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The construction of a berm shed, a sustainable and aesthetically pleasing storage solution, involves a unique process that utilizes natural building techniques and earth-sheltering principles. First, the building site is prepared using earthworks, shaping the surrounding land to create a berm, which is a raised bank of soil that will eventually cover a portion of the shed's sloping roof. Round wood timber framing is a common technique employed in berm shed construction, utilizing logs sourced from the property instead of commercially produced dimensional lumber. These logs are carefully selected and placed to form the structural framework of the shed, including the walls and roof supports. Once the timber frame is erected, a moisture barrier, such as billboard material or layers of poly sheeting and newspaper, is installed over the logs to protect them from the elements. Finally, soil is carefully layered on top of the moisture barrier, creating the berm and providing insulation, thermal mass, and a natural aesthetic. The construction process prioritizes using natural, locally sourced materials and minimizing the use of energy-intensive and potentially toxic commercial products, aligning with permaculture principles of sustainability and self-sufficiency.
WOFATI, an acronym for Woodland Oehler Freaky-cheap Annualized Thermal Inertia, represents an innovative approach to sustainable building, coined by permaculture expert Paul Wheaton. This building technique combines the affordability and simplicity of Mike Oehler’s earth-sheltered designs with Wheaton's focus on cost reduction and integration with the natural environment. WOFATI structures prioritize the use of readily available, natural materials, such as wood and earth, minimizing reliance on manufactured products and reducing the building's environmental footprint. Annualized Thermal Inertia, a key principle of WOFATI, utilizes the surrounding earth as a thermal mass, storing heat in the summer to warm the building during winter and retaining cool temperatures from winter to moderate summer heat, thereby minimizing energy consumption for heating and cooling. WOFATI designs typically feature large windows on the uphill side to maximize passive solar gain, further reducing energy needs. WOFATIs are intended to be situated on or near a woodland, embracing the concept of harmonious integration with nature. Notable examples of WOFATI structures, including Allerton Abbey and Wofati 0.8, can be found at Wheaton Labs in Montana.
When discussing "woodland" versus "forest," the structural and management approaches differ significantly, particularly within a permaculture context. Forests, often managed for timber production, frequently involve monoculture planting and practices like clear-cutting, which can create what Sepp Holzer calls a "conifer desert." This leads to decreased biodiversity, depleted soil health, and disrupted ecological balance. "Woodland" management, as described by Ben Law, focuses on a more holistic, interconnected ecosystem. Woodland management prioritizes biodiversity, recognizing the interconnectedness of all lifeforms within the ecosystem. Active human participation is encouraged, mimicking the sustainable land management practices of Indigenous cultures, as exemplified by the HUSP (Horticulture of the United States of Pocahontas) concept. Woodlands are viewed as spaces where humans actively participate and nurture, promoting long-term health and resilience. This active management ensures the woodland provides not only timber but also food, medicine, and wildlife habitat. The selection of "woodland" in Wofati design reflects a conscious shift away from extractive forestry practices and toward a more sustainable and harmonious relationship with the natural world. In essence, the distinction between woodland and forest highlights the crucial role of human management in shaping the structure and health of these ecosystems, emphasizing the permaculture principle of responsible stewardship of natural resources.
WOFATI, an acronym for Woodland Oehler Freaky-cheap Annualized Thermal Inertia, is an innovative approach to sustainable building developed by permaculture expert Paul Wheaton. WOFATI structures are designed to be eco-friendly, utilizing locally sourced natural materials, primarily wood and earth. These structures are intended to be located on or near woodlands, promoting a harmonious integration with the natural surroundings. Annualized Thermal Inertia, a key element of WOFATI design, harnesses the thermal mass of the surrounding earth to provide passive heating in winter and cooling in summer, thereby minimizing the need for artificial temperature regulation. WOFATI structures are inspired by the work of Mike Oehler, a pioneer in earth-sheltered building known for his simple, "freaky-cheap" designs, which Wheaton has adapted and refined to further reduce construction costs. WOFATI buildings are typically characterized by a large gable roof on the downhill side, with at least 35% of the uphill wall featuring glass or other light-transmitting materials to maximize passive solar gain. Allerton Abbey, the first WOFATI structure, and Wofati 0.8 are both located at Wheaton Labs in Montana and serve as prominent examples of this unique building style.
Hugelkultur offers advanced techniques and benefits for sustainable gardening and food production. This permaculture method utilizes buried wood to create raised garden beds, fostering a thriving ecosystem that reduces reliance on external inputs. As the wood decomposes, it transforms into "a sponge to hold water," decreasing irrigation needs and attracting beneficial microorganisms that enhance soil fertility. The shrinking wood creates air pockets, naturally aerating the soil and promoting a "self-tilling" effect. This "soil on wood" technique enhances soil health by creating "parking spaces for water and nutrients", ultimately minimizing the need for fertilizers. Hugelkultur beds can be constructed on varying scales, from small gardens to large farms, and are particularly well-suited for locations with limited rainfall, such as deserts. This versatile approach allows gardeners to cultivate diverse "garden plants" while minimizing environmental impact.