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What are the Most Efficient Passive Home Designs

Muhammad Ali Zia — Tue, 07 Dec 2021 17:16:27 +0000

Passive home designs have one common goal – to create energy-efficient homes (or commercial structures) without compromising on the health and comfort of the occupants.

Before upgrading your home to a passive home design you should take into consideration things like – landscape around the house, climate and weather conditions, energy consumption, and many more.

With this in mind, the most efficient designs should not only conform to strict (and proven) standards, but they should also be practical. As a leading provider of architectural, structural, and MEP engineering designs, we can help you develop or evaluate passive home designs.

You’ll be better positioned to select designs that are suitable for your needs with our help. Here is a look at the principles of passive home designs and some tips to assess efficient blueprints. Read More About Click Here: Structural Design for a Residential Building.

Photo by Chastity Cortijo on Unsplash

A brief overview of the principles of passive home designs

Passive homes seek to enhance energy efficiency and simultaneously minimize the need for heating and cooling by focusing on the following principles:

High-quality insulation
Airtight construction
Effective solar orientation
Efficient ventilation and energy recovery
High-performance windows

An efficient passive home significantly reduces the energy demands of a structure resulting in a positive environmental impact. But how can you tell the most efficient designs?

Assessing efficiency

Efficient passive home designs should incorporate the above principles and conform to PHIUS+ Standards. These benchmarks are researched and established by the Passive House Institute US. The organization also performs the following functions:

Lobbies for the mainstreaming of Passive Home Designs in America.
Provides guidelines for designing passive homes that are eligible for certification in America.

Designers and providers of architectural engineering services generally concur that these standards are both effective and practical. Below is a look at what efficient designs should look like in light of the principles and PHIUS standards.

High-quality insulation

For homes in moderate climate zones, the insulation provided by furnishings and the drywall may be sufficient. There is no need for additional insulating materials. However, that is not the case for homes in temperate or extreme climate zones.

The first principle in passive home designs is high-quality insulation. Architectural blueprints that meet the passive home design criterion entail continuous insulation at all junctions. That means the structure has continuous insulation all around it (the slab, walls, and roof) without any interruptions.

The most efficient passive home designs often double the minimum amount of insulation required. They also use high-quality and environmentally friendly insulating materials such as sheep’s fleece and cellulose. But it is hard to achieve continuous insulation throughout the structure. Some junctions could have interruptions that would create a “thermal bridge.” The architectural engineering design of passive homes minimizes the occurrence of thermal bridges. However, heat loss is inevitable. Therefore, designers of efficient models give you an idea of how much heat loss to expect. They quantify it via modeling and calculation, and advice.

Airtight construction

It would be impossible to maintain the desired air temperature in a porous structure. Therefore, the second principle – airtight construction – is a prerequisite of the first principle. Nevertheless, it is hard to imagine buildings without vents, windows, doors, and other necessary “air-leakage” points. These parts are essential. However, they complicate the need to maintain ambient internal temperatures without consuming extra energy. Plus, there is the problem of damp and mold in humid areas that have insufficient circulation.

Passive home designs use approaches such as caulking, high-quality MEP engineering, closed-cell insulation, and materials such as gaskets to plug air leaks. The most efficient passive home designs predict the air leakage rates and engineers use the information to design a balanced ventilation system.

Or a system where incoming clean air is almost equal to the outgoing exhaust air. Passive House Institute – US standards require that the supply and exhaust airflows be within 10% of each other. Moreover, where there is an unbalanced ventilation system, the net pressurization or depressurization should not exceed 5 Pa.

Effective energy recovery

Having an effective ventilation system means the home has excellent air quality, thus not compromising on comfort. However, it also means the structure would be losing energy when expelling exhaust air. Any incoming air should therefore be heated or cooled to maintain interior conditions. The resultant is a net energy loss. Efficient passive home designs minimize such losses by incorporating HRV (Heat Recovery Ventilation) or ERV (Energy Recovery Ventilation).

The geographical location of the structure determines the applicable energy recovery technique. Heat Recovery Ventilation systems maintain the humidity level within the building and are suitable for dry areas, comment Fantastic Electricians. Energy Recovery Ventilation systems extract moisture. They are ideal for high-humidity environments such as coastal areas.

High-performance doors and windows

Ordinary design homes allow for energy loss through windows and doors. However, the most efficient passive home designs minimize such losses by incorporating high-quality installations (doors and windows). The windows are often triple-paned with insulated frames and glass spacers. The installations are also only from credible suppliers who test and provide air-leak specifications.

Besides the material constitution and specs of the windows and doors, the placement is also essential. The orientation should optimize natural sunlight and heat. Windows and doors should face within 30 degrees of true south. Also, they should not be shaded or have any obstructions (by trees or other buildings) during the warm season.

Effective solar orientation

Energy conservation is a crucial aspect of passive home designs. With proper orientation, solar energy can contribute significantly to the lighting and heating requirements of the home.

Architectural designs in temperate zones aspire to optimize passive solar heating during winter and curtail overheating during the summer months. In warmer climates, efficient passive home designs seek to minimize overheating.

Efficient designs, therefore, incorporate windows with a high solar heat gain coefficient (SHGC) in south-facing walls. On the other hand, for the east or west-facing windows, the design could include overhangs, blinds, sun shades, or other techniques. This presentation by PHIUS provides insights on designing optimum window shadings in passive homes.

Passive homes also use darker colors on surfaces in direct contact with the sun during cold months to “collect” energy. Then, they apply different thermal distribution strategies to create passive solar heating throughout the structure. Effective passive home designs also incorporate deciduous trees on the east-west side of the building. The trees would block excessive sunlight during the summer months, and when the cold months set in, they shed leaves and let in solar energy.

High-performance doors and windows

Plugging air leaks and regulating ventilation is one milestone. But there is the issue of energy loss through windows and doors. The most efficient passive home designs incorporate high-quality installations (such as doors and windows) that specify the air-leakage rates. The windows also are often triple-paned with insulated frames and glass spacers. The door or window should also be high-quality, from credible suppliers with tested air-leak specifications.

Besides the material constitution of the windows and doors, the placement is also essential. The orientation should optimize natural sunlight and heat. Also, they should not be shaded or have any obstructions (by trees or other buildings), especially during the cool months.

Photo by Brian B abb on Unsplash

Efficient passive home designs – a final word

There are many different techniques and strategies employed when creating passive home designs. But any design should essentially stick to the above principles and meet the standards. You may have to do some balancing between the costs and practicality. So, reach out to seasoned designers and get help on coming up with the ideal design. Some of the considerations to incorporate include:

A simple thermal envelope.
If it is a single-family house, the window area should be 10-15% of the wall area.
A compact building for small structures. If it is a large one, it should have bump-ins for daylighting.
Minimize “open to below” areas on the floor.
The building should not be too small and detached.

In case you have architectural, structural, and MEP design requirements, or home renovation, feel free to contact us. We provide you with the full permit set design + T24.

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Top Ten Principles of Passive House Design

Muhammad Ali Zia — Wed, 22 Sep 2021 15:31:02 +0000

The passive house design theory originates in Europe around 30 years ago. In 1988, German physicist Wolfgang Feist and Swedish structural engineer Bo Adamson developed this theory.

It relies upon the concept in which, by carefully designing around some key principles, it is possible to create a building that can self-maintain a dry, healthy and comfortable indoor air quality and temperature, with a little-to-no requirement for heating or cooling. In such houses, new elements replace the standard HVAC components like ventilators, air conditioners, etc.

The structural design and construction of a Passive House follow the below ten core principles:

1. Airtightness

A vital factor in the durability and performance of a Passive House is creating an airtight layer – a virtually impenetrable barrier. Such a barrier prevents air from penetrating through to the inside.

Designers make airtight layers by using a combination of sheet and fluid-applied membranes, sealants, and tapes, This layer facilitates the uninterrupted transition between the building’s structural elements. A blower door test is then used to verify the proper function of the layer, confirming the quality of the construction.

2. Continuous insulation

A continuous layer of thick insulation is wrapped around a Passive House design. Its function is to keep them optimally cool in summer and warm in the winter months. Not only does this improve the year-round thermal comfort of the space, but it also helps to reduce the incidence of condensation inside the building.

3. Heat recovery

Passive House design incorporates the delivery of fresh, filtered air with the addition of heat recovery to ensure that the building can maintain improved air quality indoors without the need to open any doors or windows. Balanced ventilation components are installed to supply a continuous indoor fresh air stream, whilst simultaneously removing odors, stale air, and other indoor pollutants from the bathrooms and kitchen spaces. These components are Heat Recovery Ventilators (HRVs) and Energy Recovery Ventilators (ERVs).

Within these devices, a heat exchanger enables the outgoing heat energy to warm the incoming air as the two streams of air continually mix within the unit. Conversely, in the summer months, the coolness of the outgoing air brings the temperature of the incoming air down. The units contain filters for removing pollutants and pollen.

4. High-performance doors and windows

The performance quality of doors and windows plays a pivotal role in the success of a Passive House design. The addition of windows and doors essentially interrupt the advanced wall assembly including the insulative, airtight layers that have been installed. Therefore, their performance is critical to maintaining the integrity of the design.

Passive House windows and doors need to allow solar radiation to effectively warm the interior air during winter months, yet also minimize this heat radiation from the outside in summer months. They are therefore designed to be airtight and are usually double or even triple-glazed for maximum insulation capabilities.

5. Thermal bridge-free construction

Good insulation is of little effectiveness if it faces interruption. A thermal bridge refers to any element of a building that enables air temperatures to bypass the thermal barrier otherwise created for the building. Examples include a poorly constructed/installed window frame, or a concrete floor that runs from the inside to the outside of the building.

As well as keeping insulation penetrations to a minimum, the impact of thermal bridges is minimized by introducing thermal breaks, which are insulative elements that prevent any thermal energy from flowing through an assembly.

6. Maximizing solar gain effectiveness

Natural daylight provides a passive solar gain that essentially creates free heating to a Passive House building. That said, for others, they can become a liability when the existing internal heat gains are already significant and need management.

Passive house designers must work to optimize the use of the available passive solar gains in keeping with the climate, and consider orientation, layout, shading, and all other factors to determine how best to utilize this free commodity within the design.

According to Buttonwood, a Toronto Property Management Company, a large number of landlords are now deciding to invest in passive homes for these eco-friendly benefits which are also attracting more residents.

7. Adequate shading

The cooler months may benefit greatly from the solar gains coming from the outside. However, this direct heat energy must also be efficiently managed to equally suit the warmer seasons. A great solution for this is to introduce deciduous trees to the external landscape, as their full summer branches provide shade, while their bare winter branches allow more sunlight to flow into the building.

Other design elements include window screens and shades, as well as retractable overhangs. They can also assist in controlling the direct solar energy exposure seasonally.

8. Efficient heating and distribution of water

The first step is to make sure Passive House design has successfully reduced heating/cooling related-energy consumption. The next culprit to focus on is the heating and distribution of domestic water. By installing an ultra-efficient water heater and making the distribution lines well insulated, smaller, and, where possible, shorter, it is possible to minimize the energy consumption in keeping with the goal of a Passive House design.

9. Building form and orientation

How easy or difficult it will be to achieve a successful Passive House design? This will depend largely upon the initial fundamental decisions around the proposed building’s form and orientation.

The orientation of the building is also a highly important matter. It has a high impact on the optimization of solar gains for optimal energy performance. Additionally, the more simple the overall form of the building, the easier it will be to ensure continuous insulations. It also helps to minimize thermal bridge interruptions.

10. Managing moisture

Different climates will alter the way that heat and moisture behave within building designs. Therefore, passive house designers must understand how to create plans that best manage these relationships. They need this to avoid the risks of water intrusions and condensation build-up.

Final thoughts

The principles of Passive House design allow for a careful balance between different factors. These factors include occupant use, heat emissions, and climate, etc. Such balance helps to optimize the energy efficiency of the building.

When successfully carried out, a Passive House should successfully keep the interior at a consistently comfortable temperature year-round. With a little-to-no requirement, it also minimizes any additional heating or cooling. Additionally, the continuous ventilation creates a superior 24/7 indoor air quality. As a result, the long-term comfort, health, and energy efficiency benefits to Passive House design are significant

In case you need more information or requirements feel free to contact us!

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