RIGOUROUSLY DESIGNED & CONSTRUCTED
We are certified Passive House builders and proudly constructed the first Passive House in the Northern Rivers, which has been recognised as the most airtight building in Australia to date.
We are certified Passive House builders and proudly constructed the first Passive House in the Northern Rivers, which has been recognised as the most airtight building in Australia to date.
Passivhaus northern rivers
A Certified Passive House is a rigorously designed and constructed building that adheres to the stringent energy efficiency standards set forth by the Passive House Institute (PHI). The concept originated in Germany in the late 1980s and has gained global recognition as a benchmark for sustainable construction.
A Certified Passive House focuses on creating an ultra-low energy structure that requires minimal heating or cooling, even in extreme weather conditions. It achieves this through a combination of advanced building techniques, high-quality insulation, airtight construction, and mechanical ventilation with heat recovery.
The primary goal of a Certified Passive House is to achieve exceptional energy efficiency while maintaining a high level of indoor comfort and air quality. These buildings typically use up to 90% less energy for heating and cooling compared to conventional structures. To achieve certification, a building must undergo rigorous testing and modeling to ensure it meets strict criteria for thermal performance, airtightness, energy consumption, and overall environmental impact. This certification process not only ensures that the building is energy-efficient, but also guarantees that occupants will enjoy consistent thermal comfort, excellent indoor air quality, and minimized noise pollution. As sustainability becomes increasingly important in construction, Certified Passive Houses stand out as exemplars of efficient, comfortable, and environmentally conscious building design.
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Energy Efficiency: Passive Houses typically use 60-70% less energy for heating and cooling compared to conventional buildings, resulting in significant cost savings on utility bills.
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Comfort: The high level of insulation and airtightness in Passive Houses create consistent indoor temperatures year-round, eliminating drafts and cold spots, and providing exceptional thermal comfort to occupants.
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Health and Indoor Air Quality: With a constant supply of filtered fresh air provided by energy recovery ventilation systems, Passive Houses maintain superior indoor air quality, reducing the risk of allergens, pollutants, and mould growth, a major issue in our region.
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Durability: The meticulous construction techniques used in Passive House design contribute to the durability and longevity of the building, reducing maintenance costs over time.
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Environmental Sustainability: By significantly reducing energy consumption and greenhouse gas emissions, Passive Houses contribute to mitigating climate change and promoting environmental sustainability.
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Resilience: Passive Houses are inherently resilient to external temperature fluctuations, making them more comfortable and livable during extreme weather events.
Airtightness
Airtightness is a cornerstone of passive house design, holding profound implications for both energy efficiency and occupant health. In a passive house, meticulous sealing of building envelopes prevents unintended air leakage, which can lead to heat loss, drafts, and discomfort. Beyond energy conservation, airtightness significantly contributes to occupant health by safeguarding indoor air quality.
By preventing the infiltration of outdoor pollutants, allergens, and contaminants, airtight construction ensures that the air within the house remains clean, free from irritants, and conducive to respiratory well-being.
This is particularly crucial as we spend a significant portion of our lives indoors. The combination of energy efficiency and improved indoor air quality fosters a healthier living environment, reducing the risk of respiratory ailments, allergies, and other health issues. Thus, airtightness in passive houses not only champions sustainability but also prioritizes the health and comfort of its occupants.
Heat Recovery Ventilation
Heat Recovery Mechanical Ventilation (HRMV) in a passive house involves the utilization of a ventilation system that not only exchanges indoor and outdoor air but also recovers the heat from the outgoing air and transfers it to the incoming fresh air. This process helps maintain a comfortable indoor temperature while ensuring high indoor air quality.
In a passive house, which is designed to be highly energy-efficient, HRMV contributes to reducing energy consumption by recovering a significant portion of the heat that would otherwise be lost through conventional ventilation. The system typically consists of a heat exchanger that transfers heat from the exhaust air to the supply air, minimizing the need for additional heating or cooling.
Health benefits arise from this system’s ability to maintain a consistent supply of fresh air while filtering out pollutants, allergens, and contaminants from the incoming air. This results in improved indoor air quality, which has been linked to better respiratory health, reduced allergies, and enhanced overall well-being. The controlled airflow also helps prevent issues like condensation and mold growth, further promoting a healthier living environment.
Insulation
Thermal insulation holds immense importance in a passive house by sustaining a consistent indoor temperature. By minimizing heat transfer through well-insulated walls, roofs, and floors, insulation keeps the interior comfortably warm in winter and pleasantly cool in summer.
This naturally decreases the reliance on active heating and cooling systems, resulting in substantial energy savings and lower utility costs. Furthermore, effective insulation prevents heat leakage and ensures the maintenance of a comfortable and livable environment, aligning perfectly with the core principles of passive design.
As a result of reduced energy demands, a passive house not only offers enhanced environmental benefits but also provides homeowners with a sustainable and economically efficient living space.
High Performance Windows
High Performance Windows in Passive Houses adhere to the stringent energy efficiency standards of the Passive House Institute. These windows are engineered to minimize heat exchange by incorporating features like triple glazing, low-emissivity coatings, and inert gas fillings. They ensure airtightness, preventing drafts and reducing energy loss.
The design allows controlled solar heat gain in cold months while limiting it in warmer months. Frames are made from thermally resistant materials to prevent thermal bridging. Quality installation is vital to maintain efficiency. These windows have low U-values, indicating minimal heat transfer. High Performance Windows play a crucial role in achieving the energy-efficient, comfortable, and high indoor air quality goals of Passive Houses.
Thermal bridge-free construction
Thermal bridge-free construction refers to designing and constructing buildings in a way that minimizes or eliminates areas where heat can easily flow from the interior to the exterior, or vice versa, leading to energy loss and reduced comfort. This is achieved by incorporating insulation, continuous thermal barriers, and careful detailing to prevent thermal bridging points, which are areas with higher heat transfer rates.
By utilizing materials with low thermal conductivity and optimizing the building envelope, thermal bridge-free construction enhances energy efficiency, reduces heating and cooling demands, and creates more comfortable indoor environments. Attention to proper insulation installation, strategic placement of structural components, and utilization of thermal simulation tools are essential to achieve this goal.
The outcome is a building that not only meets stringent energy efficiency standards but also provides occupants with a healthier and more sustainable living or working environment.