Passive house

Bo Adamson, co-originator of the passive house concept

Wolfgang Feist, co-originator and founder of the Passivhaus-Institut (PHI) in Germany

The term passive house was originally used in the 1970s for buildings emphasizing passive solar strategies. Since the 1990s, it instead denotes meeting specific quantified PHI certification criteria (space conditioning, primary energy, airtightness and comfort requirements).^[10] The standard originated from a 1988 discussion between Bo Adamson (Lund University) and Wolfgang Feist (then at the Institute for Housing and Environment, Darmstadt), followed by research supported by the state of Hesse.^[11][12] Passive solar strategies are not required, though often form part of the approach to meet the certification criteria.

North American “superinsulation” pioneers of the 1970s (e.g., the Saskatchewan Conservation House and the Leger House) provided important technical precursors, including heat-recovery ventilation and airtightness testing.^[13][14]

Further implementation

The Passivhaus-Institut (PHI) was founded in 1996 in Darmstadt to develop, promote and certify to the standard. By 2010 an estimated 25,000+ Passive House buildings existed worldwide.^[2][17][18]

The concept has since been demonstrated at scale. Gaobeidian, China, hosts what is reported as the world’s largest Passive House development (Railway City), with several hundred thousand m² of certified area built in phases since 2019.^[19][20] The world’s tallest certified Passive House building is the 88 m Bolueta tower in Bilbao, Spain (2018).^[21][22]

In the United States, Katrin Klingenberg’s 2003 “Smith House” (Urbana, IL) catalyzed a movement that led to the creation of PHIUS (2007). PHIUS has since certified hundreds of projects; New York City’s Park Avenue Green (2019) was recognized as North America’s largest Passive House affordable housing project at the time.^[23][24][25]

In the UK health sector, the Passivhaus-certified Foleshill Health Centre (Coventry, opened 2021) demonstrated substantial energy savings in operation and a replicable delivery model for NHS facilities.^[26][27]

While techniques such as superinsulation predate the standard, Passive House (PHI) specifies quantitative performance criteria and quality assurance. Key requirements include:^[4]

• Annual space heating (and, in suitable climates, cooling) demand ≤ 15 kWh/m²/a (0.0047 MJ/sq ft/sq ft) or peak heat load ≤ 10 W/m² (0.0012 hp/sq ft), as calculated with the Passive House Planning Package (PHPP), using local climate data.
• Airtightness: n₅₀ ≤ 0.6 h⁻¹ at ±50 Pa, measured via a blower-door test.
• Efficient mechanical ventilation with heat recovery (typically ≥75% sensible efficiency).
• Whole-building primary energy/renewable energy limits as defined by PHI (see PHI documentation).

Passive House building costs vary by market, building type, and the experience of the builder and their team. Reported cost premiums for Passive House construction over conventional construction have ranged from ~5–10% in Germany, the UK and the US, with reductions noted as supply chains mature.

The specific drivers of building cost and complexity vary, but relative to basic Code-compliant construction, Passive Houses typically include superinsulation of the envelope, requiring greater thickness and complextiy of the wall assembly in particular, and particular attention to air, water, and vapour barriers, including at all penetrations. They also include very high performance window and exterior door systems.

Cost premiums are partially offset by downsized or eliminated conventional heating/cooling systems, and lower operating costs over the building life cycle.^[31][32] Delivery at cost parity with standard code buildings has been demonstrated in some German multifamily projects (e.g., Vauban, Freiburg).^[33] High-latitude locations (>60°N) can face higher envelope and glazing costs to meet targets.^[34]

Core practices include:

• Passive solar design and urban/landscape integration – compact massing, appropriate solar gains, shading, and mitigation of overheating; strategies are adapted to climate, especially in hot-humid regions.^[35]
• Superinsulation and thermal-bridge-free detailing (typical opaque U-values ~0.10–0.15 W/m²·K).^[36]
• High-performance windows (triple/quad glazing, low-e coatings, inert-gas fills, warm-edge spacers; whole-window U-values often ≤0.80 W/m²·K)^[37].^{[citation needed]}
• Airtightness to n₅₀ ≤0.6 h⁻¹, verified by blower-door testing; intermediate tests during construction are recommended.^[38]
• Balanced mechanical ventilation with heat recovery (typically ≥75% efficiency) for IAQ and energy recovery; earth-tubes may be used with careful moisture control where appropriate.^[39]
• Low-load space conditioning – many climates allow heating via tempered ventilation air with small duct heaters or heat-pump coils; peak loads are limited by envelope performance.^[40]

Concerns are sometimes raised that occupants must restrict behaviours (e.g., opening windows), but sensitivity analyses indicate performance is generally robust to typical occupant variation.^[41]

• United States – Space-heating intensity around 1 British thermal unit per square foot (11 kJ/m²) per heating degree day is typical for PHI Passive House, compared to ~5–15 for code-built homes (2003 MEE Code), representing 75–95% savings. Waldsee BioHaus (Minnesota) follows the German standard and reported ~85% lower energy use than comparable LEED homes.^[42]
• United Kingdom – New houses to Passive House standard used ~77% less space-heating energy than homes built under circa-2006 Building Regulations.^[43]
• Ireland – Typical Passive House dwellings consumed ~85% less space-heating energy and cut related CO₂ by ~94% versus 2002 Regulations baselines.^[44]