cordwood is one of the best all around natural building styles I have come across especially good for wet coastal areas

check here for more info:
http://www.cordwoodmasonry.com

Cob building tecniques have also been very successful on the coast and well suited to wet climes. There is a company that currently does some beautiful places in the gulf islands.http://www.greenhomebuilding.com/cob.htm
http://www.hobbithomes.ca/

cob is pretty cool but I prefer cordwood, it's less labor intensive, more durable and a little easier to get right, though when dealing with natural building we should be looking at what is most appropriate for the individual site, if there were few trees around but lots of clay then cob would be the way to go

also cordwood works best with nice dry cedar, if one moved onto a piece of land and had not cut any wood but wanted to build a structure now then cob would be the way to go

of course if someone has the time and $ (or lack thereof) they should build whatever they like most

True, the less labour intensive part about cordwood is appealing, but with the open ends of the wood exposed to the elements does it not tend to break down, even if it is cedar? Would plastering in the open ends of the cordwood structure protect it from the onslaught of nature? In the wet, mossy west, I can't see the open ends of those logs lasting too long without concerted effort to keep organisims at bay. In drier climes like Spain I can see it lasting but not here. I dunno, I keep picturing what happens to the end of a felled log that gets left behind in five years.

you can shellac/linseed them, or cob them

cedar will last a long time even if soaked. cedar rail fences last a hundred years or more lying right on the ground.... dried, stacked, and kept off the ground...they last much, much longer.

Check out the link below for rammed earth building technique. The BC company won an award for one of their houses last year.

http://www.greenearthbuilders.com/

peace

http://www.terrafirmabuilders.ca

funky strawbale hybrid
http://www.simondale.net/house/index.htm

http://strawjet.com

StrawJet Technology is a means for using fibrous cellulose material available from agricultural by-products such as straw or many other post-harvest fiber sources, to produce building construction materials.

The fiber cable is a continuous "rope" or "braid" of agricultural waste fiber such as wheat straw, rice straw, or other widely available fiber sources, bundled into a two inch diameter cable. The cable is held tightly together by a wrapping of very high strength synthetic filaments.

It is the ejection of this cable from the rear of the cable engine that gives StrawJet its name.

The "cable" is then fed into either of two material manufacturing processes where it is cut to appropriate lengths and cast into structural members, i.e., posts and beams, or it is cast into building panels which can be very large or very many as required.

The extremely wide variety of agricultural waste fiber sources that can be used for StrawJet cables and the simplicity and flexibility of the casting formula make it easy to make building materials nearly worldwide. The farmer has the opportunity to produce a "second crop" of building materials every year and builders obtain construction components close enough to almost any building site to minimize transportation costs.

The technology is extremely scalable, from a single braid stationary machine to which fiber material (straw) is transported up to large scale combine harvesting equipment producing wide ribbons of parallel cables. Fiber sources range from rice, wheat, or other grain straw to flax to Jerusalem Artichoke. Casting material is similarly available nearly worldwide and is dirt cheap.

The construction materials are virtually fireproof, have excellent thermal insulation properties, and thanks to the high modulus of elasticity achieved using the straw cable for structural strength, are exceptionally earthquake tolerant. The entire manufacturing process is environmentally responsible and highly sustainable. The structural strength of the material is derived from a resource that unlike trees, is renewed annually.

http://www.greenhomebuilding.com/riceland.htm
http://www.greenhomebuilding.com/riceland2.htm
http://www.greenhomebuilding.com/riceland3.htm
http://www.greenhomebuilding.com/earthbag.htm
http://www.calearth.org/EcoDome.htm
http://www.caicosdream.com/build/ebag.html
http://www.earthhandsandhouses.org/projectdome.htm
http://en.wikipedia.org/wiki/Earthbag_construction
http://www.dreamgreenhomes.com/materials/earth/earthbags.htm
http://www.karacadir.com/specialprojects.html
http://www.motherearthliving.com/issues/motherearthliving/green_home/Earthbag-Construction_78-1.html
http://www.okokok.org/

from http://www.freespiritspheres.com

Uses for these durable Spheres are limited only by ones imagination. Healing, meditation, photography, canopy research, leisure and game watching are just some of the things you could do.

Spheres can be hung from the trees as shown or from any other solid objects like buildings or rock faces. A web of rope is connected to any strong points available. This replaces the foundation of a conventional building. A suspended tree house uses the forest for its foundation. The occupants have a vested interest in the health of the grove. The supporting web also mirrors our connectedness to our surroundings. Each sphere has four attachments on top and another four anchor points on the bottom. Each attachment is strong enough to carry the entire sphere and contents.

Wood spheres are made of two laminations of wood strips over laminated wood frames. The outside is then finished and covered with clear fiberglass. The result is a beautiful and very tough skin. Fiberglass shells are also available. The skins are waterproof and strong enough to take the impacts that come with life in a dynamic environment such as the forest. The structural integrity of a sphere and the ability to move and absorb shock loads combine to produce a robust accommodation package.

(*waterproofing required in wet climates...see link below in message #25)

http://www.papercrete.com/
http://www.greenhomebuilding.com/papercrete.htm
http://livinginpaper.com/
http://www.zianet.com/papercrete/
http://en.wikipedia.org/wiki/Papercrete
http://oikos.com/library/papercrete/
http://www.northcoast.com/~tms/papercrete.html
http://www.fiberfoamconcrete.com/
http://screwdecaf.cx/papercrete.html

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tuk5k5FHroM
ZtQZcuSB9CI

http://www.monolithic.com
http://en.wikipedia.org/wiki/Monolithic_dome
http://www.dometech.com/
http://peggyatwood.com/monolithic.shtml
this one survived katrina -> http://www.domeofahome.com/


geodesic domes
http://peggyatwood.com/monolithic.shtml
http://www.thedomeblog.com/

That Simon dale house is very apt......Needs some light tubes though.

from http://www.ecoresources.com.au/ptv2/page8/files/478d9c86112ac72fb9dec395a92a6c9e-6.html

[QUOTE] Hemp Architecture
27/Dec/2005 19:39 | Hemp
J.M. Danenberg B.A. (Hons)

[This paper was delivered to the 1997 Catalyst Conference at the University of Canberra.
It is an abridged version of a paper presented as part of a Masters of Architecture at the University of South Australia. ]


Abstract.

Hemp is an eco-solution; environmentally friendly and solar powered, it's a renewable source of cellulose, fibre and seed oils. This paper will investigate hemp and it's use in construction, and it's role in an emerging sustainable "Carbohydrate economy". The paper is solution-focussed and will include case studies and life cycle analysis of hemp-based products.

keywords: hemp, sustainability, Hemp-mach

from http://tree.org/agston.htm

John Stahl
email: tree@tree.org

Our interest in hemp and other alternative fibers for papermaking has led us to considerable research in the use of these same fibers for building materials. There are a number of approaches towards the use of these fibers in building. Some of them are based upon the model of the wooden board, and various strategies of pressed fiber with heat, pressure, and various binders have been tried with a view to creating a substitute for wooden boards and/or panels.

We are pursuing an alternative approach, which seems to us to be a more ecologically efficient solution, since it is closer to the earth, and seems to offer greater advantages and less cost. The basic idea is to use a preparation of hemp hurds and lime to create a kind of cement ("Agstone") which may be used to construct floors and walls which are stronger and more durable than cement or concrete, yet less brittle and much lighter. It also exhibits superior properties of insulation, waterproofing, and fireproofing, and can effectively replace not only the structural elements of a wall, but it can stand alone without any additional exterior or interior wall covering. In addition to offering all of these benefits, the material is easy to work with, and can end up saving considerable expense when compared with traditional building methods.

We take this technology as it stands at present, and compare it with our idea for papermaking: rather than attempt to make paper from 100% hemp, our idea is to make alternative fiber paper from a mix of hemp and agricultural waste material, in order to further bring down the cost by incorporating all available cellulose material that we can recycle. (See the Alternative Fiber Pulp Mill.) In the same way, we are experimenting with formulas that incorporate the same agricultural waste material into our building material mix. In this way, we hope to evolve building materials that exhibit superior properties combined with ease of use and very low cost.

Our research with this approach began with the use of hemp hurds and lime which we learned about on our visits to the makers of Isochanvre, in France, but since we don't have enough hemp hurds here to work with, we have adapted the idea to the use of other materials: rice straw (a good choice because of the high silica content like hemp hurds) or just about any available chipped up weeds, brush, straw, or other agricultural waste. In the last couple of years we have been implementing these ideas through experimental construction projects.

Over the last couple of years, we have experimented widely with different recipes and procedures for building with Agstone, so it is time to update this article with current ideas about the process and give some general recipes which you can use as a jumping off point for your own investigations.

I express it this way because there are so many possible variations depending upon your intentions, your available materials, your budget, your tools, your time, and your labor that it is impossible to give definitive recipes or procedures. For instance, if you are trying to make the strongest, most durable, and most aesthetically pleasing structure possible, you might elect to use, for example, imported Italian marble. If your intention is more along the lines of building a solid, functional structure using appropriate materials and technology and at the lowest possible cost, you may want to use some of the recipes that follow. But even here there are choices: you can purchase fine clay, sand, fly ash, and rice straw, or you could use your own available sub-soil and whatever weeds and brush you clear from your own property. I follow the latter strategy, intending to use our own available materials whenever possible, even though we realize that better materials can be used. The first principle of appropriate building technology is to use materials that you already have locally, and this is the guiding principle that we attempt to follow.

Before I give actual recipes, let me briefly discuss some of the different approaches to low cost building technologies. Since experimenting with our own methods, I have learned a lot about what others are doing: adobe, cob, straw bale, etc. Earth structures such as adobe and cob represent a very ancient technology of building, and it has many advantages, chiefly low cost, but one disadvantage: it is not really waterproof. While many structures have survived intact for many years, they are usually annually maintained, and/or sealed with a top coat of some sort of lime plaster. Agstone is somewhat similar, except that the addition of lime makes a stronger, more durable, and much more waterproof structure. It has a much harder finish and can be used much like concrete. Straw bale is a very interesting concept, except that all that straw takes up a lot of space, and it needs to be covered anyway. When you consider the interior and exterior covering (for which you might well use a material such as our Agstone), you will probably end up using as much or more of this outer material anyway, so there seems to be little advantage other than the extended insulation. To summarize this brief overview, I have looked at a number of alternatives, and I still favor the approach we have worked out.

While there is a wide variation of possible recipes that will all work, it is useful to have a basic understanding of the chemistry involved with the use of lime. When lime (hydrated lime; calcium hydroxide) is used for an exterior coat, it hardens up by simply combining with the carbon dioxide in the air to change back to the limestone from which it was derived (by burning). However, interior lime hardens up by a different chemical reaction: it combines with materials high in silica to harden up into stone. The classic way to do this is to combine lime with clay. This is "Roman cement," and it is really the origin of the whole idea.

Other sources of silica are also used, but there seems to be no agreement about the chemistry involved. Sand is very high in silica, but because of the particle size, it is less significant than clay. However, I have experimented with mixes higher and lower in sand, and my personal experience is that sand is an essential ingredient in the mix. Mixes with little or no sand are just not as hard or durable as mixes made with plenty of sand. Then there is the question of the silica component in the aggregate, the agricultural waste, weeds, chips, or straw. Hemp hurds are high in silica, and that is probably one of the reasons why the hemp hurds plus lime formula has been such a success in France. My personal experience confirms that hemp hurds perform better than just about any other similar aggregate material. Rice straw is also very high in silica, and, while I have not had personal experience using rice straw, I am confident that it would turn out to be an excellent material for this purpose.

Then there is the sand and clay. This ideally should come altogether if you can find a good subsoil that has a high percentage of clay mixed with sand and silt (no organic matter).

Finally, there is Portland cement. Many purists recommend eschewing the use of Portland cement altogether for technical and religious reasons. I will avoid this controversy here except to mention that the technical arguments suggest that too much Portland cement creates problems, but small amounts of cement mixed with lime avoid those problems. We use about 10% cement in our mix because it works: it helps it to set up quickly, and it assists the chemical reaction with the lime. This small a concentration avoids all of the objections to its use other than its supposedly high environmental cost of manufacture, in terms of fossil fuel use, and the release of CO2 into the atmosphere. Anyway, I have experimented with and without cement, and I have found that using only lime for a binder will usually set up hard eventually, but it may take quite a long time to do so. We haven't yet found a really good local source of clay; perhaps if we did we could effectively eliminate cement from our mix altogether.

My latest addition to the recipe is wood ash. The main reason I want to use it is because there is only so much wood ash I can add to my compost, and I want to use it up. Also, lime is highly alkaline and this high pH is required for the chemical reaction to take place, so it can't hurt to use it.

I draw the line, however, at incorporating old bottles, broken or whole. This may be purely an aesthetic consideration, since the glass may be at least as useful in the mix as the wood ash I want to use up, and it is certainly nice to use your refuse for a building material. Perhaps I may get over this prejudice and start using it. When you have a lot of Agstone to pour, whatever you can throw in to extend the mix saves time and money.

In addition to all of the above, we also use rocks and gravel, especially in the lower courses of our structures. It just makes good sense to use up these rocks where they can do no harm. The more rocks you use up, the less Agstone you will need to use.

Our process allows the use of a much greater quantity of agricultural waste (chips, weeds, or straw) than other methods. We keep changing our recipe, experimenting with new ideas, but the following should give you a very sturdy mix:

For purposes of working out formulas, I always start with one bucket of chips/weeds/straw and call that 10 parts, by volume (we find that formulas measured by volume are much easier to reproduce than formulas by weight). Our mix is as much as 50% chips, weeds, or straw. We use this material because it is freely available and because all those pieces strengthen the mix. We use a random mix, striving for some variation in the size of the pieces. If broken glass is used, that would be part of the 50%.

We used to begin by adding the lime to the chips or weeds, but we have found that it is better to mix up the lime, clay, sand and cement with water and then add the chips or weeds. We recommend three parts of lime (15%), a total sand/clay portion of about five parts (25%), and about two parts Portland cement (10%).

There you have it -- this mix works very well for us, but you can modify it in many directions. You can add chipped up paper and cardboard to extend the mix, but it makes it softer and weaker. You could add more sand and clay, more lime, less cement, broken bottles, floor sweepings, old clothes (shredded), broken toys . . . We pour on site in wooden forms, which are removed the following morning, but you could also press bricks and mortar them together with the above mix, leaving out the chips, weeds, and/or straw.

You can apply a top coat of lime plaster, which is just lime water with fine sand, to smooth out the surface. For a really smooth inner surface, you could add gypsum to the plaster, along with any natural pigments.

May 7, 2002 --

As I look over what I have written earlier, I see that we still use a very similar mix, although we often use even more chips -- up to 2/3 of the total volume.

But I would like to add that, while pouring in forms works just great for foundations, for building walls I would recommend making bricks first. I want to construct a form in three pieces -- a piece of plywood with two permanent 2" x 6" sides attached, and two sets of parallel 2x6" dividers, with interlocking notches, to make up a mold for 64 bricks. Fill the mold with agstone, and the next morning you can gently move the fresh bricks to a spot to finish drying/curing. In this way, you can keep up a production of 64 big bricks per day for a building project (if you need more, use multiple molds).

http://materialicio.us/2007/05/08/grancrete/
http://grancrete.net/videos/
http://slaphog.com/hogblog/?p=43
http://patft.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PALL&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.htm&r=1&f=G&l=50&s1=7160383.PN.&OS=PN/7160383&RS=PN/7160383

http://www.abc.net.au/tv/newinventors/txt/s1296184.htm
http://www.tececo.com
http://en.wikipedia.org/wiki/Eco-cement
http://www.treehugger.com/files/2005/03/ecocement_remov.php

some interesting bucky based domes here -> http://www.sover.net/~triorbtl/index.htm

from http://www.limetechnology.co.uk/pages/hemcrete.php?page_id=21
[QUOTE]http://www.limetechnology.co.uk/upload/images/large/1158763061_miltonparkhempspray.jpg http://www.limetechnology.co.uk/upload/images/large/1173881394_hemcret01.jpg http://www.limetechnology.co.uk/upload/images/large/1173881449_hemcrete03.jpg

Produced mainly from renewable resources, Tradical

Ireland's first hemphouse:
http://www.iol.ie/%7Eoldbuilders/oldbuilders/hemphouse/hemphouse.html

more hemp buildings by the same guys here -> http://www.oldbuilders.com/indexmainpage.htm

I am probably going to go with cordwood but that hempcrete is deadly mon

nice find c-ray

more on hemp-crete (hemp lime actually)
http://www.lhoist.co.uk/tradical/index.html

more about papercrete...it deserves more attention eh Janosh

http://www.evesgarden.org/architecture/
[QUOTE] Papercrete is a building material comprised of a mixture of Portland cement and recycled paper fiber — a light-weight, insulating concrete. The maximum insulating value is obtained when the dry matrix includes the greatest density of air pockets. High strength is obtained when the paper fiber is thoroughly coated by the portland cement.

Cellulose (paper) fibers tend to have great porosity and surface area. This allows for a super saturation when paper is immersed in water. The long paper fibers experience a stack effect, giving the matrix body enough to support the Portland cement which then crystalizes on the three dimensional fiber matrix. The water evaporates and voil

To get an idea how strong paper is just mix up a bucket full of news paper and hot water, then dump it out and let it dry You have a pretty stout paper block that is insulation and soundproofing. Now mix some cement with it and do it again. Now its fire resistant, or proof, depending on how much cement is added. Clay makes it even more fireproof. add sand and it becomes stronger. There are many possible uses. Oh yeah, and it can be pumped and sprayed. There are mold issues, so it's best kept dry as it will absorb moisture unless sealed

em (effective microorganisms) might be an effective mold preventative perhaps replacing 10% of the water in the concrete mix with some AEM (activated EM)...I've come across a few references mostly from Japan and SE Asia

Lime works as well.

asperinka in columbia

http://www.cannabis-world.org/cw/showpost.php?p=95897&postcount=222

first hemp house built in the USA :)

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more hemp house construction

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en francais

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much better than my shed made of soapbar :)

thanks for sharing.

http://thepiratebay.org/torrent/4891416/Sustainable_Housing_from_Natural_Materials


[QUOTE]Design with Nature - Superadobe Homes 1 hr 41 min
How to build with arches, vaults, and domes

World renowned, visionary architect Nader Khalili teaches us the principles of
designing Superadobe structures, from emergency shelters to entire eco-villages and
towns. Khalili shares the secrets of nature's timeless principles and timeless materials.
Using symmetry, harmony and geometry he shows us how to interpret and apply these to
earth architecture. We learn how to build an arch, dome and vault, and to expand this
knowledge into the design and construction of a home or community resistant to fire,
flood, hurricane, earthquake and man-made disasters. We learn practical and simple ways
to design a home that works in harmony with all aspects of nature, such as what to look
for when we arrive at our building site, and how to integrate our design with the wind,
sun, shade, and the land itself. With

http://www.junkboulevard.com/house-build-for-only-5-000/

hobbit house