All of our construction details are certified Passive House components, certified though the Passive House Institute in Darmstsdt Germany. Our foundation, wall and roof designs as well as all structural details are currently patent pending under (DRH File No.: 9036.2.P01PCT01).
Ecocor High Performance Buildings is a Searsmont, ME- based construction firm that designs, manufactures, delivers and assembles the most energy efficient (“High Performance”) buildings on the market. All of our construction details are certified Passive House components, certified though the Passive House Institute in Darmstsdt Germany.
Our foundation, wall and roof designs as well as all structural details are currently patent pending under (DRH File No.: 9036.2.P01PCT01). Our system reduces the energy consumption of a building by 80-90% thus substantially reducing cost of ownership while at the same time increasing comfort, and reducing the carbon footprint of the building.
We started Ecocor to better execute the extremely energy efficient, healthy and architecturally unique designs of our own projects. We also realized that there were others out there struggling with the perceived cost and complexity of Passive House construction. We knew that we could leverage our expertise and experience and bring that knowledge to other projects. We believe that quality does not have to be a victim of cost, and that sustainability is no longer simply an option.
We work with architects, builders, and owners who have a commitment to high performance design and construction. We take pride in the performance and appearance of all of our buildings and look forward to helping you do the same.
Traditional building in Southern China. In this climate, cooling rather than heating, is required.
In many climate regions of the world, if buildings are "sensibly" constructed, no heating is required and neither is active cooling (e.g. in some parts of Iran, on the coast of Portugal, some parts of China…). "Passive Houses" have always been built there, although they weren't known as such. Bo Adamson (1990) was the first to classify these houses as passive houses, and the question whether it was possible to transfer this principle to Europe using technical means gave the idea for a research project concerning "passive houses".
Traditional turf houses in Iceland.
In the Middle Ages, in Iceland people started to build turf houses after wood became scarce. These were Passive Houses, although they didn't have adequate windows or sufficient ventilation.
Timber crisis: In the 17th and 18th Centuries in Europe there was a shortage of wood which was due to extensive deforestation. The solution to this problem was found in the mining of coal. However, in Iceland this was not possible. As we know, necessity is the mother of invention: the icelanders quickly found out that well-insulated houses remain warm by themselves.
The first fully functioning Passive House was actually a polar ship and not a house: the Fram of Fridtjof Nansen (1893).
He writes: "… The sides of the ship were lined with tarred felt, then came a space with cork padding, next a deal panelling, then a thick layer of felt, next air-tight linoleum, and last of all an inner panelling. The ceiling of the saloon and cabins . . . gave a total thickness of about 15 inches. …The skylight which was most exposed to the cold was protected by three panes of glass one within the other, and in various other ways. … The Fram is a comfortable abode. Whether the thermometer stands at 22° above zero or at 22° below it, we have no fire in the stove. The ventilation is excellent, especially since we rigged up the air sail, which sends a whole winter‘s cold in through the ventilator; yet in spite of this we sit here warm and comfortable, with only a lamp burning. I am thinking of having the stove removed altogether; it is only in the way." (from Nansen: "Farthest North", Brockhaus, 1897))
The DTH zero-energy house on the campus in Kopenhagen.
The "DTH zero-energy house" by Prof. Vagn Korsgaard (Kopenhagen, 1973) was also a Passive House. At the Technical University of Denmark, simulations were systematically carried out, designs were optismised and the first zero-energy house was built. The building was later used as a guest house for the university. However, the active solar technology was not renewed after it became defective. As a result, the "zero-energy house" objective was set aside in favour of the "low-energy house".
Experiences from this project were directly incorporated into Passive House research from the very beginning.
The Philips Experimental House (from: Hörster et al))
parallel to the Scandinavian and American developments, a systematic study of energy-efficient buildings was carried out in Germany by H. Hörster (research group leader), B. Steinmüller (building models and simulations) and others, with funding by the Federal Ministry of Research. A super-insulated experimental house, built in 1974/75, equipped with ground heat exchangers, controlled ventilation, solar and heat pump technology and "inhabited" by a computer served as a test and calibration object for computer models, used to explore the opportunities of energy efficiency and the use of renewable energy sources. These studies showed potential energy savings by a factor of 10 to 20 with passive measures alone for Europe and America, thus proving that such measures are an important step on the way to energy efficient buildings.
Experiences from this project also were incorporated into Passive House research from the very beginning.
A whole series of North American developments ("super-insulated houses") in the 70s and 80s were very close to the Passive House. William A. Shurcliff (1981) authored many publications on this subject. One of the early examples is the "Saskatchewan Conservation House", a still occupied building demonstrating the benefits of superinsulation.
This work was an important basis for low-energy houses and Passive Houses in Europe.
The "Rocky Mountains Institute (rmi)" by A. and H. Lovins. (Foto: rmi)
Amory Lovins, who is well-known for his publications about alternative energy, did not stop at the theory. He built an extremely well-insulated solar passive house in Old Snowmass in Colorado, at an altitude of 2164 meters. Tropical vegetation flourished in the winter garden and the stove was seldom used.
These experiences gave the Passive House research the assurance and confidence that physics works in practice too. A. B. Lovins visited the Passive House in Darmstadt Kranichstein in 1995. It was he who suggested that the Passive House should be considered not just as a research project, but also as the energy standard of the future.
The "Zero-energy house" in Dörpe near Hannover.
The "zero-energy house" by Erhard Wiers-Keiser and the organisation for "Ecological Future Workshop for Minimum-energy and Zero-energy Houses e.V." (1989) was calculated as having smaller demand values than a Passive House, but unfortunately the consumption values during operation were higher. Problems were due to reduced airtightness (non-reinforced building board), the insulation shutters on the inside and the solar storage technology. The annual 10 m³ solar storage was later removed to make space for a new wing, but the house was still used as an "almost Passive House" as before. Robert Borsch Laaks contributed significantly to the details.
Many members of the Passive House Research Group were involved in this project.
Ingolstadt-Halmstadt: Low-energy houses (30 kWh/(m²a) heating demand) in two countries, by Architekt Hans Eek (1985)
Sweden paved the way for the success of the "low-energy house". Experience with complicated and unreliable technology had taught them the right way to do things: a high level of airtightness, very
good insulation, good windows, reliable mechanical ventilation. Hans Eek is a leading pioneer in Sweden - the experiences with construction research are directly reflected in his life story: from
the "technological christmas tree" and the super-low-energy house to the Passive House. In the picture, terraced houses of the German-Swedish Ingolstadt-Halmstad Projekt can be seen.
These aren't Passive Houses, but it's only a small step further to the Passive House.
Hans Eek was and is a cooperating partner for all stages of the Passive House development.
The energy-autarchic solar house of the ISE in Freiburg. The building is used as a Passive House today.
The "energy-autarchic solar house" (ISE, Freiburg 1991/92, Wilhelm Stahl) was built around the same time as the Passive House in Darmstadt. It is also very similar to the Passive House. The sometimes very complicated autarchic supply technology with hydrogen storage was not operated any more after the end of the measurement period. The passive technologies and the heat recovery proved to be very effective. Today the ISE tests the efficiency of Passive House compact heating units under practical conditions in this house. During the project construction, the Passive House Group exchanged information with the ISE and Wilhelm Stahl, and mutual support was provided by each.
A team of scientists participated in the "Passive House Preparatory Research Project" – an international cooperation in which Bo Adamson and Gerd Hauser were also involved. With funding by the State of Hesse, a systematic research on the requirements for energy-efficient buildings has been done and prototypes of new building components were developed and produced: including insulated window frames, reduced thermal bridges and CO2-regulated ventilation. In 1990/91, based on plans by Prof. Bott/Ridder/Westermeyer, four terraced house residential units were built by for families in a joint venture. The houses have been occupied since 1991. An accompanying monitoring programme provided information about super-insulated building components, windows, ventilation heat recovery, user behaviour, indoor air quality, amount of internal heat sources and much else.
With normal use of the homes, this project confirmed the faultless functioning of all essential components – uninterruptedly to this day (…still true in March 2014). The measured energy consumption for heating has remained less than 10 kWh/(m²a) since 1991, the savings in comparison with traditional buildings are higher than 90%. Very good indoor air quality has always been monitored, and the high level of thermal comfort was confirmed by field measurements and user surveys. Most of the components (e.g insulated window frames) were manually-produced unique solutions; the decisive reason for the later production series of these quality building components was their flawless performance.