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Dwelling by Nader Khalili of Cal-Earth

Dome by Nader Khalili at Cal-Earth. This is the meeting house, extraordinary work. The brickwork is stunning, the space is intimate yet formal, and the plants emanating from/spilling into the oculus at the top is a wonderful foil to the geometry of the architecture !

Earth One, two series of vaults side by side. Using compressed earth bags. May be possible using CEB Press bricks.

Construction of the Eco Dome. For each room a string is staked to ground in the at the center of curvature, the string is then used as a guide as the structure is built up so that each layer is evenly distributed.

Basics

From: EarthBagBuilding.com

Building with earthbags (sometimes called sandbags) is both old and new. Sandbags have long been used, particularly by the military, for creating strong, protective barriers, or for flood control. The same reasons that make them useful for these applications carry over to creating housing. Since the walls are so substantial, they resist all kinds of severe weather (or even bullets) and also stand up to natural calamities such as earthquakes and floods. They can be erected simply and quickly with readily available components, for very little money.

Earthbag building fills a unique niche in the quest for sustainable architecture. The bags can be filled with local, natural materials, which lowers the embodied energy commonly associated with the manufacture and transportation of building materials. The fill material is generally of mineral composition and is not subject to decomposition (even when damp), attractive to vermin, or burnable...in other word it is extremely durable. The fill material is generally completely non-toxic and will not offgas noxious fumes into the building.

Earthbags have the tremendous advantage of providing either thermal mass or insulation, depending on what the bags are filled with. When filled with soil they provide thermal mass, but when filled with lighter weight materials, such as crushed volcanic stone, perlite, vermiculite, or rice hulls, they provide insulation. The bags can even act as natural non-wicking, somewhat insulated foundations when they are filled with gravel.

Because the earthbags can be stacked in a wide variety of shapes, including domes, they have the potential to virtually eliminate the need for common tensile materials in the structure, especially the wood and steel often used for roofs. This not only saves more energy (and pollution), but also helps save our forests, which are increasingly necessary for sequestering carbon.

Another aspect of sustainability is found in the economy of this method. The fill material can be literally "dirt cheap," especially if on-site soil is used. The earthbags themselves can often be purchased as misprints or recycled grain sacks, but even when new are not particularly expensive. Burlap bags were traditionally used for this purpose, and they work fine but are subject to rot. Polypropylene bags have superior strength and durability, as long as they are kept away from too much sunlight. For permanent housing the bags should be covered with some kind of plaster for protection, but this plaster can also be earthen and not particularly costly.

The ease and simplicity of building with earthbags should also be mentioned, since there is much unskilled labor available around the world that can be tapped for using this technology. One person familiar with the basics of earthbag building can easily train others to assist in the erection of a building. This not only makes the process more affordable, but also more feasible in remote areas where many common building skills are not to be found.

Advantages

• Faster, easier and thinner than earthship building
• Since you can fill the bags with rubble, you're improving the environment by using rubble, otherwise it would be waste.
• very inexpensive
• environmentally friendly, since most of the construction materials are produced on site

Disadvantages

• requirement for multiple buttresses
• difficulty in making long straight walls that are stable
• polyethylene bags may degrade very rapidly even when briefly exposed to sunlight during construction
  • As Owen Geiger says, bags are so resistant if they're protected. So, as the houses are usually covered with earth, adobe or stucco, they're durable

Terminology

• Contained earth (CE) is based on the original technique, but with specific soil strengths and reinforcement chosen for hazard levels. CE uses damp, cohesive, tamped bag fill, which bonds strongly with barbed wire and other reinforcement as the wall cures.
• CE is not "sandbags". Contained sand (CS) uses sand fill or any fill too dry or with poor cohesion that performs structurally like sandbags. CS must be built with solid-weave fabric bags and have good protection from fabric damage, relying on the strength of the bag fabric for wall strength.
• CS needs more vertical reinforcement for both shear and out-of-plane strength than CE, or may require a structural skin. Some builders use narrow bags of contained sand as wall infill.
• Contained gravel (CG) uses fill of any aggregate larger than coarse sand, usually in doubled rice bags, although strong mesh can be used. CG limits dampness transmission from footings.

Modular CE vs Solid CE=

• Modular uses "modules" (Similar to Concrete Masonry Units / Precast Concrete in concept) such as
  • Grain Bags
  • Smaller Fabric or Geotextile Tubes
• Solid CE is Hyperadobe built in large continuous tubes making almost monolithic "layers" in a similar manner to a Construction 3D Printer

Internal Links

• Contained Sand
• Contained Gravel
• Contained Carbon
• Mechanically Stabilized Earth
• Cellular Confinement
• Sand Bags
• HESCO Bastion

External Links

• The Wikipedia Page on Earthbag Construction
• Cal-Earth - The California Institute of Earth Art and Architecture
• Instructables: How to Build an Earthbag Dome step by step
• blog with more info
• Hyperadobe - an extension of and improvement on earth bag building