What is Earthship ?

An Earthship is a type of passive solar home made of natural and recycled materials. Designed and marketed by Earthship Biotecture of Taos, New Mexico, the homes are primarily constructed to work autonomously and are generally made of earth-filled tires, using thermal mass
construction to naturally regulate indoor temperature. They also
usually have their own special natural ventilation system. Earthships
are generally Off-the-grid homes, minimizing their reliance on public utilities and fossil fuels.

The original Earthships' designs were at first very experimental, but
with practice and evolution the houses began looking attractive.

Earthships are built to utilize the available local resources,
especially energy from the Sun. For example, windows on sun-facing walls
admit lighting and heating, and the buildings are often
horseshoe-shaped to maximize natural light and solar-gain during winter
months. The thick, dense inner walls provide thermal mass that
naturally regulates the interior temperature during both cold and hot
outside temperatures.

Internal, non-load-bearing walls are often made of a honeycomb of recycled cans joined by concrete and are referred to as tin can walls. These walls are usually thickly plastered with stucco.
The roof of an Earthship is heavily insulated – often with earth or adobe – for added energy efficiency.



The Earthship, as it exists today, began to take shape in the 1970s. Mike Reynolds,
founder of Earthship Biotecture, a company that specializes in
designing and building Earthships, wanted to create a home that would do
three things; first, it would be sustainable, using material
indigenous to the entire planet as well as recycled materials wherever
possible. Second, the homes would rely on natural energy sources and be
independent from the “grid”, therefore being less susceptible to
natural disasters and free from the electrical and water lines that
Reynolds considered unsightly and wasteful. Finally, it would be
economically feasible for the average person with no specialized
construction skills to be able to create.
Eventually, Reynolds' vision took the form of the common U-shaped
earth-filled tire homes seen today. As a concept, the Earthship was not
limited to tires – any dense material with a potential for thermal
mass, such as concrete, adobe, or stone could theoretically be used to
create an Earthship. However, the earth-rammed tire version of the
Earthship is now the most common design, and is usually the only
structure referred to as “Earthship”.

Unlike
other materials, rammed-earth tires are more accessible to the average
person. Scrap tires are ubiquitous around the world and easy to come
by; there are an estimated 2 billion tires throughout the United
States. As of 1996, as many as 253 million scrap tires were being
generated each year in the United States, with 70% being reclaimed by
the scrap tire market (leaving perhaps 75 million scrap tires available
for reuse as whole tires).^[1]
In addition to the availability of scrap tires, the method by which
they are converted into usable "bricks", the ramming of the earth, is
simple and affordable.
The earth-rammed tires of an Earthship are usually assembled by teams
of two people working together as part of a larger construction team.
One member of the two person team shovels dirt, which usually comes from
the building site, placing it into the tire one scoop at a time. The
second member, who stands on the tire, uses a sledge hammer to pack the
dirt in. The second person moves in a circle around the tire to keep
the dirt even and avoid warping the tire. These rammed earth
tires in an Earthship are made in place because, when properly made,
they weigh as much as 300 pounds and can be very difficult to relocate.
Additional benefits of the rammed earth tire are its great load-bearing capacity and its resistance to fire.
A fully rammed tire, which is about 2 feet 8 inches wide, is massive
enough to surpass conventional requirements for structural load
distribution to the earth. Because the tire is full of soil, it does not
burn when exposed to fire. In 1996 after a fire swept through many
conventional homes in New Mexico, an Earthship discovered in the
aftermath was relatively unharmed.^{[citation needed]} Only the south-facing wall and the roof had burned away, compared to the total destruction of the conventional homes.
Currently, Earthships are in use in almost every state in the United
States, as well as many countries in Europe. The use of insulation on
the outside of tire walls, which was not common in early designs, is
improving the viability of Earthships in every climate without
compromising their durability. In the year 2000, Mike Reynolds, in
partnership with Daren Howarth, launched Earthship Biotecture Europe, an
organization that aims to explore and evolve the concept of the
Earthship within a European context. Two more directors were appointed
to Earthship Biotecture Europe in July 2006 – Kevan Trott and Kirsten
Jacobsen.

 

Europe

In 2004, the very first Earthship in the UK was opened at Kinghorn
Loch in Fife, Scotland. It was built by volunteers of the SCI charity.
In 2005, the first earthship in England was established in Stanmer Park, Brighton with the Low Carbon Trust.
Earthship biotecture has now finalized plans for a planning application to build on a valuable development site overlooking the Brighton Marina
in the UK. The application follows the successful six-month
feasibility study funded by the UK Environment Agency and the Energy
Savings Trust. The application calls for sixteen one, two, and
three-bedroom earthship homes on this site. The homes are all designed
according to basic earthship principles developed in the United States.
15,000 tires will be recycled to construct these homes (the UK burns
approximately 40 million tires each year). The plans include the
enhancement of habitats on the site for lizards
that already live there, which is the reasoning behind entitling the
project "The Lizard". This will be the first development of its kind in
Europe, and successful development in Brighton may help to pave the way for similar projects around the UK and other places.^[2]
The first official Earthship home in mainland Europe with official
planning commission approval was built in a small French village called
Ger. The home, which is owned by Kevan and Gillian Trott, was built in
April 2007 by Kevan, Mike Reynolds and an Earthship Crew from Taos. The
design was modified for a European climate and is seen as the first of
many for the European arena. It is currently used as a holiday home
for eco-tourists.^[3]

 

Africa

The
first earthship was built by Angel and Yvonne Kamp from 1996 to 1998.
They rammed a total of 1,500 tires for the walls. The earthship, near Hermanus, is located in a 60 hectare private nature reserve which is part of a 500000ha area enclosed in a game fence and borders the Walker Bay Nature Reserve.^[4]
Two new projects are also in early development in Africa, an information and training centre in Orania, South Africa^[5] and a residential house in Swaziland.^[6]

 

Systems

The
Earthship was designed as a structure that would exist in harmony with
its environment and be freed from the constraints of modern shelters
which rely on centralized utilities. It is important that the Earthship
create its own utilities as well as use readily available and
sustainable materials. In order to be entirely self-sufficient the
Earthship needs to be able to handle the three systems of water,
electricity, and climate. While these systems are not exclusive to
Earthships, a properly designed Earthship must have these systems.

 

Water

 

Collection

Earthships
are designed to catch and use water from the local environment without
bringing in water from a centralized source. Water used in an
Earthship is harvested from rain, snow and condensation. As water
collects on the roof it is channeled through a silt-catching device and
into a cistern. The cisterns are positioned so they gravity-feed a WOM
(water organization module), that filters out bacteria and
contaminants, and makes it suitable for drinking. The WOM consists of
filters and a DC-pump that are screwed into a panel. Water is then
pushed into a conventional pressure tank to create common household
water pressure. Water collected in this fashion is used for any
household activity except flushing toilets the conventional way.
Rather, the water used for flushing toilets has been used at least once
already: frequently it is filtered waste-water from sinks and showers,
and described as "Greywater".

 

Greywater

Greywater,
water that has been used and is unsuitable for drinking, is used
within the Earthship for a multitude of purposes once it is reclaimed.
First, before the greywater can be reused, it is channeled through a
grease and particle filter/digester and into a 30”-60" deep
rubber-lined botanical cell, a miniature living machine, within the Earthship. This filter with imbedded plants can potentially also be used to produce food (by using a fruit tree, ...). Oxygenation, filtration, transpiration,
and bacteria-encounter all take place within the cell and help to
cleanse the water (Reynolds 2000). Within the botanical cell, filtration
is achieved by passing the water through a mixture of gravel and plant
roots. Because of the nature of plants, oxygen is added to the water
as it filters, while nitrogen is removed. Water taken up through the
plants and transpired at their tops helps to humidify the air. In the
cell, bacteria will naturally grow and help to cleanse the water.
Water from the low end of the botanical cell is then directed through a
peat-moss filter and collected in a reservoir or well. This reclaimed
water is then passed once more through a greywater board and used to
flush conventional toilets.
Often, any greywater that is made at earthships is not polluted enough
to justify treatment (its "pollution" being usually just soap, which is
often not environmentally damaging). At earthships, the use of plants
placed at outlets of fixtures is then practiced to regain the water and
the nutrients lost (from the soaps, etc.).. Usually, a single plant is
placed directly in front of the pipe, but mini drain-fields are also
sometimes used. The pipe is made large enough (5,08 cm) so that the
formation of underground gas (from the greywater) is avoided. This is
done with kitchen and bathroom sinks, and even showers, washing
machines, and dishwashing machines. The plants are usually placed
indoors with the sinks and outdoors with the washing/dishwashing
machines and shower (to avoid indoor "floods"). Also, with the latter,
larger drain-fields are used instead of a mere plant being placed before
an outlet.^[7][8]

 

Black water

Black water,
water that has been used in a toilet, was usually not created within
many of the earliest earthships as the use of conventional toilets was
discouraged.^[9] Instead, in the early days composting toilets
were advocated, which use no water at all. However, with the new
greywater treatment system design (used in Nautilus, Helios, ...)
created by Michael Reynolds, flush toilets have now found a place in the
earthship and the general water system has been redesigned according
to the new "6-step process".^[10][11]
Now, when the newly included flush-toilets are used, blackwater is not
reused within the Earthship. Instead, blackwater is sent to a
solar-enhanced septic tank with leach-field and planter cells (the whole
being often referred to as the “incubator”). The solar-enhanced septic
tank is a regular septic tank
which is heated by the sun and glazed with an equator-facing window.
The incubator stores the sun's heat in its concrete mass, and is
insulated, to help the anaerobic process. Water from the incubator is
channeled out to an exterior leach field
and then to landscaping "planter cells" (spaces surrounded by concrete
in which plants have been put). The cells are similar to the botanical
cell used in greywater treatment and are usually placed just before
and under the windows of the earthship.
In cases where it is not possible to use flush-toilets operating on water, dry solar toilets are now advocated, instead of regular composting toilets.
If this is the case, obviously no black water is formed and the use of
an incubator is thus (usually) not necessary. Instead, regular
"planters" (plants used for sucking up water/nutrients) are then used.
When using regular planters as well, no chemical soaps or detergents can
be used.
The space where the WOM (water organization module), graywater pump
panel, pressure tank, (first set of) batteries, and POM (power
organising module) are stored is in a small room referred to as the
"systems package".

 

Electricity

Earthships
are designed to collect and store their own energy from a variety of
sources. The majority of electrical energy is harvested from the sun
and wind. Photovoltaic panels and windturbines located on or near the Earthship generate DC energy that is then stored in several types of deep-cycle batteries.
The space in which the batteries are kept is usually a special,
purpose-built room placed on the roof. Additional energy, if required,
can be obtained from gasoline-powered generators or by integrating with
the city grid.
In an Earthship, a Power Organizing Module is used to take stored energy from batteries and invert
it for AC use. The Power Organizing Module is a prefabricated system
provided by Earthship Biotecture that is simply attached to a wall on
the interior of the Earthship and wired in a conventional manner. It
includes the necessary equipment such as circuit breakers and converters.
The energy run through the Power Organizing Module can be used to run
any house-hold appliance including washing machines, computers, kitchen
appliances, print machines, vacuums, etc. Generally, none of the
electrical energy in an Earthship is used for heating or cooling.^{[12][not in citation given]}

 

Climate

The
interior climate of an Earthship is stabilized and made comfortable by
taking advantage of many phenomena. Mainly, the Earthship tries to
take advantage of the properties of thermal mass and passive solar
heating and cooling. Examples are large front windows with integrated shades, trombe walls and other technologies such as skylights or Track Rack solar trackers (dualling as an energy generation device and passive solar source.
The load-bearing walls of an Earthship, which are made from steel-belted tires rammed with earth, serve two purposes. First, they hold up the roof, and second, they provide a dense thermal mass
that will soak up heat during the day and radiate heat during the
night, keeping the interior climate relatively comfortable all day.
In addition to high thermal mass, some Earthships may be earth-sheltered.
The benefits of earth-sheltering are twofold because it adds to the
thermal mass and, if the Earthship is buried deep enough, allows the
structure to take advantage of the Earth's stable temperature.
The Earthship is designed in such a way that the sun provides heating,
ventilation, and lighting. To take advantage of the sun, an Earthship
is positioned so that its principal wall, which is nonstructural and
made mostly of glass sheets, faces directly towards the equator. This
positioning allows for optimum solar exposure.
To allow the sun to heat the mass of the Earthship, the
solar-orientated wall is angled so that it is perpendicular to light
from the winter sun. This allows for maximum exposure in the winter,
when heat is wanted, and lesser exposure in the summer, when heat is to
be avoided. Some Earthships, especially those built in colder climates,
use insulated shading on the solar-orientated wall to reduce heat loss
during the night (Reynolds 2000).

 

Natural ventilation

The earthships usually use their own natural ventilation
system. It consists of cold(er) air coming in from a front ("hopper")
window, especially made for this purpose and flowing out through (one
of) the skylights that are placed on the earthship. As hot air rises,
the system maintains itself and keeps sucking in (and out), air.

 

Heating problems

Earthships
rely on a balance between the solar heat gain and the ability of the
tire walls and subsoil to transport and store heat. The design intends
to require little if any auxiliary heat. Some earthships have suffered
from over-heating and some from over-cooling.
Some earthships appear to have serious problems with heat loss. In
these cases heat appears to be leaking into the ground constantly during
the heating season and being lost. This situation may have arisen from
the mistaken belief that ground-coupled structures (building in
thermal contact with the ground) do not require insulation. The
situation may also be due to large climatic differences between the
sunny, arid, and warm Southwest (of the USA) where earthships were
first built and the cloudier, cooler, and wetter climates where some
are now being built. Malcolm Wells, an architect and authority on earth-sheltered design, recommends R-value
10 insulation between deep soils and heated spaces. Wells's insulation
recommendations increase as the depth of the soil decreases.
In very limited and specific situations, uncommon during the heating season, thermal mass can marginally increase the apparent R-value of a building assembly such as a wall. Generally speaking thermal mass and R-value
are distinct thermodynamic properties and should not be equated.
Thermal performance problems apparently seen in some earthship designs
may have occurred because of thermal mass being erroneously equated to
R-value. The R-value of soil is about 1 per foot.^[13]

 

Potential advantages

• Having an earth-bermed home with windows facing the sun is a good idea in any climate where heating is required.
• Collecting rainwater that falls on the roof reduces the runoff impact of the building and may reduce water and even sewer service fees.
• Having a combination of photovoltaic cells and wind generation is a prudent way to provide electricity in many situations.
• Using curved modules as horizontal arches to resist earth loads is a sound structural design.
• On-site processing of runoff water, grey water, and black water using plant beds reduces the environmental impact of the building.
• Rubber tires make a wind- and puncture- resistant wall. They may be safe from outgassing when plastered semi-airtight.
• Rubber tires are usually free and it may be possible to be paid to take them. It also is beneficial to keep them out of landfills or prevent them from being illegally burnt.
• Potential to eliminate utility bills.
• The structure is highly moldable to different aesthetic tastes.

 

Potential disadvantages

• The sloped glazing may be hard to keep watertight and in warm climates allows excessive solar gain in summer. In colder climates, the glazing
  itself, which has far poorer insulating properties than any other
  component, will obviously be the major conduit of heat loss in winter.
  New designs call for vertical windows with an overhang.
• Uninsulated ground-coupled thermal mass presents a large potential for heat loss, especially in climates with a heating season. This varies to a degree with soil type and moisture content.^{[citation needed]}
• Rubber-tire walls tend to lack structural stiffness and may require perpendicular stiffening ribs.^{[citation needed]}
• Most solar photovoltaic systems suffer from poor efficiency and some wind systems only generate in periods of high wind velocity.
• The novel design may diminish resale value or make buyers more difficult to find.
• The intimate ground contact inherent in this approach may increase hazards due to soil gases including Radon, and those due to water intrusion.
• Packing or ramming dirt into the inside of tires is a very labor-intensive process.
• Many Earthship builders are drawn to this system by its apparently low environmental impact. However, this is only valid if the design is highly thermally efficient. Earthship designs may require substantial
  thermal analysis and redesign to be adapted to non-Southwest USA
  climate.
• Earthships built with concrete, sand bags, or adobe and with better solar and heat control perform better.^{[citation needed]}
• Earthships are usually built in areas of extremely low population density, so unless they are entirely self-sufficient, a significant amount of fossil fuels could have to be expended in their construction
  because of the transportation of materials and workers. They can be
  built anywhere, however, and this can mitigate certain issues dealing
  with fossil fuels and transportation.