, and provided the filters (minimum F6) are maintained, HEPA quality air is provided. 0.3 air changes per hour (ACH) are recommended, otherwise the air can become "stale" (excess CO2, flushing of indoor air pollutants) and any greater, excessively dry (less than 40% humidity). This implies careful selection of interior finishes and furnishings, to minimize indoor air pollution from VOC's (e.g., formaldehyde). This can be counteracted somewhat by opening a window for a very brief time, by plants, and by indoor fountains.
- Because of the high resistance to heat flow (high R-value insulation), there are no "outside walls" which are colder than other walls.
- Homogeneous interior temperature: it is impossible to have single rooms (e.g. the sleeping rooms) at a different temperature from the rest of the house. Note that the relatively high temperature of the sleeping areas is physiologically not considered desirable by some building scientists. Bedroom windows can be cracked open slightly to alleviate this when necessary.
- Slow temperature changes: with ventilation and heating systems switched off, a passive house typically loses less than 0.5 °C (0.90 °F) per day (in winter), stabilizing at around 15 °C (59 °F) in the central European climate.
- Quick return to normal temperature: opening windows or doors for a short time has only a limited effect; after apertures are closed, the air very quickly returns to the "normal" temperature.
- Some have voiced concerns that Passivhaus is not a general approach as the occupant has to behave in a prescribed way, for example not opening windows too often. However modelling shows that such concerns are not valid.
- In the United States, a house built to the Passive House standard results in a building that requires space heating energy of 1 British thermal unit per square foot (11 kJ/m2) per heating degree day, compared with about 5 to 15 BTU/sq ft (57 to 170 kJ/m2) per heating degree day for a similar building built to meet the 2003 Model Energy Efficiency Code. This is between 75 and 95% less energy for space heating and cooling than current new buildings that meet today's US energy efficiency codes. The Passivhaus in the German-language camp of Waldsee, Minnesota was designed under the guidance of architect Stephan Tanner of INTEP, LLC, a Minneapolis- and Munich-based consulting company for high performance and sustainable construction. Waldsee BioHaus is modeled on Germany's Passivhaus standard: beyond that of the U.S. LEED standard which improves quality of life inside the building while using 85% less energy than a house built to Minnesota building codes. VOLKsHouse 1.0 was the first certified Passive House offered and sold in Santa Fe New Mexico.
- In the United Kingdom, an average new house built to the Passive House standard would use 77% less energy for space heating, compared to the circa-2006 Building Regulations.
- In Ireland, it is calculated that a typical house built to the Passive House standard instead of the 2002 Building Regulations would consume 85% less energy for space heating and cut space-heating related carbon emissions by 94%.
Comparison with zero energy buildings
A net zero-energy building (ZEB) is a building that over a year does not use more energy than it generates. The first 1979 Zero Energy Design building used passive solar heating and cooling techniques with air-tight construction and super insulation. A few ZEB's fail to fully exploit more affordable conservation technology and all use onsite active renewable energy technologies like photovoltaic to offset the building's primary energy consumption. Passive House and ZEB are complementary synergistic technology approaches, based on the same physics of thermal energy transfer and storage: ZEBs drive the annual energy consumption down to 0 kWh/m2 with help from on-site renewable energy sources and can benefit from materials and methods which are used to meet the Passive House demand constraint of 120 kWh/m² which will minimize the need for the often costly on-site renewable energy sources. Energy Plus houses are similar to both PassivHaus and ZEB but emphasize the production of more energy per year than they consume, e.g., annual energy performance of -25 kWh/m2 is an Energy Plus house.
Tropical climate needs
In a tropical climate, it could be helpful for ideal internal conditions to use energy recovery ventilation instead of heat recovery ventilation to reduce the humidity load of ventilation on the mechanical dehumidification system. Although dehumidifiers might be used, heat pump hot water heaters also will act to cool and condense interior humidity (where it can be dumped into drains) and dump the heat into the hot water tank. Passive cooling, solar air conditioning, and other solutions in passive solar building design need to be studied to adapt the Passive house concept for use in more regions of the world.
There is a certified Passive House in the hot and humid climate of Lafayette, Louisiana, USA, which uses energy recovery ventilation and an efficient one ton air-conditioner to provide cooling and dehumidification.
Solar access is a very important factor in any design of a passive house as it allows the structure to use the solar energy to heat and light the space naturally, replace electrical water heaters with solar-energy-based water heaters.
- Benefits of High Performance Building
- EnerGuide (Canada)
- Energy-plus buildings
- Green building
- History of passive solar building design
- Home energy rating (USA)
- House Energy Rating (Aust.)
- List of low-energy building techniques
- List of pioneering solar buildings
- Low-energy house
- National Home Energy Rating (UK)
- Passive solar
- PlusEnergy buildings
- Quadruple glazing
- R-2000 program
- Renewable heat
- Self-sufficient homes
- Solar air heat
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