WO2016024019A1 - Building construction elements and building construction - Google Patents

Abstract

The building construction element (1200, 1300) comprises: - a first part (1205, 1305), having a rectangular parallelepiped shape, comprising on one face a blind opening (1210, 1310), said opening being configured to receive static air forming a thermal insulator, - a second part (1215, 1315), having a rectangular parallelepiped shape, attached to the first part, against a face adjacent to the face comprising the blind opening, said face being referred to as the "attachment face", by feet (1220, 1320) and - a space (1225, 1325), formed between the first and second parts, having an opening on at least two adjacent sides of the attachment face, said space being configured to receive air moving from or to another volume linked to the space, so as to form a thermal insulator.

Description

 ELEMENTS OF REAL ESTATE BUILDING AND CONSTRUCTION

 REAL ESTATE

TECHNICAL FIELD OF THE INVENTION

 The present invention relates to building components and a building construction. It applies, in particular, to the thermal insulation of building construction.

STATE OF THE ART

 The thermal insulation of a building, such as a house for example, is currently achieved by adding a thermal insulating material on the surfaces inside the building in the case of insulation called "from the inside" ".

 These systems have several disadvantages:

 - on the one hand, the cost of these systems is high due to the cost of materials and manpower requirements for the installation of the insulation layer and

- on the other hand, these systems reduce the interior habitable surface of the construction, which reduces the sale price of the construction.

 In the case of insulation called "from the outside", an insulating material is positioned under a cladding enveloping the walls of the building construction. These systems have the advantage of not impacting the size of the habitable interior surface of the building construction. However, these systems are expensive, because of the cost of materials and labor, and bulky.

OBJECT OF THE INVENTION

 The present invention aims to remedy all or part of these disadvantages. For this purpose, according to a first aspect, the present invention relates to a building construction element which comprises:

a first part, having a rectangular parallelepiped shape, comprising on one face a blind orifice, this orifice being configured to receive static air forming a thermal insulator, a second part, having a rectangular parallelepiped shape, fixed to the first part, against a face adjacent to the face comprising the blind hole, this face being called the "fixing face", by feet and

 a space formed between the first and the second part having an opening on at least two adjacent sides of the attachment face, this space being configured to receive air moving from or to another volume connected to the space, so as to form a thermal insulator.

 With these arrangements, air circulates in the space between the first and the second portion, which has the effect of distributing the heat received locally between the spaces of adjacent building elements, including in cool places. In addition, the air can move both vertically and horizontally. As a result of these hot air movements, a building construction made from the building elements is thermally insulated. In addition, the dimensions of the interior volume can be small, which reduces the dimensions of the building element. In addition, the construction element can be assembled by gluing to a building block, such as a block, for example, which ensures a fast assembly speed. Finally, the building element imparts a great acoustic insulation to the building construction thus created without requiring installation of additional acoustic insulation materials.

 In embodiments, the object element of the present invention comprises a plurality of orifices whose openings are positioned on the same face of the first part.

 These embodiments make it possible to create a cellular structure of static air, this structure allowing both rigidity of the structural element and thermal insulation by static air.

 In embodiments, the feet and the second portion are molded in one piece, the first portion being bonded to this molded part.

 In embodiments, the feet and the first portion are molded in one piece, the second portion being adhered to this molded part.

 In embodiments, the feet, the first portion and the second portion are molded in one piece.

These embodiments allow a simple realization of the construction element. In embodiments, the second portion has at least one opening through the second portion, each opening being perpendicular to the general plane formed by the space between the first and the second portion.

 These embodiments allow the insertion of tools into the aeration space once construction elements have been assembled.

 In embodiments, at least one blind hole has a circular opening.

 These embodiments allow the attachment of cylindrical tubes, these tubes for fixing the construction element to various structures or the connection of the volume of air contained in these orifices with other volumes.

 In embodiments, the element of construction object of the present invention is made of concrete.

 According to a second aspect, the present invention aims at a building construction which comprises a plurality of building elements object of the present invention, which are assembled by juxtaposition or stacking according to a plane, the space between the first part and the second part of each element being connected to said space of at least one other element.

 The aims, advantages and characteristics of the construction object of the present invention being similar to those of the element of construction object of the present invention, they are not recalled here.

BRIEF DESCRIPTION OF FIGURES

 Other advantages, aims and particular characteristics of the invention will emerge from the following nonlimiting description of at least one particular embodiment of the building element, the building construction and the construction method which are the subject of the present invention. invention, with reference to the accompanying drawings, in which:

 FIG. 1 represents, schematically and in perspective, a particular embodiment of the construction element object of the present invention,

FIG. 2 represents, schematically and in perspective, a particular embodiment of the element of construction which is the subject of the present invention, FIG. 3 schematically and in profile shows a particular embodiment of the construction element which is the subject of the present invention, FIG. 4 schematically and from above shows a particular embodiment of the construction element which is the subject of FIG. the present invention, FIG. 5 represents, schematically and from above, a particular embodiment of an assembly of construction elements which are the subject of the present invention,

FIG. 6 represents, schematically and from above, a particular embodiment of the construction element which is the subject of the present invention; FIG. 7 is a diagrammatic and side view of a particular embodiment of the construction element which is the object of the present invention illustrated in FIG.

FIG. 8 represents, schematically and from above, a particular embodiment of an assembly of construction elements that are the subject of the present invention,

FIG. 9 represents, schematically and in profile, a particular embodiment of the construction element which is the subject of the present invention, FIG. 10 is a diagrammatic and side view of a particular embodiment of the construction element which is the subject of FIG. the present invention, Figure 1 1 shows, schematically and from below, a particular embodiment of the construction element object of the present invention,

FIG. 12 represents, schematically and in profile, a particular embodiment of the construction element which is the subject of the present invention; FIG. 13 is a diagrammatic front view of a particular embodiment of the real estate construction object of FIG. FIG. 14 represents, schematically and in profile, a particular embodiment of the real estate construction object of the present invention, FIG. 15 schematically and in profile shows a particular embodiment of the real estate construction object of the present invention. FIG. 16 represents, schematically and in profile, a particular embodiment of the real estate construction object of the present invention; FIG. 17 represents, schematically, a particular flow diagram of the method of the present invention; FIG. 18 represents, schematically and in profile, a particular embodiment of the real estate construction object of the present invention,

FIG. 19 represents, schematically and in profile, a particular embodiment of the real estate construction object of the present invention,

FIG. 20 represents, schematically and in perspective, a particular embodiment of the construction element which is the subject of the present invention,

 FIG. 21 represents, schematically and in perspective, a particular embodiment of the construction element which is the subject of the present invention and

 - Figure 22 shows schematically and front, a particular embodiment of the construction object of the present invention.

DESCRIPTION OF EXAMPLES OF EMBODIMENT OF THE INVENTION

 The present description is given in a non-limiting manner.

 FIG. 1, which is not to scale, shows a perspective view of an embodiment of the construction element 10 which is the subject of the present invention. This element 1 0 real estate construction presents:

 a first face 105, called internal,

 a second face 1 1 0, said external, opposite to the internal face 105 and

 four connecting faces 1 15 linking the inner faces 1 05 and outer 1 1 0, and comprises:

 a hollow internal volume 1 open on each connecting face 1 15, the internal 105 and outer faces 1 10 not opening on the inner volume 1,

 a first portion 125 extending from the inner face 105 to the inner volume 120,

 a second part 130, complementary to the first part 125, the distance between the internal face 105 and the internal volume 120 being at least twice the distance between the internal volume 1 and the external face 1 1 0 and

at least one hollow interior space opening on two opposing connecting faces, the other two connecting faces opening to no interior space 1, each hollow interior space being integrally in the first portion the building element. The building element 10 has two parts 125 and 130. These two parts 125 and 30 may be molded independently or together.

 The first part 1 25 is similar to a manufactured building block, sometimes called "breeze block" and roughly presents a rectangular parallelepiped shape. This first part 125 is made, for example, by deposition of wet concrete in a mold to form a molding of the shape of the first part 125. This first part 1 presents:

 an inner face 105, usually positioned towards the interior of a building construction made by assembling building elements 1 0,

 an external face, not referenced, opposite the inner face 105 and facing the second portion 130 and

 - Four connecting faces 1 1 5 connecting the inner face 105 and the outer face not shown, a plurality of hollow volumes 135 extending between two of these connecting faces 1 15, opposite to one another.

 The hollow volumes 1 35 are preferably oriented perpendicularly to the ground during the laying of the construction element 10.

 Preferably, the distance between the inner face 105 and the outer face of the first part measures twenty centimeters.

 The second part 130 comprises:

 a rigid surface, made of molded concrete for example, having an external face 110 directed towards the outside of the building construction during the laying of the construction element and

 a set of reliefs 140 configured for:

 - be fixed to the outer face of the first part 1 25 by gluing and

- Allow the passage of air between the reliefs 140 so as to achieve the thermal insulation of the first part 1 25.

 Preferably, the distance between the outer face of the first portion 125 and the outer face 110 of the second portion 1 when the two parts 125 and 130 are assembled measures seven centimeters.

 FIG. 2 diagrammatically and in perspective shows a particular embodiment of the assembled construction element.

The assembly of the construction element 1 0 is made during the molding of the construction element 10. This molding is carried out, for example, in a mold with fixed reliefs configured to achieve the hollow volumes 135 on the one hand and a portion of the inner volume 120 on the other. In addition, this mold comprises moving reliefs, perpendicular to the fixed reliefs, at the second portion 130, configured to be brought into contact with the fixed reliefs to produce another part of the interior volume 120 of the building element 10.

 In variants, the molding uses only fixed reliefs and includes a step of drilling the construction element 10 to create the interior volume 1 20.

 In other variants, the first portion 125 and the second portion 130 are molded independently and glued to each other thereafter.

 It will be noted, in particular, in FIGS. 1 and 2, that the air can circulate in the interior volume 1 20 both laterally and vertically with respect to the external face 1 1 0.

 FIG. 3 diagrammatically shows a third view, in profile, of the construction element 10 which is the subject of the present invention. It is observed, in particular, that the air can circulate in the internal volume 120 laterally relative to the outer face 1 10 when the outer face 1 1 0 is positioned from the front or rear relative to a user.

 FIG. 4 diagrammatically shows a fourth view, from above, of the construction element 10 which is the subject of the present invention. It is observed, in particular, that the air can circulate in the interior volume 120 vertically when the element 10 is placed on the floor. It is further observed that the construction element 10 comprises two hollow volumes 1 35. This FIG. 4 also makes it possible to illustrate the positioning of the mortar 145 on the construction element 1 0 for assembly to a building element 1 0. similar. The mortar 145 is positioned, for example, in three places of the construction element 1 0:

 a first part of the mortar 145 is positioned on the second part 130 of the construction element 10,

 a second part of the mortar 145 is positioned on the first part 125 of the building element 10, between the hollow volumes 135 and the interior volume 120 and

- A third part of the mortar 145 is positioned on the first portion 125 of the element 10 of construction, between the inner face 105 and the hollow volumes 1 35. FIG. 5 schematically and seen from above shows an assembly of two construction elements 1 0 subject of the present invention. The two building elements 1 0 are joined by their connecting faces 1 15, a connecting joint 150 linking the construction elements 1 0. The interior volumes of the building elements 10 are connected to one another. In addition, a tube 155 is positioned at the junction of the inner volumes so as to connect these two volumes.

 FIG. 6 shows diagrammatically and seen from above, an embodiment of the construction element 20 of the present invention. This element 20 of real estate construction presents:

 a first face 205, called internal,

 a second face 21 0, said external, opposite to the internal face, the external face 210 has at least one opening on the inner volume 220, each opening of the outer face having a larger opening dimension of less than five centimeters and

 four connecting faces 215 connecting the inner and outer faces, all the connecting faces 215 open on the internal volume 220, one of the connecting faces having at least one opening, not shown, on a volume 220 inside, each opening said connecting face 215 having a larger opening dimension of less than five centimeters,

and comprises at least one hollow internal volume 220 open on at least three connecting faces and the inner face.

 This building element 20 serves, for example corner stiffener for a building construction. The openings allow easy molding of the construction element 20. These holes are, when assembling the building construction, filled by a worker so that the internal volume 220 remains isolated from the outside air.

 FIG. 7 diagrammatically shows a second view, in profile, of the construction element 20 illustrated in FIG. 6. In particular, openings 225 are observed positioned on a connecting face 21 of the element of FIG. construction 20. These openings, superimposed, have a diameter less than 5 centimeters.

FIG. 8 shows an assembly between a building element 20 as illustrated in FIG. 6 and a building element 10 as illustrated in FIG. 3. In particular, a mortar positioning 230 is observed to allow the attaching another construction element 20 to the assembly. This other element 20 is positioned on the building element 10 and partly on another building element 20 so as to create, by iteration, a mesh of building elements 20 at the angle to ensure the function of stiffener.

 FIG. 9 diagrammatically and in profile shows an embodiment of the construction element 30 of the present invention. This construction element 30 performs the function of chaining element. This construction element 30 has a housing 305 open on a connecting face of the element 30. This housing 305 corresponds to a blind alternative to the interior space 135 of the construction element 10 described with reference to FIG. . This housing 305 is configured to receive concrete. An armature and concrete are positioned in a plurality of housings 305 of different building elements 30 so as to increase the resistance of the building construction to a mechanical deformation.

 FIG. 10 diagrammatically and in profile shows a second view of the construction element 30 illustrated in FIG. 9. In this new view, the housing has been filled with concrete 31 0 and concrete 31 5, said " arase ", covers the upper face of the construction element 30. This concrete arase 31 5 is traversed by at least one hollow tube 320 for planelle, allowing the passage of air through the concrete base 315.

 FIG. 11 shows schematically and from below an embodiment of the planelle 40. This planelle 40 is a construction element 10 as described with reference to FIG. 1, the interior spaces 1 of which are blind and configured to be nested on hollow tubes 320 as described with reference to FIG. 10. These internal spaces 135 are tubular cells 405 opening on a connecting face of the planelle 40.

 FIG. 12 shows, schematically and in profile, an assembly between the planelle 40 and a construction element 30 as described with reference to FIG.

FIG. 13 diagrammatically and frontally shows one embodiment of the real estate construction object 50 of the present invention. This building construction 50 comprises a plurality of elements 505 of construction as described with reference to Figures 1 to 12, which are assembled by their connecting faces, the interior volumes of said building elements communicating between them. This plurality of building elements 505 illustrates, in FIG. 13, a wall comprising a window 510 surrounded by said building elements 505. The building elements 505 are assembled horizontally by juxtaposing the elements 505 and vertically by superposing the elements 505 an upper element 505 is placed on two lower elements 505.

 This building construction 50 comprises a trunk 515 for roller shutter, positioned above the window 510. This box 51 5 is traversed by hollow tubes 525 connecting the two elements 505 horizontally adjacent to the trunk 515 so as to allow air to flow from an interior volume of an element 505 to the interior volume of the other element 505.

 In order to position a base and / or window cheeks on the height of a building element, the outer face of this building element is removed so as to expose a structure similar to a conventional building element. The part of the hollow volume thus discovered is filled with concrete, this concrete serving as a support for the window support, for the base and rails of the shutter by the cheeks. In variants, the concrete serves as support for any type of surface, such as a window for example.

 FIG. 14 diagrammatically and in profile shows a particular embodiment of a crawl space 60 from building elements as described in one of FIGS. 1 to 13 or 20. This crawl space 60 has:

 a rigid 605 foundation serving as support for the rest of the construction,

a superposition of elements 610 of construction so that the interior volumes, called "spaces" in FIG. 20, are connected, the external face of these elements 610 being oriented towards the outside of the building, facing the earth 620,

 an insulating layer 625 made of insulating material superimposed on the external faces of the elements 610 and having a bowl shape at the junction between the element 610 in contact with the foundation 605 and the foundation 605 and

- A drain 61 5 positioned at the bottom of the bowl, in the ground 620.

FIG. 15 diagrammatically and in profile shows a particular embodiment of an assembly 70 of the device described with reference to FIG. 14, of a layer of raised concrete 705 and of an overlay of elements 71. 0 of construction. It is observed, in particular, that the 705 arased concrete is in contact with first parts of the building elements so that air can be introduced into the hollow volumes of the building elements.

 FIG. 16 shows, diagrammatically and in profile, a variant of the assembly 70 described with reference to FIG. 1, in which the superimposition of elements 805 of construction positioned below the ground level is positioned in such a way that the hollow volumes of the elements 805 are oriented towards the interior of the construction. The superposition of elements positioned on the bare concrete is, nevertheless, oriented so that the hollow volumes of the elements gives on the outside of the construction above the ground.

 FIG. 17 diagrammatically shows a particular flow diagram of the process of the present invention. This construction method 90 comprises:

 a step 905 for assembling building elements as described with reference to one of FIGS. 1 to 1 6, by their connecting faces, by superposing openings on the interior volume,

 a step 910 for plugging openings having a larger opening dimension of less than five centimeters when elements as described with reference to FIGS. 6 to 8 are assembled and

 a tube insertion step 915 connecting the interior volumes of two building elements.

 The assembly 905 of the building elements is made, horizontally, by juxtaposition and, vertically, by superposition. When horizontal juxtaposition of building elements, a connection joint is placed between each building element. During the vertical superposition of building elements, a layer of mortar is positioned between each building element. During this assembly step 905, the interior volume of each building element is connected to the interior volume of neighboring building elements vertically and horizontally.

 The plugging step 91 0 of openings is carried out in the case of a structural element serving as a stiffener, the openings being plugged by a mason.

 The insertion step 915 of tubes is carried out parallel to, or after, the assembly step 905.

FIG. 18 shows a particular embodiment of the building construction object of the present invention. This construction 1000 is made from building elements 1010 as described with reference to one of Figures 1 to 1 6.

 In this embodiment, the building elements 101 0 are oriented towards the interior of the building construction 1000, that is to say that the openings of the hollow volumes are superimposed and that these hollow volumes are positioned inside the building. real estate construction 1000. One calls "interior of the building construction 1000" the habitable part of the construction 1000.

 This embodiment has several advantages:

 First, the thermal and acoustic insulation is achieved by requiring a thickness of only eight centimeters, including seven centimeters corresponding to the hollow volume of the building elements 1010 and one centimeter corresponding to the plaster cast and the paint of this plaster. In the state of the art, an insulation implementing plasterboard usually requires ten or fourteen centimeters in thickness to be realized. The gain of space allows an increase of the living space in the building construction.

 Secondly, this embodiment reduces the risk of construction failure due to the laying of armored strips on joints between building elements 1010.

 Thirdly, this embodiment makes it possible to reduce the time required for placing the plasterboard, the projection of plaster being faster than the application of plasterboard.

 Fourthly, the drawing of the electrical ducts and plumbing ducts is greatly facilitated by the presence of the space formed by the hollow volumes, these ducts and ducts being positioned in this space.

 In variants, once the ducts and ducts are positioned, rock wool or glass cellulose is blown into the space formed by the hollow volumes. These variants have the advantage of implementing natural products unlike polystyrene usually used in the case of plasterboard placement.

 Fifth, the building element 1010 is usually made of concrete, the inner surface of the building construction 1000 is harder than in the case of plaster for example.

Sixthly, the cost of production is lower in the context of the projection of plaster than in the case of laying plasterboard or other surfaces for example. Seventhly, in the context of the realization of a piece of water from the building construction, due to the absence of plasterboard, the risk of appearance of mold is reduced by the embodiment in the case where the Paint used is waterproof.

 FIG. 19 shows a particular embodiment of the real estate construction 1 100 which is the subject of the present invention. In this embodiment, we observe:

 a wall, made by superposition of construction elements 1 105 as described with reference to FIG. 18 placed on a foundation 1 1 15,

 a floor 1 1 between the floor of the building 1 1 0 and

 - A hollow space 1 1 10 formed by a set of hollow volumes such as hollow volumes implemented in the building elements 1 105. This hollow space 1 1 10 is connected to the hollow space formed by the hollow volumes of the elements of construction 1 105. This hollow space 1 1 1 0 is horizontal and juxtaposed to the floor 1 120.

 This embodiment makes it possible to perform a floor heating function when the air trapped in the hollow space is hotter than the floor.

 FIG. 20 shows a particular embodiment of the element 1200 of real estate construction object of the present invention. This 1200 building element features:

 a first part 1205 having a rectangular parallelepiped shape, comprising on one face a blind hole 121 0, this orifice being configured to receive static air forming a thermal insulator,

 a second part 1215 having a rectangular parallelepipedal shape, fixed to the first part, against a face adjacent to the face comprising the blind hole, this face being called the "fixing face", by feet 1220 and

 a space 1225 formed between the first and the second part, having an opening on at least two adjacent sides of the fixing face, this space being configured to receive air moving from or to another volume connected to the space, so as to form a thermal insulator.

The first part 1 205 has, for example, a rectangular parallelepiped shape having a large side and two small sides of smaller dimensions. This first portion 1205 comprises at least one orifice 1 210 blind. This orifice 1210 blind is placed on any face of the parallelepiped. Preferably, this orifice 1210 is positioned on a face delimited by the long side and a small side. Preferably, the orifice 1 21 0 has a depth slightly less than the height of the parallelepiped.

 In preferred embodiments, the element 1200 comprises a plurality of blind orifices 1210. Preferably, these orifices 1210 are positioned on the same parallelepiped face.

 Each orifice 1210 allows the compression of air blocked in the volume of this orifice 1210 when positioning another element on the element 1200. This air, called "static", can then leave this volume and act as an insulator thermal and acoustic.

 In variants that are not shown, the element 1200 does not have orifices 1210 blind.

 In variants not shown, the element 1200 has orifices passing through the parallelepiped.

 The second portion 121 5 preferably has a plate shape, one side of which has a length much shorter than the length of the other sides.

 Preferably, the second portion 1 215 has a length and height equal to the length and height of the first portion 1 205, while the thickness of the first portion 1205 and the second portion 1 215 diverges. Preferably, the thickness of the second portion 1215 is at least two times smaller than the thickness of the first portion 1205. Preferably, the thickness of the second portion 1215 is at least four times smaller than the thickness of the first portion 1205. Preferably, the thickness of the second portion 121 is at least five times smaller than the thickness of the first portion 1205.

 The second part 1 21 5 is fixed on one of the two long sides of this second part 121 5 to the first part 1205. The second part 1 215 is fixed against a face of the first part 1205 delimited by the long side and a small side of the parallelepiped. This face is adjacent to the face with the blind holes 1210.

The feet 1220 are, for example, mechanical elements having a rectangular parallelepiped shape positioned both against the first portion 1205 and the second portion 1215. The space between these legs 1220 delimits the space 1225, this space 1225 has at least two openings, at least two openings are positioned perpendicularly relative to each other.

 In preferred embodiments, the legs 1220 are positioned so that the first portion 1205, each leg 1220 and the second portion 1215 has a profile continuity. In this way, the element 1200 has a general shape of rectangular parallelepiped, this element 1 200 having openings on at least two of its faces.

 In embodiments, the legs 1220 and the second portion 1215 are molded in one piece, the first portion 1205 being adhered to this molded part.

 In embodiments, the legs 1220 and the first portion 1 205 are molded in one piece, the second portion 1 215 being adhered to this molded part.

 In embodiments, the legs 1220, the first portion 1205 and the second portion 1205 are molded in one piece.

 In embodiments, as shown in Figure 21, the second portion 1315 has at least one opening 1330 through the second portion, each opening being perpendicular to the general plane formed by the space 1325 between the first and the second portion.

 These embodiments, and each opening 1330, are described with reference to FIGS. 8 and 9.

 In embodiments, at least one blind hole 1210 has a circular opening.

 In embodiments, the element 1200 is made of concrete.

 FIG. 21 shows a particular embodiment of the construction element 1300 that is the subject of the present invention. This element 1300 of construction corresponds to the element 1200 of construction described with reference to FIG. 20. The references 1305, 1310, 1315, 1320 and 1325 correspond to references 1205, 1210, 121 5, 1220 and 1225.

In particular, it is observed that the second portion 1315 has a longer dimension in the length direction, so that the second portion 131 5 can not be perfectly aligned with the first portion 1305. The openings 1330 are positioned in this alignment difference, this difference being delimited by the projection of the first part 1305 on the second part 1315.

 As can be understood from reading the present description, the elements 1200 and 1300 constitute an equivalence of the elements of construction described with reference to FIGS. 1 to 19.

 FIG. 22 diagrammatically shows a particular embodiment of the construction 1400 which is the subject of the present invention. This building 1400 real estate comprises a plurality of elements, 1200 or 1300, construction object of the present invention, which are assembled by juxtaposition or stacking in a plane, the space between the first part and the second part of each element being connected in the said space of at least one other element.

 Thus, as can be understood from reading the previous description, the building construction object of the present invention makes it possible to have a continuous air connection, through the hollow volumes of the building elements, on all the vertical surfaces of the building. construction. In the case of a roof framing, a connection with the insulation in place in this frame, this insulation is generally the same as that used in the walls of the construction.

Claims

1. Element (1,200, 1,300) of building construction, characterized in that it comprises:

 a first portion (1205, 1 305), having a rectangular parallelepipedal shape, comprising on one face a blind orifice (1210, 1310), this orifice being configured to receive static air forming a thermal insulator,

a second part (1 21 5, 1315), having a rectangular parallelepipedal shape, fixed to the first part, against a face adjacent to the face comprising the blind hole, this face being called the "fixing face", by means of feet (1,220, 1,320) and

 a space (1225, 1325) formed between the first and second parts, having an opening on at least two adjacent sides of the attachment face, this space being configured to receive air moving from or to another volume connected to the space, so as to form a thermal insulation.

2. Element (1,200) according to claim 1, which comprises a plurality of orifices (121 0) whose openings are positioned on the same face of the first part.

3. Element (1200) according to one of claims 1 or 2, wherein the feet (1220) and the second portion (121 5) are molded in one piece, the first part (1205) being glued to this piece molded.

4. Element (1,200) according to one of claims 1 or 2, wherein the feet (1220) and the first part (1205) are molded in one piece, the second part

(121 5) being glued to this molded part.

5. Element (1200) according to one of claims 1 to 4, wherein the feet (1220), the first portion (1205) and the second portion (1 215) are molded in one piece.

6. Element (1300) according to one of claims 1 to 5, wherein the second portion (131 5) comprises at least one opening (1330) passing through the second portion, each opening being perpendicular to the general plane formed by the space (1325) between the first and the second part.

7. Element (1200, 1300) according to one of claims 1 to 6, wherein at least one orifice (1,210, 1,310) blind has a circular opening.

8. Element (1200, 1300) according to one of claims 1 to 7, consisting of concrete.

9. Construction (1400) real estate characterized in that it comprises a plurality of elements (1200, 1300) of construction according to one of claims 1 to 8, which are assembled by juxtaposition or stacking in a plane, the space between the first part and the second part of each element being connected to said space of at least one other element.