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Dry outhouses offer a sustainable alternative to conventional flush toilets, aligning with permaculture principles of resource conservation and waste reduction. A well-designed dry outhouse, strategically situated on an elevated point to encourage water runoff, utilizes a pit for waste collection. To mitigate odors and promote composting, sawdust is a crucial element. A "no pee" policy, though challenging for women due to anatomical differences, helps maintain a dry environment, crucial for minimizing pathogen survival and groundwater contamination. This "dry" approach allows the waste to essentially mummify over time, becoming poop-jerky after two years. This aged material, though technically safe for vegetable gardens, is ideally used to nourish "poop beast" trees like willows, poplars, or cottonwoods, as part of a "willow feeder system." For optimal functionality and user comfort, urine diversion mechanisms are essential, particularly in mixed-gender settings. This separation of urine, a valuable fertilizer, further reduces the volume and toxicity of the solid waste, facilitating easier handling and nutrient cycling. The dry outhouse, therefore, presents a low-cost, eco-friendly sanitation solution that embodies the essence of permaculture's closed-loop systems.

The berm shed, a hallmark of permaculture design, is an eco-friendly, earth-sheltered structure renowned for its unique construction techniques. Earthworks are fundamental to its creation, as the surrounding landscape is carefully shaped to form the berm that will encase a portion of the shed's sloping roof. This berm serves a dual purpose, acting as both a natural insulator and a source of thermal mass, effectively regulating the internal temperature. The structural framework of the berm shed is often built using round wood timber framing, a technique that prioritizes using logs instead of conventional dimensional lumber, further enhancing its sustainable appeal. However, the longevity of these logs, especially when in contact with soil, is a crucial consideration. The sources recommend peeling the bark from posts before burying them, a technique born from experience and aimed at minimizing the risk of rot. Another technique for ensuring the durability of the structure involves incorporating gravel into the post holes. The gravel facilitates drainage, preventing water from pooling around the base of the posts and contributing to premature decay. These carefully considered details, combined with the innovative "attic" cell design at the termination ends of the shed, as described in source, showcase a commitment to sustainable building practices that go beyond mere functionality, exemplifying the core principles of permaculture.

WOFATI, an innovative sustainable building technique coined by permaculture advocate Paul Wheaton, stands for Woodland Oehler Freaky-cheap Annualized Thermal Inertia. The design utilizes readily available natural materials like wood and earth to create a "soil on wood" structure that harmonizes with the surrounding woodland. The "freaky-cheap" construction methods pioneered by Mike Oehler and further developed by Wheaton significantly reduce building costs. WOFATI structures are characterized by a double layer of membrane, a "two-skin" system that encapsulates the earthen roof, ensuring dryness and longevity. The principle of Annualized Thermal Inertia is key, using the earth's mass to regulate temperature, providing passive heating in winter and cooling in summer. WOFATI houses feature large windows on the uphill side for optimal passive solar gain, while the downhill side typically boasts a large gable roof, also incorporating glazing for natural light penetration. Allerton Abbey, located at Wheaton Labs, serves as a prime example of a WOFATI house

Dehydrating food with electricity can cost hundreds of dollars, plus heat your house when you don't want heat. A solar dehydrator not only runs for free, but is arguably the most efficient use of solar power. Solar dehydrators can be made from different recycled materials: old refrigerators, reclamed lumber, sheet glass and miscellaneous hardware.

Beyond the foundational elements of WOFATI design, there are advanced concepts that further enhance its effectiveness and versatility. The strategic placement and sizing of windows on the uphill side, for instance, are crucial for optimizing passive solar gain and regulating temperature. The design of the "two-skin" system, incorporating a double layer of membrane, demands careful consideration of materials and installation techniques to ensure long-term dryness and durability. The integration of WOFATI principles with other sustainable technologies, such as rocket mass heaters, offers the potential for a highly efficient and self-sufficient dwelling. The concept of WOFATI extends beyond just houses; variations such as WOFATI coolers and freezers, utilizing specialized venting systems and expanded thermal mass, showcase the adaptability of this approach to address various needs. Furthermore, WOFATI principles can be applied to animal shelters, with specific modifications to accommodate larger spaces and functionality. The ongoing development and experimentation at Wheaton Labs, as seen in projects like Allerton Abbey and Wofati 0.8, continue to push the boundaries of WOFATI design and its potential for sustainable living.