FR2999203A1 - Method for constructing dwelling made of stones, bricks, wood, concrete or composite materials, involves forming framework from wooden, metal or composite materials, and providing framework in fixed air chamber - Google Patents

Abstract

The method involves forming a framework (2) from wooden, metal or composite materials. The framework is provided in a fixed air chamber. Interior trims and exterior trims are separated from the framework by chambers (31), which comprise a fixed air insulator. Reflective thin insulators and polished aluminum films (32) are separated by cells (33) containing fixed air. Thermal insulation is applied on walls, a ground (6) and a roof. The chambers are separated by an insulating product of equivalent heat capacities and chemical capacities.

Description

- 1 - Traditional dwellings, built of stone, brick or wood, are weakened by climatic events and the movements of the soil on which they rest, ranging from simple cracks caused by drought or poor connection between building materials, 'to landslide and destruction during earthquakes, tornadoes, tsunamis or other climatic outbursts. Their manufacture is long and expensive in comparison with other types of products. For example, a car, 8000 times more complex to manufacture than a house, with materials and features far more elaborate, is manufactured in a few hours and is marketed 10 times cheaper. It is endurance and reliability tests, to provide a product in which it is possible to live comfortably and safely.

It takes years between the decision to build and entry, at a time when worker mobility is becoming commonplace. A dwelling is a reflection of the mentality of the occupants and the change of residence is often experienced as a hard test. It must be dismantled and rebuilt elsewhere, where the need arises, in a few days, so that the family quickly finds its bearings. A change of professional life does not have to lead to a change of family life. The steps to be taken in order to acquire a real estate property are binding and strictly supervised, leaving little room for innovation and self-construction. Yet this is an area where creativity and the use of industrial rest times would be free to express themselves. Some self-help attempts, assisted by professionals, are emerging, but they face the reluctance of the banks. The complexity of the current construction means, requires its supervision by architects or developers, with labels, controlled by certifying bodies and protected by three compulsory insurance, considerably increasing the cost of construction without, ultimately, guarantee the non-destruction of the well by events classified "natural disaster". The houses in kit, wood or metal frame, require the construction of a base slab, proof of their fragility. A soil study is necessary, burdening even more the budget of the purchasers - 2 - Directives, emanating from the certifying bodies, oblige the manufacturers to ventilate the roofs and the facades of the houses, chasing the solar calories, pleasant in periods of heat waves but terribly harmful for the habitat, in cold period, because this ventilation pumps the calories, passing through the traditional insulators, which are only retarders of heat transfer, and sends them in the atmosphere, thus wasting expensive energies. The present invention greatly simplifies all these constraints by a return to fundamentals.

A dwelling must, first and foremost: - Be solid, in order to protect the inhabitants. Whether located in the plains or mountains, south or north, it must withstand heat and cold, earthquakes, tornadoes, exceptional snowfalls and floods. - It must allow to live healthy, sheltered from humidity, heat and cold, by making the best use of celestial inputs, which provide free rain and sun and being careful not to waste them. - It must be quickly built, using techniques and materials that meet specific needs, while meeting environmental constraints. - It must finally be cheap, to be accessible to all, as well as the car, ranging from low-end to high standing while maintaining the above obligations. Like wood, steel is a building material that is ideally suited to creating light and indeformable habitats. 100% recyclable and infinite, it is classified in the category of ecological materials. Its implementation allows industrialization of the means of production, drastically lowering manufacturing costs.

Still air is the best thermal insulation. - 3 - An industrial process of making still air blades, within the walls, the ground and the roof, allows to keep all the benefit for the benefit of the thermal protection of the inhabitants, in summer as in winter. This insulating process can be applied to all other construction methods, wood, bricks, concrete or composite materials, while respecting their specificities. Figure 1 shows the plan (1) of a dwelling. From this plane (1) is defined the frame (2), face and profile. In the present example, it is the metal frame version that is described. Then each constituent element is elaborated: in (3) are the walls; in (4) are the roof elements; in (5) are the connecting elements, respectively composing the floor (6) and the ceiling (7) of the habitat (8). Each wall (3) consists of a frame (31), preferably made of profiled sheets, assembled by welding. Uprights (32) and crosspieces (33), also in profiled sheets, are welded to the frame (31), determining the positioning of the openings used to receive the joinery, while ensuring the rigidity of the assembly. Once constituted, each wall (3) is protected from chemical attack (salinity, humidity of the ambient air, etc.) as well as thermal fluctuations, protecting it from frost as well as the heat wave. thus eliminating any expansion or removal of the steel. He is then dressed with his facings, inside and outside, preferably in the factory. These walls (3) are designed to withstand all mechanical stresses caused by wind, snow and other weather that may occur in our climate. The roofing elements (4), preferably profiled sheet metal, consist of 2 pediments (41), connected by 2 lattice girders (42), supporting the rafters (43). The walls (3), mechanically assembled on site, support the roof elements (4), as well as the connecting elements (51) and (52) subsequently receiving, respectively, the floor (6) and the ceiling (7). ), habitat (8).

All these elements will be fixed mechanically between them, rigidly and then immobilized between them, preferably by welding, to form an indestructible carcass (53). Everything can be easily deconstructed by removing the immobilization points of the elements.

This carcass (53) must be able to withstand, without damage, earthquakes, winds, floods, unforeseen events. It will be independent of the ground on which it will rest, separated from it by a crawl space.

Its upgrade will then be performed. This carcass (53) will be protected from thermal and chemical attacks, following the same process applied to the walls (3), then receive the roof and decorative ornaments, integrating it to its environment.

It can be protected from external vibrations from surrounding sites or heavy traffic lanes by installing vibration damping pads. This constructive process applies to any type of habitat, regardless of its nature, shape and size. Realized in this case steel, it can extend to wood or composite materials, insofar as these technologies ensure the strength of the carcass (53) made, not requiring the manufacture of a base slab. Figure 2 shows the attachment of a joinery (21), by means of lugs (22), fixed on the metal frame (2) constituting the wall (3). This frame (2) is coated, internally as well as externally, with a thin reflective insulation (24), thus creating still air chambers (25), providing thermal and chemical protection.

This IMR (24) is composed of polished aluminum films (32), separated by cells, containing still air (33).

This IMR (4) can be replaced by a product with equivalent or higher thermal and chemical capacities, shielding the framework (2) from chemical attack such as humidity and salinity, as well as the risk of expansion or removal of steel, caused by differences in temperature, sun shade, night day or summer winter. This process also achieves impermeability between the habitat and the outdoors.

The inner lining (26) is fixed on uprights (27), separated from the metal frame (2) by the IMR (24). Between the IMR (24) and the inner lining (26) there is a chamber (28), containing an insulator preferably consisting of still air, a thermal buffer for maintaining the inner wall at the temperature of the habitat , removing the cold wall effect, found in traditional achievements. Indeed, the reflective effect of the IMR (24) rejects the calories provided by habitat (8) towards this habitat, unlike traditional insulators that only slow down the escape of calories to the outside. The external cladding (29) is fixed on uprights (30), separated from the metal frame (2) by the IMR (24).

Between the IMR (24) and the cladding (29) there is a chamber (31), containing an insulator constituted, preferably, immobile air, thermal buffer having the following properties: In the walls (3), at the shade or cold period, it dampens the penetration of frigories and the effects of gales. These frigories are pushed outward by the reflecting effect of the IMR (24). In the sunny walls (3), it causes a greenhouse effect and accumulates solar calories that a device, not represented in this application, will collect, avoiding overheating of the external cladding (29), eliminating the risk of dilation of the last. The IMR (24), located between the chambers (31) and (25), rejects the calories and frigories coming from outside, through the cladding (29), towards the latter, contrary to the traditional thermal insulators that only slow down their penetration towards the habitat (8). These walls (3), will advantageously prefabricated in the factory, in order to control the hygrometry and quality of realization of the different still air chambers component.

It should be noted that the insulating complex, consisting of the still air chambers (25), with the air chambers, preferably immobile (27) and (31), shown in Figure 2, in the walls (3) , also applies to the ground (6) and to the roof (4) whether flat or sloping and to all types of constructions, stones, wood, bricks or composite materials existing or to be constructed.

Claims (10)

CLAIMS1) Construction method of a dwelling, characterized in that it consists of a frame (2), wood, metal or composite materials; 2) A construction method according to claim 1, characterized in that the frame (2) is in immobile air chambers (25); 3) A construction method according to claim 2, characterized in that the inner linings (26) and outer (29), are separated from the frame (2), by chambers (28) and (31), containing an insulator constituted preferably, still air; 4) A construction method according to claim 3, characterized in that the preferably immobile air chambers (28) and (31) are separated from the immobile air chambers (25), advantageously by thin reflective insulators (24). made of polished aluminum films (32) separated by cells containing still air (33); 5) Construction method according to claim 3, characterized in that the preferably immobile air chambers (28) and (31) are separated from the still air chambers (25) by an insulating product whose thermal and chemical capabilities are equivalent to or better than IMR (24) 6) Construction method according to claims 4 or 5, characterized in that it is composed of elements (3), (4) and (5) prefabricated advantageously in the factory; 7) Construction method according to claim 6, characterized in that the elements (3), (4) and (5), are assembled on site, to form a carcass (53), indestructible out of unpredictable event; 8) Construction method according to claim 7, characterized in that the carcass (53) is removable, according to the claims of the manufacturer, and then transported to another site, to be rebuilt. 9) Construction process according to claim 6, characterized in that the thermal insulation principle of the walls also applies to the ground (6) and the roof (4), whether flat or sloping. 10) Construction method according to claim 9, consisting of at least one immobile air chamber (25) and air chambers, preferably immobile (28) and (31), according to claims 4 or 5, characterized in that it is applicable to any type of dwelling, stone, brick, wood, concrete or composite materials existing or to be built.