In 2014, I was living in a small apartment in the San Francisco Bay Area, a few miles south of Stanford University. I wanted to improve my quality of life by purchasing a home. Real estate in the area was extremely expensive and prices were accelerating upwards, so I decided it was time to consider a move to a more affordable locale.

For a long time, I had wanted to live in New England. When an opportunity arose to purchase an undeveloped property in southern Rhode Island, I jumped on it. This looked like a great place to build an interesting new house. I wanted the home to be comfortable, quiet, and energy-efficient. Beyond that, I was open to any and all ideas.

Conceptual drawing of Maynard residence
Conceptual drawing of Maynard residence
Credit: Steve Baczek



A New Approach

After a tour of a home site with an innovative local builder, I decided to design and build a house that achieves (and hopefully exceeds) a very stringent set of requirements called the Passive House building standard. I assembled a team of highly-qualified professionals who understood what we wanted to do and were up to speed on the latest advances in science-based design and construction methods.

A Passive House typically uses 80-90% less energy than a conventional American home — hard to believe, but true. The air inside the home is clean and safe, with very little temperature variation (no hot or cold spots). Occupants aren’t bothered by pollen, excessive humidity, or outside noise.

How does a Passive House achieve this?

  • Passive solar heating. The primary source of heat during the cooler months is sunlight that enters through large, south-facing windows. Wide eaves and other shading techniques are used to minimize solar gain during the warmer months.

  • Superinsulation. A passive house uses insulation with very high R-values around the main envelope, including the foundation.

  • Minimal thermal bridging. Passive house designers try very hard to eliminate thermal bridging inside the main envelope. Thermal bridging occurs when a conductive material extends from within the main envelope to the outside air.

  • No leaks! The main envelope is virtually airtight, preventing infiltration of outside air and loss of conditioned air.

  • High-performance windows and doors. European-designed windows and doors provide exceptional thermal and acoustical insulation. Features include triple glazing, multiple gaskets, warm-edge spacers, and a multi-point locking system to ensure a tight seal.

  • Whole-house ventilation. An independent ventilation system exchanges the air inside the main envelope every few hours, and includes subsystems for air filtration, energy recovery, and dehumidification.

  • Supplemental heating and cooling. Small, ductless heat pumps called mini-splits are used to maintain a comfortable temperature inside the home regardless of outside conditions. When cooling the air inside the home, heat pumps also help to reduce humidity.


Powered by the Sun

To reduce my dependence on power sources that emit greenhouse gases, I decided to generate power on site using a photovoltaic system from Newport Solar. An array of thirty rooftop solar panels generate up to 9000 watts during daylight hours to power the house and recharge an energy storage system manufactured by Sonnen USA. Surplus power is sold to the local electric utility.

Eight lithium-ion batteries charge up during the day and provide power to the house at night. When the grid goes down, the batteries provide power to essential loads — ventilation, refrigeration, climate control — that keep the house habitable. I expect residential energy storage systems to grow in popularity as manufacturing costs come down. Every homeowner can benefit from the ability to store energy on site for use during power outages instead of relying on noisy gas-powered generators.


The Project Team


Photos

During the construction of the house, I took photos every few days.

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