FR2952949A1 - Construction block e.g. brick, for use in building construction to air-conditioning and heat insulation of room, has cavity opened by openings that are formed on upper face, lower face, side faces and end faces - Google Patents

Abstract

The block (1) has a cavity opened by openings (10, 12) that are formed on an upper face (2), a lower face, end faces (5a) and side faces (4a). A projecting part is arranged on the upper face and the lower face. The openings of the lower face and upper face are arranged on a tenon (6) and in a housing recess (8). The openings of the end faces are arranged on another tenon (7) and in another housing recess, where the cavity is filled with insulating foam. Independent claims are also included for the following: (1) a method for raising a wall (2) a method for air-conditioning and heat insulation of a room.

Description

The invention relates to a building block for the construction of buildings and processes for air conditioning and thermal insulation of a room of which at least one wall is constructed with these blocks.

Modern building blocks such as bricks or blocks are not solid but have cavities, which gives them several advantages: on the one hand they are lighter than stone while having good mechanical properties, on the other hand air-filled cavities contribute to the thermal insulation of buildings built with these blocks. However, air is a bad insulator and heat transfer can be effected by mortar joints between blocks, which act as thermal bridges, the mortar being a better conductor of heat than for example brick. The application FR 2 307 096 describes a rubble comprising cavities filled with an insulating material. However, these cavities do not communicate with each other, which makes their filling tedious, and the number of thermal bridges is not decreased. The application FR 2,633,650 describes a building block whose cells have no bottom, which allows a vertical circulation of air between blocks. However, the air does not circulate horizontally between blocks and there remain mortar joints which are thermally bridged. Another known way to improve the thermal insulation of a wall is to build two walls separated by a layer of insulation. But this is an expensive solution. 2952949 2- Moreover, the need to reduce the energy consumption of buildings is increasingly felt, the Grenelle Environment Forum imposing ambitious goals. There is therefore still a need for a building block that provides the buildings that will use it with excellent thermal insulation at an affordable cost. For this purpose, the invention proposes a building block comprising at least one upper face, one lower face, two end faces and two lateral faces, and further comprising a cavity opening through at least one respective opening on the upper face. , on the lower face as well as on each end face. The cavities of the blocks can be placed in continuity horizontally and vertically during the elevation of a wall, by comparing the openings they comprise on the upper and lower faces and on the end faces of the block, thus creating an almost continuous air gap in the thickness of the wall. This continuity can be used to improve the thermal insulation of a room or a building. Advantageously, the cavity has a substantially flat shape with the same thickness throughout the space it occupies within the building block.

In one embodiment, the upper, lower and end openings have an oblong shape of the same width and the cavity has the same width. This creates an air gap of constant thickness throughout the block and therefore throughout the thickness of the wall. In another advantageous embodiment, the cavity has a substantially planar shape with narrowing at the upper, lower and end openings. It is equivalent to say that, in this embodiment, the cavity has, in all its central part, an area of greater width than that of the openings, which provides a larger space for example to circulate air from air conditioning or inject an insulating foam.

Advantageously, the building block may further comprise at least a first projecting portion on an upper face or on a lower face and, on the opposite face, at least a first concavity cooperating with the first projecting part of another block, of so that, when two blocks are assembled one above the other in staggered rows, the opening of the upper face of the lower block and the opening of the lower face of the upper block cooperate to ensure continuity between the cavities of the two blocks. For example, the first projecting portion constitutes a first post, separating two wings, and the first concavity is a first mortise, separating two wings, the blocks being assembled one above the other by mortise and tenon assembly. Advantageously, the same arrangements can be found on the end faces of the block, that is to say that the block may further comprise at least a second projecting portion on one end face and, on the opposite end face at least one second concavity cooperating with the second projecting part of another block, so that when two blocks are assembled next to each other, the opening of the end face of a block and the opening of the end face of the other block cooperate to ensure continuity between the cavities of the two blocks. For example, the second projecting portion is a second post, separating two wings, and the second concavity is a second mortise, separating two wings, the blocks being assembled one next to the other by mortise and tenon assembly. Advantageously, the openings of the lower and upper faces are respectively disposed on the first pin and in the first mortise and the openings of the end faces are respectively disposed on the projecting portion of the second pin and in the concavity of the secondary mortise.

Advantageously, the first and second pins have the same value of off-hook. The building block according to the invention comprises two mortise and tenon assembly means, a first means for a vertical assembly and a second means for a horizontal assembly. The block also comprises an internal cavity communicating with the outside by at least four openings, openings disposed on the projecting and recessed faces of the first tenon and mortise device, and openings disposed on the projecting and recessed faces of the second device. tenon and mortise. This space inside the block has a cross shape. When assembling the blocks, the openings are thus automatically placed at least partially facing. Thanks to these arrangements, it is realized in a high wall with building blocks according to the invention a quasi-continuous space, both vertically and horizontally.

This space can be used for example to circulate air at controlled temperature, to obtain an air conditioning of the room with this wall, or to fill it with an insulating foam to improve the thermal insulation of the premises.

Another advantage of the building block according to the invention is that thanks to its means of assembly mortise and tenon, it is not necessary to have the binder, for example mortar, over the entire surface of the opposite faces, it is sufficient to have on the wings flanking the tenons and / or the wings flanking the mortises. This breaks the thermal bridge that constitute the joints between blocks.

Advantageously, the cavity may comprise on the upper face of the block two openings offset longitudinally with respect to each other, and / or it may comprise on the underside of the block two longitudinally offset openings with respect to the other. The blocks being assembled vertically staggered, it may be advantageous to provide, on the vertical assembly pin and / or in the mortise, openings which are in two parts offset longitudinally, separated by a connecting element. By virtue of these arrangements, the structural strength of the block is increased without losing the continuity of the cavity inside the block and inside a wall 20 with this block. Advantageously, the block can constitute a brick. This block can be delivered as is, ie with its cavity filled with air, or with its cavity filled with insulating foam. In the first case, the choice is open, during its implementation, to circulate an air conditioning air in the wall or to fill the insulating foam cavity 25 during construction. In the second case, the brick integrates its own insulation.

The invention also relates to a method for raising a wall, characterized in that it comprises the step of: - assembling building blocks according to the invention so as to bring the apertures of the upper and lower faces together two superposed blocks, as well as the openings of the end faces of two adjacent blocks, so as to put into communication the cavities of the contiguous blocks.

In this way, there is an almost continuous space in the thickness of the wall, this space can be used for air conditioning or thermal insulation of the building or room using the wall. It is thus possible to regulate the temperature inside the envelope of any type of building construction.

Advantageously, the method may comprise the steps of: - assembling building blocks according to the invention by mortise and tenon assembly, so as to put in register the openings of the upper and lower faces of two superimposed blocks, as well as the openings end faces of two adjacent blocks, so as to put in communication the cavities of the blocks, - deposit binder, such as a mortar, between two blocks only on the flanges framing the first and second tenons, and / or only on the wings flanking the first and second mortises. As mentioned above, the mortar, horizontal and vertical joints are thus interrupted and the thermal bridges they usually constitute are eliminated when the block is made of a material that is less heat-conductive than the mortar, such as the brick.

The invention also relates to a method of air conditioning a room, comprising the steps of: - raising at least a portion of at least one wall of the room according to the method according to the invention, - circulating the air in the cavities of the blocks. The air admitted to circulate in the cavities can be fresh air in summer situation, to cool the room, or hot air in winter situation.

The invention also relates to a method of thermal insulation of a room, comprising the steps of: - raising at least one wall of the room according to the method according to the invention, - injecting an insulating foam into the cavities of said blocks . An insulating foam has a much lower heat transfer coefficient than air, so the block provides better thermal insulation on the wall. It can be an expansion foam, whose components are injected in liquid form into the building block and react to form an insulating foam. The operation of injecting foam into the cavities of the blocks is greatly facilitated because, thanks to the provisions of the block according to the invention, these spaces communicate horizontally and vertically within the wall. The foam can easily occupy the entire space. The operation can take place in several stages: raising the wall over a portion of its height, for example one meter, injecting the foam on this portion of the height, which makes it possible to control its good distribution in the cavities building blocks. Advantageously, it is possible to use a spray foam in the aqueous phase, not releasing any volatile organic compound, for example of the ICYNENETM type.

The invention also relates to a method of air conditioning and thermal insulation of a room, comprising the steps of: - raising a first wall portion of the room according to the method of the invention, - raising a second portion of wall of the room according to the method of the invention, above the first wall portion, - inject an expansion foam into the cavities of the building blocks of the second wall portion, - circulate air in the cavities of the building blocks of the first wall portion. The air circulating in the thickness of the walls loses its calorific value (whether to heat or cool) after a few meters, in practice on two floors. It is therefore advantageous, in the upper floors, for example of a three-storey house, to simply isolate the walls of the third floor by injecting foam into the cavities of the blocks.

Embodiments and variants will be described hereinafter by way of non-limiting examples with reference to the accompanying drawings in which:

FIGS. 1A and 1B show a perspective view of a first embodiment of the building block according to the invention, FIG. 2 represents a vertical section along X-X 'of the first embodiment of the building block according to the invention,

FIG. 3 represents a vertical section along Y-Y 'of a second embodiment of the building block according to the invention, filled with a foam,

Figure 4 is a summarily vertical sectional representation of a staggered assembly of blocks according to the invention.

The building block 1 illustrated in FIG. 1A comprises an upper face 2, a lower face 3, two lateral faces 4a and 4b, and two end faces 5a and 5b (not visible). The upper face 2 has a protruding portion 6 which extends longitudinally, and one of the end faces 5a has a projecting portion 7 which extends vertically; these projecting parts 6 and 7 form respectively a first and a second pin or tabs. The lower face 3 comprises a recess 8 of corresponding shape, forming a first mortise or groove for the first pin 6 of a lower block. Similarly, the end face 5b has a recess 9, forming a second mortise or groove for the second pin 7 of an adjacent block.

In Figure lA the faces of the tenons and mortises are shown at right angles and the same height / depth, but other arrangements are possible. For example, they may have a trapezoidal profile, and the unhooking of the first and second tenons is not necessarily identical; likewise, the tenons and mortises could be interrupted and present several segments along the corresponding faces. The upper face 2 has an upper opening 10 of oblong shape of width d, located on the first pin 6, and the lower face 3 has a lower opening 11 in the first mortise 8. The length and width of these openings are such that when two blocks are superimposed staggered, the openings come at least partially overlapping. The end face 5a has an opening 12 in the second pin 7 and the opposite end face 5b has a corresponding opening 13 on the second mortise 9. These openings are also oblong in shape of width d.

These openings 10, 11, 12, 13 put into communication a cavity 14 located inside the block with the outside. The cavity 14 has the shape of a blade of constant thickness d equal to the width of the openings. In FIG. 1A the first tenon 6 and the first mortise 8 comprise a single opening, respectively 10 and 11. Other arrangements are possible, for example an upper opening in two longitudinally offset parts, 10a and 10b, and / or an opening lower part in two longitudinally offset parts, 1 la and 1 lb.

With reference to FIG. 1B, another way of describing the building block 1 is as follows. Block 1 is composed of three contiguous parallelepiped sub-blocks, two lateral sub-blocks A and B of the same height and of the same length, and a central sub-block C, situated between the two lateral sub-blocks A and B. The sub-lateral blocks A and B are classic; they comprise in particular longitudinal channels A1, A2, A3 ... and B1, B2, B3 ... which do not communicate with each other. They may be identical or, as shown, have a different width. The central sub-block C also comprises longitudinal channels C1, C2, C3, which do not communicate, but also a cavity 14 in its thickness, which will be described later.

The central sub-block C is offset by a distance H in the vertical direction and a distance D in the longitudinal direction with respect to the sub-blocks A and B. The central sub-block C therefore has two projecting portions with respect to the upper faces. and at one of the end faces of sub-blocks A and B, and two recesses. These projections and recesses are tenons and mortises for assembling the blocks together. The central sub-block C comprises on its upper, lower and end faces respectively apertures 10, 11, 12, 13, of oblong shape and of width d, which put in communication the cavity 14 that it encloses and the outside . This cavity 14 is essentially in the form of a cross. In this first embodiment, the cavity 14 has an identical thickness over its entire extent and equal to the width d of openings 10, 11, 12 and 13. FIG. 2 illustrates a section of block 1 according to the vertical plane X-X ', longitudinal plane of symmetry of the sub-block C. The sub-block C comprises within it a cavity 14 delimited by connecting elements 15a to 15e between the blocks A and B, for example upper, lower openings 10, for example in two parts 11a and 11b in the example shown, and end 12, 13. The sub-block C is offset by a value H in the vertical direction and a value D in the longitudinal direction relative to the sub-blocks A and B. FIG. 3 illustrates a section of the block 1 along the vertical plane Y-Y ', the transverse plane of symmetry of the sub-block C, of a second improved embodiment of the building block 1'. The sub-blocks A and B comprise, as in the case of the first embodiment, channels A1, A2, A3 ... and B1, B2, B3 ... which extend parallel to the side walls 4a and 4b. These channels are blocked by the mortar that joins two adjacent blocks, so they can not be used as horizontal circulation channels. The sub-block C comprises longitudinal channels which frame the upper and lower openings 11, respectively C'l, C'2 and C'3, C'4. The cavity 14 of the sub-block C has openings 10 and 11 located respectively on its upper and lower faces. These openings have a width dl; the end openings 12 and 13 have a width d3 (not shown) which may be different from dl. The cavity 14 has restrictions at the openings 10, 11, 12, 13, that is to say a zone of width d2 in its central portion greater than the width of the openings. This is a larger volume than in the first embodiment to devote to the ventilation of the building envelope or air conditioning. The block 1 'is shown with its cavity 14 filled with an insulating foam with 25 open or closed cells.

Figure 4 schematically illustrates, in vertical section, a block assembly 1 or 1 'staggered. It follows from this that the cavities 14 of the blocks 1 and 1 'must be communicated through the upper and lower openings 10 in the case of single and identical openings on the upper and lower faces. The ends of the openings 10 and 11 are at a distance 1 from the end of the block, the thickness of the joint is equal to e and the length of a block is L. It can be seen that the cavities 14 communicate at least partially if: + e / 2 <L / 2, ie: 2952949 -10- 1 "L e) / 4. During the assembly of the blocks 1 or 1 'and the addition of mortar to form the joints between blocks, mortar is deposited only on the upper faces 2a and 2b of the sub-blocks A and B, which constitute the wings the tenon of the upper face 2 of the block, and not on the projecting portion 6. Similarly, on the ends 5a, 5b of the block 1, the (mortar, cement) is deposited for example only on the faces of end 5c and 5d sub-blocks A and B, which constitute the mortise wings of the end face 5a, and not in the concavity.

In this way, we break the thermal bridges that constitute the joints.

Claims (19)

Revendications1. Building block (1) comprising at least one upper face (2), one lower face (3), two end faces (5a) and two lateral faces (4a), characterized in that it also comprises a cavity (14) opening through at least one respective opening on the upper face (10), on the lower face (Il a, l lb) and on each end face (12, 13). 2. Building block according to claim 1, characterized in that the cavity (14) has a substantially flat shape with the same thickness throughout the space it occupies within the building block. The building block according to claim 1, characterized in that said cavity (14) has a substantially planar shape with narrowing at said upper, lower and end apertures (10, 11a, 11b, 12, 13 ). 4. Building block according to one of claims 1 to 3, characterized in that it further comprises at least a first projecting portion (6) 20 on an upper face (2) or on a lower face (3) and on the opposite side, at least a first concavity (8) cooperating with the first projecting portion of another block, so that, when two blocks are assembled one above the other in a staggered, the opening the upper face of the lower block and the opening of the lower face of the upper block cooperate to ensure continuity between the cavities 25 of the two blocks. 5. Building block according to claim 4, characterized in that said first projecting portion (6) constitutes a first tenon, separating two wings (2a, 2b), and said first concavity (8) constitutes a first mortise, separating two wings, the blocks being assembled one above the other by mortise and tenon assembly. 2952949 -12- 6. Building block according to one of claims 1 to 5, characterized in that it further comprises at least one second projecting portion (7) on one end face and, on the opposite end face, the minus one second concavity (9) cooperating with the second projecting part of another block, so that when two blocks are assembled next to each other, the opening of the end face of one block and the opening of the end face of the other block cooperate to ensure continuity between the cavities of the two blocks. 7. Building block according to claim 6, characterized in that said second projecting portion (7) constitutes a second tenon, separating two wings, and said second concavity constitutes (9) a second mortise, separating two wings, the blocks being assembled next to each other by mortise and tenon jointing. 8. Building block according to one of claims 5 to 7, characterized in that said openings of the lower faces (Il a, Il b) and upper (10) are respectively disposed on the first pin (6) and in the first mortise (8). 9. Building block according to claim 7 or 8, characterized in that said openings of the end faces (12, 13) are respectively disposed on the second pin (7) and in the second mortise (9). 10. Building block according to one of claims 7 to 9, characterized in that the first and second pins (6, 7) have the same value of off-hook. 11. Building block according to one of the preceding claims, characterized in that said cavity (14) has on the upper face of said block 30 two openings offset longitudinally relative to each other. 12. Building block according to one of the preceding claims, characterized in that said cavity (14) has on the underside of said block two openings (Ila, Il b) offset longitudinally relative to each other. 2952949 - 13 - 13. Building block according to one of the preceding claims, characterized in that it constitutes a brick. 5 14. Building block according to one of claims 1 to 13, characterized in that the cavity (14) is filled with insulating foam. 15. A method for raising a wall, characterized in that it comprises the step of: assembling building blocks according to any one of claims 1 to 14 so as to put in register the openings of the upper and lower faces; lower (10, 11a, 1 lb) of two superimposed blocks, as well as the openings (12, 13) of the end faces of two adjacent blocks, so as to ensure the continuity of the cavities of the contiguous blocks. 15 16. A method for raising a wall, characterized in that it comprises the steps of: - assembling building blocks according to any one of claims 7 to 14 by mortise and tenon assembly, so as to match the openings of the upper and lower faces (10, 11a, 11b) of two superposed blocks, as well as the openings of the end faces (12, 13) of two adjacent blocks, so as to ensure the continuity of the cavities of the blocks; depositing binder, such as a mortar, between two blocks only on the flanges framing the first and second tenons, and / or only on the flanges framing the first and second mortises. 17. A method of air conditioning a room, characterized in that it comprises the steps of: - raising at least a portion of at least one wall of the room according to the method of claim 15 or 16, using building blocks according to one of claims 7 to 13, - circulating air in the cavities of said building blocks. 2952949 - 14 - 18. A method of thermal insulation of a room, characterized in that it comprises the steps of: - raising at least a portion of at least one wall of the room according to the method of claim 15 or 16, using building blocks according to one of claims 7 to 13, - injecting an insulating foam into the cavities of said building blocks. 19. A method of air conditioning and thermal insulation of a room, characterized in that it comprises the steps of: - raising a first wall portion of the room according to the method of claim 15 or 16, using building blocks according to one of claims 7 to 13, - raising a second wall portion of the room according to the method of claim 15 or 16, above the first wall portion, - injecting an expansion foam into the cavities building blocks of the second wall portion, - circulating air in the cavities of the building blocks of the first wall portion.