vitro house

image by Luis de Garrido

all information from http://www.archilovers.com/p43874/Vitrohouse-Eco-House#info

Facts

VITROHOUSE ECO-HOUSE

2005

ANAVIF. Construmat 2005

Barcelona

126 m2

€ 138,000

image by Luis de Garrido

Description

1. Most Important Goals

- Build a habitable dwelling, entirely made of glass, as the only material, including the supporting structure. The idea is to show the untapped possibilities-glass-construction. Hence, all elements are glass housing (including columns, beams, decks, fireplaces, floors, walls, furniture, appliances, bathrooms, decorative ...).

- Experience with glass as a structural material. The ultimate goal is to define a technical standard, and a process of structural design and dimensions, base only, glass elements.

- Designing a home with the highest possible degree of sustainability, despite the difficulty of using mostly glass building. The intention is to invite reflection on all the features you must have a building to be 100% sustainable. 

- Ask a virtual home, multimedia, equipped with the latest advances in control technology, telecommunications, air conditioning and lighting. The aim is to experiment with light, sound, multimedia projections and glass, so that transcend physical spaces in virtual spaces, and the matter is diluted into light and sound.

- Achieving a self-sufficient housing, constructed of standard elements of flat glass.

- To design all the furniture, health and housing supplements, based solely on flat glass. Of course, these elements must be fully functional and ergonomic.

- Design a removable housing that can be built in protected natural environments, and is perfectly integrated into the environment.

image by Luis de Garrido

2. Architectural Solution

The prototype includes the construction of the house (126 m2) as its outer urban areas (314 m2).

The house is divided into three zones:

- A core set of 42 m2, for work activities in the home. This is the area where heat is generated in winter (greenhouse double skin of glass and solar control glass cover) and cool in summer (by air from the wind sensor).

- Two lateral bodies of 42 m2 each. A body hosts the sleeping area (bedrooms and bathrooms) and the other the living area (living room and kitchen).

image by Luis de Garrido

3. Sustainable Analysis

1. Resource Optimization

Maximum degree of recyclability

Glass is easily recyclable material, and requires very little energy to it. The recyclability of a material means little regard to their sustainability, as the vast majority of materials are recyclable. What is really true is that a material is recyclable using very little energy and resources. For example, aluminum can be recycled, but the energy required is very high, much higher even than the collection of almost any other material.

Ato degree of naturalness

Glass is a material that is generated naturally in nature, and requires relatively little energy to be produced from abundant materials and through a simple process. Thus the degree of naturalness is high.

Abundance

The Glass is very heavy and will remain, as the raw material for manufacturing, silica, is one of the most abundant of nature.

Reuse

The prototype has been designed with prefabricated elements so that, after dismantling, can be reused for anything else. The glass pieces are designed with little variety of sizes, so you can exchange your position, and are easily repairable. He has designed an ingenious structural system, so that the windows do not even need to be bored, so it is easier to reuse later. Only used a simple hardware-faint-gravity to hold the glass. The hardware is capable of holding all the parts without holes or lines, ensuring resistance to vertical and horizontal loads to bear argo of life. This hardware is perhaps the greatest achievement of the prototype.

No toxicity

The glass has no toxic component at all that can alter human health and the planet. Adhesives have been chosen just as well as silkscreen paintings used.

High durability

The durability of the glass is extraordinarily high. There are no comprehensive data that can last a tempered glass or laminated glass, but suitably treated, is the most durable materials.

Similarly, the prototype is designed so that, taken together, can have an infinite life cycle and natural environments. To do this, we designed a structural system and construction in which all parts can be replaced at any time for another of equal or better features, at the time they stopped being useful. Just as different parts are easily replaceable. No holes, no hardware to replace parts just have to loosen it and remove it.

image by Luis de Garrido

2. Waste and Emissions Reduction

In the manufacture of materials

For the manufacture of glass does not generate any waste, as the remaining scraps are recycled continuously. Similarly, virtually no environmental emissions.

In building the prototype

No waste of any kind generated in the assembly of the prototype. The pieces have been cut with pinpoint accuracy, and have used them all. Most materials have been served on site without packaging, and the few existing packages have been designed to carry elements of the house back to the factory, once you remove the prototype.

In the life of the building

There is no residue and no emissions during the life of the prototype. Keep in mind that the prototype has been designed to have an infinite lifetime, ie an infinite life cycle.

In the dismantling

The prototype has been designed so as not to generate almost no waste in its dismantling. Applying heat with a wire will remove the few adhesives used (inert nature and biodegradable). The remaining materials will remain intact and ready to be reused as many times as necessary.

image by Luis de Garrido

3. Energy Reduction

Obtaining materials

Energy consumption for obtaining the glass is half (aprox.17 mJ / kg.) Compared to other materials. Materials such as concrete, ceramic or stone with less power consumption. In contrast, the production of other materials such as steel, aluminum, plastics, paints, varnishes or isolates implies a much higher energy consumption. In addition, the parts designed for the prototype have little dimensional variation and repeated, therefore, the energy cost needed is minimal.

Construction

We used only pieces of flat glass (laminated and tempered), so that the number of pieces as small as possible, has the fewest number of different pieces and parts are placed as quickly as possible (and with the least amount possible labor and auxiliary machinery).

Dismantling

The dismantling is very simple and consumes very little power. You only need to remove the adhesive with a wire and pick up one by one each piece of glass (which need not broken or damaged).

Transportation of material and labor

The materials and labor have been local. There has been no need for skilled labor.

Life

Despite being built solely of glass, the prototype has an adequate thermal performance. Of course the fact that we chose glass as the only material-a priori implies severe restrictions on energy efficiency of the prototype (eg, decks and glass walls would inevitably generate a significant warming of summer days building at same time involving a low thermal insulation). However, they have used a set of bioclimatic strategies that have offset these deficiencies and have allowed a proper thermal performance and high energy efficiency.

The prototype has a zero energy consumption of non-renewable. The prototype generates hot water (via solar thermal sensors), electricity (via solar photovoltaic sensors and wind turbines), heat (greenhouse effect), and cool (by geothermal architectural devices).

4. Improved health and well-being

All materials used are environmentally friendly and healthy and have no emissions that can affect human health. Similarly, the building is naturally ventilated, and maximizing natural light, creating a healthy environment and provides the best possible quality of life for its occupants.

5. Reduced price of the building and maintenance

The prototype maintenance costs are very low. The only short-term maintenance is cleaning, because the transparent nature of glass and semi-transparent. However, treatment of the glass and the design of each component part has been done to minimize this section. To reduce the degree of breakage or damage, given the fragility of glass, are suitably designed supports and elastic joints of the structure. As maintenance personnel of the prototype was not necessary

5. Bioclimatic characteristics

For the prototype design have been carefully chosen a set of architectural strategies that have resulted in a bioclimatic architectural style perfectly.

image by Luis de Garrido

image by Luis de Garrido

1. Orientation.

The orientation of the prototype has been made to the south, in order to ensure both the greatest number of hours of sunlight, as solar control architectural possibility (without control technologies or other artifacts).

2. Tripartite typology.

We have chosen a tripartite typology, so that both the area day and night area are geared towards the central body (covered patio). Precisely this is the central body that ensures cool in summer and heat generation in winter. In winter, close the glazing elements of the double skin of glass, making the central space in a huge greenhouse, which heats the other rooms of the prototype.

1. Solar control.

Sunscreens on the south side preventing sun rays from entering in summer but allow winter coming. In the sleeping area of ​​the prototype has been installed a double skin of glass with a shutter on the inside that allows you to control the passage of sunlight into the building. In contrast, in the day, the solar control system chosen has been the willingness of a set of horizontal slats stained glass (the darker the better) with dimensions that allow the sun passes in winter, but not in summer.

In summer the outside folds of the double skin, which allows, along with sunscreens, the sun's rays do not enter the glass from the inside. This prevents overheating of the prototype.

The sloping roof panel has on its inner face a special film of sunscreen, so that filters out a good amount of light passing through glass. This will minimize the heat gains in summer, while increasing thermal insulation in winter.

4. Air Cooling System

The cooler air is absorbed northern winds by the captor, cool shade under the floor inside the prototype and is distributed by the false floors. But for those days when you can not cool the air by architectural means, the wind sensor has a built-in mechanical and thermal conditioning ecological,. The chosen system is energy efficient, generating ionization, oxygenation and bactericide. Fresh air to circulate through the entire house inside out has an ingenious system of natural convection "chimney effect".

5. Isolation.

The wall insulation has been achieved by incorporating a double skin of glass. This is achieved by a ventilated chamber can even be filled with insulating material to ensure proper insulation. On the other side for the insulation of roofs have followed two different strategies. A deck is covered with natural soil with vegetation, which guarantees the shading of the prototype, its isolation and thermal inertia. The other cover is filled with water, which is stored underneath the house cool summer nights (in a buried tank) and is pumped into the deck during the day, allowing the interior refresh.

6. Thermal inertia.

The house has a large thermal inertia that allows the generated cool summer nights continue throughout the next day. On the other hand, the heat produced by the greenhouse effect (and others) during the winter days, is conserved throughout the night. The high thermal mass has been achieved due to the large mass of glass panels, and the large mass of water and land included in the covers of the housing.

7. Renewable energy.

As sources of energy has turned to solar energy (thermal and photovoltaic) and wind energy. Solar thermal energy is used for hot water, while solar photovoltaic and wind power for electricity consumption of the prototype. In a real case, the electricity generated would be sold directly to power supply companies, so that energy efficiency is multiplied almost fourfold due to the difference in price between energy sold and to purchase (system network connection). It should be noted the new system for photovoltaic generation of electricity: double laminated glass panels that make photovoltaic cells. This will reduce costs and ensure the correct inclination of the photovoltaic cells (about 30 degrees in our latitude) to be effective.

image by Luis de Garrido

5. Highlights Innovations

- Construction of glass. The prototype shows the potential of glass as a structural material in construction, but also to provide sustainable, decorative and insulating ... He has experimented with all kinds of glass and constructive solutions to achieve a sturdy, stable, adequate heat and 100% functional.

- Land cover and aquarium. To increase the thermal inertia, there are two types of coverage: a garden of water and other circadian cycles. On the cover of water, has provided an aquarium, while providing a show for the home users.

- Integration of alternative energies. They have integrated seamlessly into the architecture of the house alternative energy devices like solar thermal and photovoltaic sensors and wind generators. Laminated glass panels of the central pitched roof including photovoltaic cells.

- Ecological mechanical conditioning system. Environmental conditioning equipment installed has a bactericide, and ionization of oxygen and a heat exchanger.

- Multimedia technology. A set of video projectors, robots projectors, speakers and synthesizers seamlessly integrated and coordinated with the home automation control system can produce a multimedia show continued in all the architectural elements of the house. Architectural spaces are defined at all times by the lighting and multimedia information, and continuously change according to environmental conditions (temperature, humidity, noise, number of people ...). Even the privacy and functionality of the different living spaces can be changed by changing only the level of lighting in each room.

- Flexible structure. To respond to changing needs, spaces are easily renewable, thanks to the kitchen and bathroom are relocatable, electrical, water and sewer flexible, soils recordable media ethereal spaces and mobile toilets and a new functionality.

- Lighting option. The lighting of the house was made with an intelligent low-energy lighting by LEDs. Among many other innovations, have been used transparent glass walls lit with LEDs inside, and new materials backlit, halfway between the ceramics and glass.

- Furniture and sanitary glass. Both furniture and the bathrooms are made with flat glass postemplado. They have a unique aesthetic, play with light effects and are perfectly integrated into the architecture.

- Building system that lets you build a house in 5 weeks.

image by Luis de Garrido

hotel room drop eco-hotel

image by estudibasic

all information from http://www.in-tenta.com/index.php/design-works/item/105-drop-eco-hotel

Description

DROP eco-hotel is a removable modular hotel room. A new travel and leisure concept and a different hotel experience. It is a concept that fits between a caravan and a permanent room in a traditional building. The idea is that this unit can be placed in a beauty spot, but then easily removed without any ecological damage as a consequence of its presence. Its design draws inspiration from organic shapes found in nature. The use of lightweight materials allows the modules to be installed on a great variety of terrains and to be transported to remote natural locations: remote forests, beaches, mountains, jungles... DROP is fully built in a factory and then transported to their final location by truck. For the modern nomad, these eco-friendly rooms are not only sustainable but surprisingly comfortable and perfectly integrated on the natural surroundings. DROP is especially suitable for anyone who has an inherent yearning for nature but doesn’t want to cause a negative impact on the environment.

image by estudibasic

The structure is composed of modular prefabricated wooden and steel elements. This fully mobile microarchitecture is specifically designed to be installed with a minimum impact on the environment. The structure's base is elevated from the ground, on adjustable steel legs, to adapt to the irregular terrains and minimize the contact with the unspoilt land. A notable feature of the design is the large bubble windows at the ends of the central cylindrical tube. These operable spherical transparent windows can be opened to bring guests into direct contact with nature, removing the barrier between indoors and outdoors and providing natural ventilation. A skylight running the entire length of the pod provides ample daylighting and sky views. Each green hotel unit can comfortably accommodate two adults. Despite its small size, 25 square meter, there is space for a lounge area and a bedroom at night in the same shared space, as well as a separate bathroom with toilet, shower and bath. A wood terrace offers outdoor seating.

image by estudibasic

Some of the many green features that are planned for these portable hotel rooms include thin photovoltaic solar films on the roof that can be combined with wood siding for power generation. A rainwater collection system harvests water for use in the bathroom, further reducing its environmental impact.

image by estudibasic

The aim of Drop eco-hotel is to meet the growing demand for eco-tourism around the world with customers who demand sustainable architecture and a high degree of design. The DROP concept won a design contest organized by the urban furniture and microarchitecture manufacturer URBAN SQUARE, the brand design network O-cults and the Architecture office Ricardo Bofill Taller de Arquitectura.

image by estudibasic

Facts

2012 - microarchitecture

DROP eco-hotel together with DROP XL are removable modular hotel rooms that draw inspiration from organic shapes found in nature.

Client: URBAN SQUARE

image by estudibasic

cheops eco-house

image by Luis de Garrido

all information from http://www.archello.com/en/project/cheops-eco-house

Cheops Eco-House is a symbolic, iconic and self-sufficient Museum of human behavior. For this reason it has been dedicated to the prestigious British researcher Richard Wiseman. 

Cheops Eco-House is located at the top of the pyramid of Cheops, in Cairo, Egypt. The goal is to build the most important museum in the history of mankind, in the most emblematic place on the planet. As in reality little is known about human behavior, there is little to be displayed in the museum, so that only multimedia equipment and a continuous connection to the global network is needed. Thus, more than a museum, Cheops Eco-House aims to be a unique place for meditation. A place of pilgrimage for all those who want to transcend as humans, and wish to meditate about the future of mankind and the human network on the planet Earth. 

image by Luis de Garrido

Therefore, in reality what has been set out to be built is the world's most iconic building, which is representative of all humans. 

Given this responsibility, Cheops Eco-House has been designed using an extensive repertoire of symbolic mathematical proportions: 

1. The mathematical proportions (harmonic and cosmic) used in the design of the Great Pyramid of Cheops. 

2. The human scale units of measurement (The “elbow” and others) used in the construction of the Great Pyramid of Cheops. 

3. The symbolic and mystical relationships used in the design of the Great Pyramid of Cheops. 

Cheops Eco-House is perfectly integrated into nature, it has an infinite life cycle, has zero energy consumption, and does not generate waste and emissions. In addition, it can be dismounted at any time, without having a trace and without causing any environmental impact.

The building is self-sufficient in energy, water and food, and perhaps its most striking feature is the large organic garden installed on the entire surface of the east face of the Great Pyramid of Cheops. A garden that ensures the basic supply of food for the occupants of the building and their neighbors. 

image by Luis de Garrido

1. Architectural Solution 

Cheops Eco-House has pyramidal shape with a square layout (13.9 m. * 13.9 m.), with a height 1/7 of the height of the pyramid of Cheops, and volumetric lines of the original pyramid, before the external limestone blocks had deteriorated and fallen off over time. For this reason a gap between the pyramid and the building has been created, that gives it a strong symbolic character, but at the same time is the reason of its perfect bioclimatic behavior. The building is built by a set of horizontal perimeter strips (slats), made of stainless steel, joined on its inner face by glass panels, shaping a pyramid. 

Access to the museum is via a shuttle lift similar to the one used by the Egyptians in the construction of the pyramid of Cheops. The building has a very small living space and has the needed equipment for a family to live comfortably. The goal is that anyone can spend a period of time in the building, with access to all kinds of meta-knowledge that allows them to get to know themselves, transcend as humans, and view their role as part of the future human network. 

image by Luis de Garrido

2. Most important characteristics 

1. Self-sufficiency in energy 

Cheops Eco-House is self-sufficient in energy. That is a connection to the mains is not necessary. 

This energy self-sufficiency has been achieved through a set of complementary strategies: 

1. An excellent bioclimatic design has been carried out to minimize the need for energy. The pyramid-shaped building, made of stainless steel horizontal slats, creates a stable microclimate inside ensuring the welfare of its occupants. In addition, in the design of building all sorts of bioclimatic strategies have been used to naturally ventilate and thermally self-regulate throughout the year without the need of technologic devices, and therefore without any energy consumption. As a result of its special self-regulating design, the building is cooled by itself in summer and warmed by itself in winter. Similarly, during the day the building is naturally lit, every day of the year, without the use of artificial lighting. 

image by Luis de Garrido

The used bioclimatic strategies have been as follows: 

a. Appropriate architectural typology 

The building is pyramid-shaped made of spaced horizontal slats. The building is placed on the pyramid of Cheops, allowing for a ventilated space in between, which protects the top of the pyramid from solar radiation, and capable of cushioning thermal changes. The building has four faces aligned with the cardinal axes, so that each side can be designed independently in order to take advantage of solar radiation, or achieve the maximum solar protection. 

image by Luis de Garrido

b. Shading 

The building is formed by horizontal slats that act as sunscreens. These slats are carefully dimensioned, so that in summer, on the south facade, the direct solar radiation does not enter into the building, while in winter the maximum amount enters. Similarly, internal blinds control the indirect solar radiation. There are opaque internal blinds on the east and west side of the building and translucent blinds on the south side. Thus, the building remains naturally lit (by indirect sunlight) without becoming warm. 

The slats situated on the lower part of the building (2/3 of its height) of the north and south faces are spaced, and the slats located on the top (1/3 of its height) are joined by an internal double glass. 

image by Luis de Garrido

Moreover the slats located in the lower part (2/3 of its height) of the east and west sides are separated by an internal metallic grid that protects the pyramid from solar radiation, and the slats located on the top (1/3 of its height) are joined by an internal double paned high solar reflection glass to protect the building from direct sunlight in the morning and evening. 

image by Luis de Garrido

c. Glass with high insulation capacity 

The double paned glass used (6-14-4) has a large internal air chamber, and thus a high insulation capacity. Thus, during the winter it keeps the heat (generated by solar radiation and greenhouse effect), and maintains the building warm throughout the day. On the other hand, during the summer it keeps the cool (generated due to the drop in temperature overnight, and low temperatures inside the pyramid of Cheops), and maintains the building cool all day. 

d. The greenhouse effect 

The south facade has a large glass area, which allows the building heated by direct exposure to solar radiation and greenhouse. The greenhouse effect is maximum in winter, but is not generated in summer because the calculated separation between the compositional slats. In winter the building is heated by the greenhouse effect during the day, and the heat builds up in the stone blocks above the apex of the pyramid of Cheops. 

image by Luis de Garrido

e. Natural ventilation 

The building is naturally ventilated in a continuous manner, through the perimeter space created between the pyramid and the slats of the building. This space continuously generates a volume of warm air, which acts as a heat exchanger, so that the ventilation air enters into the building with a suitable temperature. 

In summer, the slats create a shaded space that protects the pyramid from solar radiation. Thus the pyramid remains cool (cooled due to the falling temperatures overnight), and refreshes the air pocket between it and the slats. Finally, this cool air enters the building through perimeter vents. 

In winter, the slats allow solar radiation to enter, which heats the surface layers of the pyramid of Cheops. Thus the pyramid heats the air layer between it and the slats (which protects the layer of air). 

f. Removing the hot interior air by means of stack effect. 

The hot air generated inside the building rises to reach the apex. In this vertex are 8 holes specially designed to allow air to easily pass, but avoids rain from entering. 

The solar radiation heats the air in the upper housing part (where the glass has no sun protection and no blinds), and therefore rises and creates a suction stream, extracting hot air from the housing, and forcing fresh air from the lower perimeter galleries to enter into the building, and cooling it in its path. 

g. Harnessing the night coolness. 

This is the most efficient mechanism to cool a building in summer. 

At night, in summer, the surface of the pyramid of Cheops becomes cool (inside remains at an average temperature of 18 º C). The cool night air is introduced into the building, and cools it in its path. The building remains fresh during the next day, because of its high thermal inertia. In a complementary manner, during the day, the slats of the building protect a large area of the top of the pyramid and keep it shaded. Thus the top of the pyramid remains cool throughout the day, so it can cool the building. On the other hand, between the slats and the surface of the pyramid a big pocket of fresh air is created, which is used to ventilate the building continuously. 

image by Luis de Garrido

h. Use of the low temperature inside the pyramid. 

The interior of the pyramid remains stable at a temperature of about 18 ° C year round. In contrast, the temperature of the surface layer varies according to external temperature changes. Therefore, when the top of the pyramid is covered with the building, an envelope intermediate space is created, shaded, protected and with much less temperature variation. 

Thus, in summer the building protects the top of the pyramid, so it remains fresh throughout the day, and the building can maintain cool. But in winter the building becomes a huge greenhouse, capable of heating the surface layer of the top of the pyramid, that remains warm during the night, capable of keeping the building warm. 

Therefore, the building remains cool throughout the summer and warm all winter without technological devices and without any energy consumption. 

image by Luis de Garrido

image by Luis de Garrido

2. Only essential appliances of very low power consumption have been incorporated in the building. 

3. Artificial lighting fixtures OLEDs with very low power consumption were used. 

4. A photovoltaic system has been installed to generate the electricity needed for the housing (4,000 watts). The photovoltaic solar captors have been arranged and photovoltaic cells integrated into the stainless steel blades of the south face of the building, and the stained glass of the south face. In addition, a set of next-generation, long lasting electrical batteries have been used, which are capable of storing the electrical energy generated by photovoltaic captors. 

5. A set of solar thermal collectors have been integrated into the upper colored glasses on the south side, to generate hot water needs. 

6. In the perimeter entries of cool and ventilated air (from perimeter shaded areas between the pyramid and housing) a set of trays have been incorporated, containing silicate salt dehumidifiers. Thus, the cool and ventilated air that enters into the building has a low humidity, thereby improving the thermal sensation (increasing the temperature in winter and decreasing the temperature in summer). 

2. Water self-sufficiency 

Cheops Eco-House is self-sufficient in water. That is, there is no need to connect to the municipal water supply systems. 

The water required for human consumption, human hygiene, and to irrigate crops and green areas is obtained from several complementary sources: 

1. Groundwater. A hole in the ground has been made next to the pyramid of Cheops, in order to get water from underground aquifers, which can be used directly for irrigation. 

2. Rainwater. Rainwater that falls on the pyramid is collected at the bottom of its four sides, and is taken to a buried tank. Much of the rainwater that falls on the eastern face of the pyramid accumulates in the stratum of vegetable growing trays, and drained water is collected at the bottom, partially filtered as it passed through layers of the soil. 

Ground water is mixed with rain water and stored in a buried tank with a capacity of 25,000 liters. Most of the stored water is used for drip irrigation of orchards and gardens on the east side, and a small portion of the water is filtered and purified subsequently to become fit for human consumption. 

Water purification (for human consumption) is accomplished by a reverse osmosis system with triple membrane (which governs the characteristics of the resulting water by means of an electronic processor), which includes a bacterial system. The resulting water has the same purity and content than mineral water. What's more, the user can choose the mineral content, simply by reprogramming the processor. 

3. Greywater recycling. Gray water generated by the building is filtered, treated and stored in an underground reservoir arranged for this purpose. The water thus obtained is mixed with water from underground aquifers and rainwater, and used as biological irrigation of orchards and gardens on the east face of the pyramid. 

image by Luis de Garrido

3. Food self-sufficiency 

On the east side of the pyramid of Cheops have been arranged several gardens and orchards that provide basic food to the occupants of Cheops Eco-House, and residents of the region. 

Every two rows of the pyramid (every row on the bottom) have a set of linear trays filled with farmland, with a drip irrigation system. This way you can easily grow all kinds of food. These foods are trucked to the building through reciprocating hoists of the pyramid. The climate of Egypt, and its fertile land, allows for several crops a year of cereals, fruits and vegetables, legumes, and arable land available is more than enough to feed the building occupants. 

4. High bioclimatic level 

Cheops Eco-House has been designed to have the best bioclimatic behavior possible, and capable of being thermally self regulated. The advanced and highly refined architectural design of the building takes advantage of the huge mass (thermal inertia) of the pyramid, the solar radiation during the day, and the falling temperatures at overnight in Cairo, in order to achieve a building self-sufficient in energy, without the need of technological devices. 

In fact, due solely to its design, the building is heated by itself in winter and cooled by itself in summer. The building maintains within it a stable comfortable temperature of between about 22 degrees in winter, and 25 degrees in summer. 

5. High efficiency and minimum energy consumption 

Cheops Eco-House has been designed carefully to consume the least amount of energy throughout its life cycle: construction of its components, construction of building (assembling all its components), use, maintenance, and dismantling. Due to its especial bioclimatic design the building has very little need for energy, and the energy it does need can be obtained by its own means from solar radiation, using a minimal amount of technological devices, with a very small economic cost. 

6. Complete industrialization 

All components of Cheops Eco-House have been designed to be manufactured in different factories, and transported to the pyramid for assembly and construction of the building. Of course, this requires a good architectural design to be carried out. 

7. Disassemble Construction System 

The building has been designed to be built using a fully industrialized and disassemble system, which allows all the architectural components to be easily assembled and disassembled. This gives the building an infinite life cycle and allows it to be disassembled and moved as often as you like. 

8. Transportability 

The set of elements of Cheops Eco-House have been designed to be assembled and disassembled easily and indefinitely. For this reason, these elements can be transported to any location, to be easily mounted (in less than a week) as many times as necessary. 

image by Luis de Garrido

9. Extreme Flexibility 

By design, Cheops Eco-House can be expanded, reduced, or even take on a different architectural configuration. Similarly, its interior open space has been designed to adopt different types of space partitions and reconfigurations, through sliding interior panels. 

10. Elimination of waste 

Cheops Eco-House components have been made in the factory, without generating waste. Similarly, they can be assembled and disassembled without waste generation. This has been achieved through the use of three different strategies: the integral industrialization of all of its components, the design of the assembly system, and compositional design system used on building. 

Also, organic waste generated during the use of the building are managed optimally and are used to make "compost" to serve as fertilizer for the sloping gardens and orchards of east side. Moreover, the wastewater is properly treated and also used as fertilizer. 

11. Infinite life cycle 

Every component of Cheops Eco-House has been designed to be assembled by means of screws, nails or pressure. This way they can be easily dismounted and removed from the building, to be repaired, reused or returned to the building. Thus, the building can last infinitely, with very low energy consumption. 

12. Sloping gardens and orchards 

biological garden, and a sloping garden, have been disposed. The selected plant species are native with low water consumption, and most are edible, medicinal and aromatic. Furthermore, the orchard structure has been formed using a cubic container assembly polypropylene filled with soil. The containers, half a meter wide and two meters long, are located along the inner part of each row of stones of the pyramid, joined together by means of a drip irrigation system, while leaving a passage on outside. Thus, the vegetation completely covers the surface of the pyramid, while leaving space for the harvesting of crops. In this sense, the same system of shuttle lift used for access to the building can be used to explore the east side height of the pyramid, and is helpful for harvesting of crops. 

13. Reversible Interior 

All interior materials of Cheops Eco-House are reversible. That is, they can be removed, retrieved and replaced with ease. All components are assembled by pressure, or screws and therefore can easily be repaired and replaced. This concept extends even to the bathroom fittings and kitchen, toilets and kitchen furniture. 

14. Use of environmentally friendly materials 

Cheops Eco-House uses purely ecological and healthy materials, including new innovative ecological products (insulation made of recycled airplane towels, insulation made of recycled glass, insulation made of glass bottles, panels made of recycled glass, screws, scrap,.... extruded polycarbonate panels, ecological paints, etc.) 

15. Promote welfare and happiness 

It might seem that everyone has different needs and a different concept of happiness. However, from a physical, emotional and psychological standpoint, a set of general patterns can be identified, capable of ensuring the welfare and happiness of people. These patterns have been fully taken into account in the design of Cheops Eco-House, and thus becomes a sounding board, able to promote and increase the happiness of its occupants. 

1. Thermal Stability 

2. Seasonal temperature variation 

2. Natural day lighting 

4. Technological simplicity and minimal maintenance 

5. Natural materials 

6. Architectural design simple and not monotonous 

7. Use of the correct colours 

8. Sense of security and privacy 

9. Beauty 

10. Absence of pathogens 

11. Breathability 

12. Promote human relationships 

13. Self-sufficiency (energy, water and food)

image by Luis de Garrido