FR3009571A1 - PROCESS FOR MANUFACTURING AN INSULATING BUILDING BLOCK IN NATURAL OR RECONSTITUTED STONE, BLOCK REALIZED AND WALL MADE WITH SUCH A BLOCK - Google Patents

Abstract

The method of producing an insulating building block, of natural stone or reconstituted stone or of concrete or clay, comprising horizontal faces (11), vertical lateral faces (10) extending in the direction of the largest dimension of the block and the vertical end faces (12), characterized in that it consists in: - defining a first model of arrangement and alveolar distribution comprising one or more cells of predefined shapes and full of material forms predefined devices delimiting said cells, - defining a second alveolar arrangement model comprising one or more cells of predefined shapes and solid shapes of predefined shapes, not superimposable to the preceding one, - forming in the mass of a block, according to successive vertical geometrical planes spaced from each other, alternately, grooves reproducing the first and second alveolar pattern so that the p material leins corresponding to each plane or groove is offset with respect to the solid matter of the contiguous plane or planes and that the cells corresponding to each plane or groove are communicating and isolated from the alveoli of the contiguous groove or grooves by a slice of material of uniform thickness. The invention also relates to a building block made using the method.

Description

PROCESS FOR MANUFACTURING AN INSULATING BUILDING BLOCK IN A NATURAL OR RECONSTITUTED STONE, BLOCK PRODUCED AND WALL PRODUCED WITH SUCH A BLOCK Technical field.

The present invention is in the field of manufacturing processes of building blocks of natural stone or reconstituted stone or cement-based concrete and gravel or sand or clay. It also relates to an insulating building block, honeycomb natural stone or reconstituted stone or concrete or clay, and a wall made with blocks according to the invention. State of the art Exemplary building block fabrication methods are known from the state of the art. These processes are mainly used for making blocks or bricks made from clay. Other methods involve molding techniques of a cement-based paste and gravel or sand. State-of-the-art honeycombed building blocks made by extrusion from a clay paste are known. Also known from the state of the art honeycomb building blocks reconstituted stone and cement-based building blocks based on cement and pumice. Solid stone building blocks are also known. On the other hand we do not know building blocks made of natural stone with cells hollowed out in the mass. One of the problems to be solved for this type of block lies in the fact that the cells can greatly weaken the stone building block making it particularly fragile and unusable for the realization in particular of the load-bearing walls. For this reason, those skilled in the art have turned away from the use of such blocks for the realization of constructions. In addition, a disadvantage common to most blocks lies in the fact that their cellular system and their technical configuration in general, do not allow the realization of high thermal resistance wall. Some blocks based on clay, made by extrusion, do not have this last drawback.

Presentation of the invention. According to a first aspect, the invention relates to a method of manufacturing an insulating building block, parallelepiped, honeycomb natural stone or reconstituted, or cement-based concrete and sand or gravel, or clay which block includes horizontal faces, vertical side faces extending in the direction of the largest dimension of the block and vertical end faces. The method according to the invention is remarkable in that it consists in: - defining a first model of arrangement and alveolar distribution comprising one or more cells of predefined shapes and full of material of predefined shapes delimiting said cells, - defining a second cellular arrangement model comprising one or more cells of predefined shapes and solid shapes of predefined shapes, not superimposable to the preceding one, to be formed in the mass of a block, according to successive vertical geometric planes spaced apart; alternating, bleeding reproducing the first and second alveolar pattern so that the solid material corresponding to each plane or bleed is offset from the solids of matter or contiguous planes and that the cells corresponding to each plan or bleeding are communicating and isolated from the alveoli of the contiguous blood or a slice of material of uniform thickness. The formed grooves divide the block into slices of material and the full of material ensure the mechanical connection between the different slices.

The block obtained according to this method has on the one hand a high mechanical strength but also a high thermal resistance, about six times greater than that of walls made with the usual blocks of the same thickness. According to another characteristic, the method consists in producing a first cellular arrangement pattern having an asymmetry at least horizontally and in producing a second cellular arrangement pattern by symmetrizing the first pattern in a horizontal plane. According to another characteristic, the second cellular arrangement pattern is deduced from the first by shifting the latter in the direction of the length of the block. According to another feature, the second honeycomb arrangement pattern is derived from the first by pivoting the latter at an angle of 1800. According to another characteristic, the method consists of preliminarily raising the faces of the block by machining. According to another characteristic, the cells are formed by digging the block from at least one of the horizontal and / or end faces. According to another characteristic, the digging of the block is achieved by vertical or horizontal penetration of a cutting tool in the block. According to another characteristic, the tool is constituted by a circular cutting disk. According to another characteristic, the depth of penetration of the cutting disk into the block is equal to two-thirds of the seat height of said block, the diameter of the disk is equal to at least twice the seat height of the block, for each plane or groove a first horizontal row of cells spaced a constant pitch p is formed in the block from the horizontal upper face thereof, and a second horizontal row of cells is formed in the block from the bottom face this second row of cells being offset from the first by a value equal to p / 2. According to another characteristic, the value of the spacing pitch p is equal to the value of the diameter of the disc. According to another characteristic, the method consists, for each plane or kerf to achieve the cells in a communicating manner. According to another characteristic, the digging of the block is carried out by oblique penetration of a tool from at least one of the horizontal faces of said block and in a through manner. Alternatively, according to another characteristic, the tool is constituted by a chainsaw blade. According to another characteristic, the method consists, for each vertical plane, in introducing the blade alternately with a left inclination and a right inclination. According to another characteristic, the method consists, for each plane, from one of the horizontal faces, of producing a continuous deep groove running from one end face to the other, and, from the other side, to producing a second continuous groove, smaller current depth from one end face to another and to achieve in the solid part remaining between the two grooves, a series of equidistant perforations.

According to another characteristic, the method consists, during the realization of each groove, to superpose the horizontal advance movement of the digging tool of the groove, reciprocating vertical translation movement. According to another characteristic of the process, the block is obtained by molding a paste.

According to a second aspect, the invention relates to a honeycombed stone building block having good mechanical strength despite the formed cells. The honeycombed stone building block, in particular for the construction of a building wall, comprising at least two vertical parallel lateral faces, at least two horizontal parallel upper and lower, forming a joint plane, and at least two faces of vertical end also forming a joint plane, one of the vertical lateral faces or outer face being provided to be turned towards the outside of the building, is essentially characterized in that according to geometric planes parallel to the two vertical lateral faces, it comprises vertical grooves in each of which is formed at least one series of communicating cells opening at least in the horizontal faces, these vertical grooves dividing the block into successive slices of materials, joined two by two by full of material, spaced from each other delimiting the communicating alveoli, the full of material ensuring the mechanical connection between two successive slices of material and the solids of material, a successive slit) to the other being staggered with respect to each other so that no continuous alignment of solids of material is formed between the two lateral faces of the block.

Such an arrangement allows a regular distribution of the solid in the block while avoiding any alignment of solid material likely to constitute direct thermal bridges between the two vertical side faces of the block. The provision of vertical grooves allows to provide air blades capable of providing thermal insulation between the two side faces. The width of these air gaps will be sufficiently small to prevent any movement of air from one side of the groove to the other and thus avoid any convective flow from one side of the groove to the other.

According to another characteristic of the invention, the upper and lower rows of pins are separated respectively from the upper and lower horizontal faces of the building block. Such an arrangement, household in the upper part and lower part, at each groove, continuous horizontal grooves.

According to another characteristic of the invention, the value of the spacing between two rows of solid of the same groove is substantially equal to or close to twice the distance between the axis of each row of the horizontal face which is the closest. In this way, when several blocks stack to form a wall, the horizontal axes of the lines formed by the solid matter are spaced from one block to another, substantially of the same value as on the same block. According to another characteristic of the invention, at least one of the grooves in contact with the slices bearing the vertical lateral faces of the block is wider than the intermediate slits. By this arrangement, this bleeding, if it corresponds to the internal lateral face of the building, can receive conduits for fluids, gas or water and electrical and other conduits, and if it corresponds to the outer face of the building can be crossed, without creating significant pressure losses, by an air space set in motion to temper the building.

According to another characteristic of the invention, the two grooves in contact with the slices bearing the inner and outer side faces of the block have a width greater than that of the intermediate slits. Such a block can thus accommodate fluid conduits in one of the grooves and a moving air gap in the other groove.

According to another characteristic of the invention, at least one of the two side edges carrying the vertical side faces of the block, is thicker than the intermediate slices or the block. The present invention also relates to a wall constructed using blocks according to the invention. Brief presentation of figures and drawings. Other advantages, aims and features of the invention will become apparent on reading the description of a preferred embodiment given by way of non-limiting example with reference to the accompanying drawings, in which: FIG. perspective view of a block according to a first embodiment of the invention, - Figure 2 is a longitudinal sectional view of the block according to Figure 1 - Figure 2a is a cross sectional view along the line AA of FIG. 2 is a reduced scale view in longitudinal section of the block according to an embodiment variant; FIG. 3 is a perspective view of a block according to a second embodiment of FIG. FIG. 4 is a longitudinal sectional view of the block according to FIG. 3; FIG. 4a is a cross sectional view along line BB of FIG. 4; FIG. 5 is a perspective view of FIG. a block according to a third embodiment FIG. 6 is a longitudinal sectional view of the block according to FIG. 5; FIG. 6a is a cross-sectional view of the block along the line CC of FIG. 4; FIG. perspective view of a block according to a fourth embodiment of the invention, - figure 8 is a longitudinal sectional view of the block according to figure 7, - figure 8a is a cross sectional view along the line DD of FIG. 8 is a perspective view of a block according to a fifth embodiment of the invention, FIG. 10 is a longitudinal sectional view of the block according to FIG. 9, FIG. FIG. 11 is a perspective view of a block according to a sixth embodiment of the invention; FIGS. 12 and 12a are diagrammatic views of the block according to line EE of FIG. longitudinal sectional views of the block according to FIG. 11, made in two vertical planes corresponding to two successive bleedings, - Figure 12b is a cross-sectional view of the block according to the line FF of Figure 12a, - Figure 13 is a perspective view of a corner structure according to a first embodiment of the invention. FIG. 14 is a perspective view of an angle structure according to a second embodiment of the invention; FIG. 15 is a vertical sectional view of a wall made using blocks in accordance with FIG. to the invention.

Best way to realize the invention. As shown, the building block 1, monolithic, honeycomb, natural stone or reconstituted or even concrete, or clay, according to the invention, used for the construction of the walls of a residential building for example , comprises two vertical parallel side faces 10, two horizontal parallel faces 11 forming jointing planes, and two vertical end faces 12, also forming a joint plane, one of the vertical side faces or outer face being intended to be rotated towards the outside of the building, while the other, the inner face, is intended to be turned towards the interior of the building.

According to the invention, the block 1 according to geometric planes parallel to the two vertical lateral faces 10 comprises vertical grooves 13 opening at least in the two horizontal faces 11, these grooves 13 dividing the block into successive slices la of material, together two by two by one or full of material 14, spaced from each other and distributed in each groove. These solid material 14 provide the mechanical connection between two successive slices 1a; they result from the process of forming the grooves 13 and the cells and are cut into the mass of the block. These full 14 material delimit for each bleeding common cells iquants.

According to the embodiment object of Figures 1, 2, 2a, 2b, the full 14 of material are organized in two parallel rows, horizontal upper and lower. The solid material 14 of each row are regularly spaced along the latter with a spacing pitch p. The upper and lower rows are shifted longitudinally relative to each other by a value equal to that of a half pitch spacing p / 2 so that the solids of each row are respectively at the intervals between the full 14 of the other row.

It can be seen in Figures 2, 2b that the full14 and the cells they delimit appear in continuous lines and define a first model of arrangement and alveolar distribution while those appearing in dotted lines in this figure, formed in the or the two adjacent grooves define a second alveolar distribution pattern. Note also that the second model is deduced from the first by symmetrization of the latter in a horizontal plane P1 located equidistant from the upper and lower faces 11 of the block. Thus the upper rows of full 14 two adjacent bleeds 13 are offset longitudinally relative to each other by the value of a half p / 2 so that the full of one of its two upper rows is find the right intervals between the full 14 of the other top row. The same arrangement is reproduced with regard to the two lower rows of solid 14 of two adjacent grooves 13. By these provisions is avoided any continuous alignment of solid 14 between the internal and external side faces of the block 1, of nature to create direct thermal bridges between the two faces 10. On the other hand, the offset created, increases the thermal path between these two faces 10. Advantageously, the upper and lower rows of full 14 are spaced respectively from the upper and lower horizontal faces 11 of the block of construction. Such an arrangement provides at the upper part and in the lower part, at each groove 13, continuous horizontal grooves perforated flat bottom. Still according to the preferred embodiment, the value of the spacing between two rows of solid 14 of the same groove 13, is substantially equal to or close to twice the distance between the axis of each row of the horizontal face 11 which is closest to him. In this way, when several blocks 1 are stacked to form a wall, the horizontal axes of the rows formed by the solid 14 are spaced from one block to another substantially of the same value as on the same block. In the embodiment which is the subject of FIGS. 1 and 2, 2a, the solid parts 14 have an isosceles trapezium shape. The large base and oblique sides of this isosceles trapezium are formed by arcs of circular circumference. Such an arrangement results from the digging of the groove 13 and therefore the realization of the cellular arrangement model using a circular cutting disc driven in rotation and in vertical translation in the block. The diameter of the cutting disk is equal to or greater than at least twice the seat height of the block, this height corresponding to the normal distance between the two horizontal flat faces 11 of the block. The penetration depth of the disc in the block is equal to two thirds of the seat height. Finally, the value p corresponding to the spacing pitch of the solids 14 of each lower and upper row, and consequently to the spacing pitch of the cells situated between the solid parts 14, may be equal, without being limiting, to the 15 value of the diameter of the disc. The upper and lower grooves are formed using the cutting disc; for this purpose, the latter, always being rotated, is animated by an advance movement parallel to the upper and lower faces 11 of the block. Due to these arrangements, the solids of material 14 have a section sufficient to give the building block sufficient mechanical strength despite the formation of the grooves 13. It is noted that the grooves 13 also open into the end faces 12. can see more particularly in Figures 2, and 2b that the full 14 end of one of the rows of each groove, insofar as one of the ends of a block corresponds to their vertical axis of symmetry, form each half-pattern so that, in such a case, a complete pattern of full is reconstituted at the abutment of two blocks 1 by one of their two end faces 12. Such an arrangement is reproduced alternately for the lower and upper rows of different grooves 13. According to an alternative embodiment, as shown in Figure 2b, the material pins 14 are each in the form of a triangle c urviligne.

Such an arrangement results from the formation of the grooves and the solid with the aid of a larger diameter cutting disc. In Figure 3, 4, and 4a is shown a block according to a second embodiment. It can be seen that the grooves 13 open both in the horizontal faces 11 and upper than in the end faces 12. The solid 14 are divided into three horizontal rows namely two upper and lower rows and a middle row. In this embodiment, the full lengths of the middle row are diamond-shaped while the full 14 of the top and bottom rows are in the form of an isosceles triangle corresponding to the half-pattern of the diamond shape of the solid ones. the middle row. Note also that the base of each isosceles triangle that forms each full of the upper row, is contained in the horizontal upper face 11 of the block while the base of each isosceles triangle that forms the full 14 of the lower row is contained in the lower face 11 of the block. Such an arrangement has the effect of increasing the importance of the joint surfaces that constitute the lower and upper faces of the block and consequently, when making a wall, has the effect of strengthening the connection between the rows of block.

Such arrangements, according to a first technique of manufacture by removal of material, result from the digging of each groove 13 and thus the realization of the honeycomb arrangement model, with the aid of a saw blade, caused to penetrate into the obliquely traversing block, alternately with a right inclination and a left inclination. Note that the full 14 of the different rows are regularly spaced with the same pitch spacing. Note also that the full 14 of the upper and lower rows are aligned along vertical axes and that the middle row of full 14 is shifted longitudinally relative to the upper and lower rows of the value of half a pitch spacing p / 2 between the full 14, so that the full 14 of this middle row are located at the intervals between the full 14 of the upper and lower rows. It can also be seen in FIG. 3 that the end solids 14 are upper and lower rows, or the middle row of each groove 13, insofar as one of the ends of a block corresponds to their vertical axis of symmetry. , each form a half pattern so that, in such a case, a complete solid pattern 14 is reconstituted at the abutment of two blocks 1 by one of their end faces 12. In Figure 4, the first model The alveolar arrangement pattern appears in bold lines while the second alveolar pattern pattern reproduced in the adjacent bleed or grooves appears in dashed lines. It is observed that this second model of cellular arrangement is deduced from the first by translation along the length of the block of a value equal to that of a half pitch spacing p / 2. In this way, the full 14 of material of each groove 13 are located in line with the intervals between the solid material 14 adjacent grooves, always in order to avoid any continuous alignment of full 14 material between the side faces 10 of the block.

In Figure 5, 6 and 6a is shown a third embodiment of the block according to the invention. The grooves 13 open into the horizontal faces 11 and the lateral faces 12. The solid 14 of each groove 13 are distributed equidistantly in a horizontal row disposed close to one of the horizontal faces 11 and at a greater distance from the other face 11. In order to ensure the holding of the block, there are provided spaced bracing pins 15, preferably made of expanded glass, or any other thermally insulating material, glued to the internal faces of the groove 13. These pins 15 equidistant form a horizontal row. These pins 15 are spaced from each other by the value of the same spacing pitch p. These pins 15 may be located at the intervals between the full 14 or be arranged at the right of these full 14. These pins are spaced apart from each other by the value of spacing pitch p. It is also noted that the studs 15 of each groove 13 are offset relative to the pins 15 and the full 14 of the one or both adjacent grooves to avoid forming continuous alignments of pions and / or pions and solid, d one face 10 to the other. Such full arrangements 14 result from the digging of each groove using for example a cutting disc driven in rotation and in translation along the length of the block. Thus, with a view to producing the honeycomb arrangement model specific to the groove 13 in question, a first deep groove will be hollowed out from one of the horizontal faces 11 of the block and a second shallower groove from the other face 11 of the block. so as to leave a linear bead of material. This linear cord will then be perforated for the formation of the full 14 using any suitable cutting tool such as chainsaw blade or cutting disc. In FIG. 6, the first alveolar arrangement model appears in full lines, while the second alveolar arrangement model, reproduced in the adjacent groove (s) 13, appears in dashed lines. Note that this second arrangement model is deduced from the first translation of the latter downwards and translation in the direction of the length of the block according to a value equal to p / 2. In FIGS. 7 and 8 and 8a is shown a fourth embodiment of the block according to the invention. This embodiment is in accordance with the previous one except that the two rows of solid 14 and pins 15 are respectively tangent to the upper and lower faces 11 of the block and that the second alveolar arrangement model is deduced from the first only by simple translation operated according to the length of the block of a value equal to p / 2.

In Figures 9, 10 and 10a is shown a block according to a third embodiment. It can be seen that the grooves 13 open into both the horizontal faces 11 and the vertical end faces 12. The full 14, of square outline, are distributed in two horizontal rows spaced apart from each other. The solids of each row are spaced from each other at the same spacing pitch p. In this embodiment, the full 14 of each row are located at the right of the full 14 of the other row. It is also noted that one of the rows of full 14 is tangent to the horizontal face 11 which is closest to it while the other full row 14 is spaced from the horizontal face111 which is closest to it to provide a discontinuous flat bottom groove. In addition, one of the two end faces of each row is tangent to the end face 12 which is closest thereto, the other end end 14 being in this case separated from the other face of the end face. end 12 of a value corresponding to that of the spacing step of the full 14 in each row. Such provisions result from the digging of each groove 13 using for example a saw blade caused to penetrate the block both vertically and horizontally to form the cells and concomitantly, the full 14 material. In Figure 10 appears in bold lines the first pattern of cellular arrangement and in dashed lines the second alveolar arrangement model, the second model being reproduced in the adjacent grooves 13. This second model is deduced from the first by a first translation of the latter operated along the length of the block and according to a value equal to half a pitch spacing p / 2 and a second translation operated according to the height of the block. In Fig. 11, 12 and 12a is shown a sixth embodiment. It can be observed in FIG. 12 that the solid ones are distributed not in a horizontal rectilinear row but in a horizontal undulation formed near one of the two horizontal faces. In order to increase the strength of the block, a horizontal row of equidistant pawns spaced from a pitch p is formed in the groove 13 away from the full ones 14. These pins 15 are preferably made of expanded glass or any other thermally insulating material and are glued on both sides of the groove 13. It is also noted that the studs 15 of each groove 13 are offset relative to the pins 15 and the full 14 of the one or two adjacent grooves to avoid forming continuous alignments of pins and / or pions and solid, from one face to the other. Such full arrangements 14 result from the digging of two opposite grooves, from the horizontal faces using for example a cutting disc driven in rotation, in translation along the length of the block and in vertical translation in a reciprocating motion. Thus is formed a bead of continuous corrugated material which is then perforated for the formation of the full 14 using any suitable cutting tool such as saw blade or cutting disc. In Fig. 12, the first honeycomb arrangement pattern appears in solid lines while the second honeycomb arrangement pattern appears in dashed lines. We can notice that this second model of arrangement is deduced from the first translation downwards of the full 14.

Preferably the building block as described in its various embodiments, has two side edges corresponding to the outer and inner faces 10 and one or more intermediate slices parallel to the side slices. Preferably, at least one of the two side slices 1a is thicker than the intermediate slice or slices. Such an arrangement gives the thick wafer increased mechanical strength. In the embodiments described, the two side slices 1a are thicker than the intermediate slices always in order to give the slices most exposed to shocks, increased strength.

Still according to the preferred embodiment, at least one of the grooves 13 in contact with the lateral slices 1a that is to say those carrying the vertical side faces 10 of the block 1 is wider than the intermediate slits. By this arrangement, this bleeding 13, if it corresponds to the internal side face of the building may receive conduits for fluids, gas or water and electrical conduits and the like, and if it corresponds to the outer face of the building can be crossed, without creating significant pressure losses, by an air space set in motion to temper the building. With a view to its mechanical reinforcement, the block according to the invention may be equipped with metal bars embedded in oblique or horizontal grooves formed in the end faces 12 and fixed rigidly by any known means, to the different slices 1a of the block. Such an arrangement ensures the bracing of the different slices of the block. In Figures 13 and 14 is shown an angle structure formed by two blocks 1 according to the invention. It can be seen that the blocks forming this corner structure are joined to each other and form a non-flat angle between them preferably a right angle. This angle structure has two external and internal vertical lateral faces each forming a dihedron, two upper and lower horizontal faces 11 and two vertical end faces 12 arranged in planes perpendicular to each other. It can be seen that according to this embodiment, the side slices namely the slices bearing the inner and outer faces of the corner structure, also form a dihedron. We also note that the side faces are 10 are continuous. According to the embodiment object of Figure 13, a through hole 16 is formed at the junction between the two blocks 1, parallel to the intermediate slices of the first block. With this arrangement, the intermediate wafers 1a of the second block are kept spaced from the first block, so that the kerf in contact with the wafer carrying the inner face of this first block communicates through this perforation 16 with the grooves 13 of the other block. It may be noted that the grooves 13 that the first block 1 has are not open at the angle formed by the angle structure, but are closed by an attached wall.

The angle structure according to the embodiment object of Figure 14, does not include through hole 16 and no communication can be established between the grooves 13 of the two blocks 1. The block as described is preferably made by machining d a mass of natural stone or reconstituted stone, but this block can be obtained by molding a hardenable paste based on aggregates of natural stone or other and a hydraulic binder such as cement with sand or gravel or from any other ingredients such as clay, used in the building industry for the manufacture of building blocks. In order to produce them by molding, molds will be used in several parts that can be assembled together in accordance with joint plans. These molds in known manner may be associated with vibrating devices. In Figure 15 is shown a wall made by block stack 1 according to the invention. Preferably, these blocks are assembled to each other by a binder which may be an adhesive. This binder is affixed to the horizontal faces 11 and the end faces 12 and the blocks 1 are arranged so that the grooves 13 of each of them are in communication with the homologous grooves 13 of the adjacent blocks 1. Thus the wall produced has a series of parallel vertical air slats, extending from bottom to top forming insulating layers.

In order to ensure the tightness of these air gaps, each block 1 will comprise along its longitudinal and vertical edges continuous rabbets provided to receive after stacking, a sealed binder. Advantageously, at least the air space closest to the outer face of the wall can be circulated between a lower heat exchanger 17 of the Canadian well type formed in the ground, around the foundations for example, and a heat exchanger. air 18, disposed in the upper part of the construction.

The Canadian well 17 will comprise an air intake opening in communication with the atmosphere, for example, and will be in sealed communication relation, by any means of connection adapted with the groove or grooves 13 accommodating the at least one air gap. movement. The air extractor 18 will also be in tight communication with these same 10 bleeds 13. Such an arrangement can temper the building. The wall in the upper part and in the lower part will receive closure means 19 of the grooves 13 corresponding to the air blades not set in motion. These closure means 19 may be formed by a layer 15 of cellular glass or the like. Advantageously, the air extractor 18 is controlled by a temperature probe, known per se, not shown, set with respect to low and high temperature peaks. This temperature sensor will be sensitive to the temperature outside the building.

It goes without saying that the present invention can accommodate any modifications and variations of the field of technical equivalents without departing from the scope of this patent as defined by the claims below.

Claims (4)

CLAIMS1 / A method for producing an insulating building block, honeycomb natural stone or reconstituted or concrete or clay, comprising horizontal faces (11), vertical side faces (10) extending in the direction of the most large dimension of the block and vertical end faces (12), characterized in that it consists: - in defining a first cellular arrangement pattern comprising one or more cells of predefined shapes and solid shapes of predefined shapes, defining a second cellular arrangement pattern comprising one or more cells of predefined shapes and solid shapes of predefined shapes, which can not be superimposed on the preceding one, to be formed in the mass of the block according to successive vertical geometric planes, separated by each other, alternately, the first and second alveolar pattern so that the solid matter corresponding to each plane 15 are offset s with respect to the solids of the contiguous plane or planes and that the cells corresponding to each plane are communicating and isolated from the cells of the adjacent plane or planes by a blade of material of uniform thickness. 2 / A method of manufacturing a building block according to claim 1, characterized in that it consists in producing a first alveolar arrangement pattern having an asymmetry according to at least the horizontal and in making a second pattern of alveolar arrangement by symmetrization of the first pattern in a horizontal plane. 3 / A method of manufacturing a building block according to claim 1, characterized in that the second pattern of cellular arrangement is deduced from the first offset of the latter in the direction of the length of the block. 4 / A method of manufacturing a building block according to claim 1, characterized in that the second pattern of cellular arrangement is deduced from the first by pivoting the latter at an angle of 180 °. 5 / A method of manufacturing a building block, according to any one of claims 1 to 4, characterized in that it consists in prior to erect the faces of the block by machining. 6 / A method of manufacturing a building block, according to any one of the preceding claims, characterized in that the cells are formed by digging the block from at least one of the horizontal faces and / or end. 7 / A method of manufacturing a building block according to claim 5, characterized in that the digging of the block is achieved by vertical (downward) or horizontal penetration of a cutting tool in the block. 8 / A method of manufacturing a building block according to claim 6 or claim 7, characterized in that the tool is constituted by a circular disc 10 cutting. 9 / A method of manufacturing a building block according to the preceding claim, characterized in that the depth of penetration of the cutting disc in the block is equal to two-thirds of the seat height of said block, that the diameter of each cell formed is equal to at least twice the seating height of the block, that for each plane a first horizontal row of cells spaced at a constant pitch p is formed in the block from the horizontal upper face of the latter and a second horizontal row of cells is formed in the block from the bottom face, and this second row of cells is offset from the first by a value equal to p / 2. 10 / A method of manufacture according to the preceding claim, characterized in that the value of the spacing pitch p is equal to the value of the diameter of each cell. 11 / A method of manufacture according to claim 9 or claim 10, characterized in that it consists, for each plan to achieve the cells communicating manner. 12 / A method of manufacturing a building block according to claim 6, characterized in that the digging of the block is achieved by oblique penetration of a tool from at least one of the horizontal faces of said block and in a through manner . 13 / A method of manufacturing a building block according to the preceding claim, characterized in that the tool is constituted by a saw blade.14 / A method of manufacturing a building block according to the preceding claim, characterized in that that for each plane, it consists of alternately introducing the blade with a left inclination and a right inclination. 15 / A method of manufacturing a building block according to claim 6 or claim 7, characterized in that it consists, for each plane, from one of the horizontal faces, to achieve a deep continuous continuous groove of a end face to the other and from the other side continues to achieve a second continuous groove, smaller depth running from one end face to the other and to achieve in the solid part remaining between the two grooves a series equidistant perforations. 16 / manufacturing method according to the preceding claim, characterized in that it consists in the realization of each groove to be superimposed on the horizontal advance movement of the digging tool of the groove, reciprocating vertical translation movement. 17 / A method of manufacturing a cellular building block, according to any one of claims 1 to 4, characterized in that it is obtained by molding a paste. 18 / Block of stone construction, honeycomb, especially for the construction of building wall, comprising at least two vertical parallel side faces (10), at least two parallel horizontal faces (11) forming a joint plane, and at least two faces vertical end portions (12), also forming a jointing plane, one of the vertical lateral faces (10) or outer face being provided to be turned towards the outside of the building, characterized in that according to geometric planes parallel to the two vertical side faces (10), it comprises vertical grooves (13) in each of which is formed at least one series of communicating cells opening at least in the horizontal faces (11), these vertical grooves (13) dividing the block into slices successive materials (1a), joined two by two by solids of material (14), spaced apart from each other delimiting the communicating cells, the solid material (14) a ssurant the mechanical connection between two successive slices of material and the solid matter (14), a successive slit (13) to the other being offset relative to each other so that no continuous alignment of solids of material (14) ) is formed between the two lateral faces of the block. 19 / building block according to the preceding claim, characterized in that the solid material (14) at each groove (13) are organized in at least two horizontal rows, the solid (14) of material of each row are spaced from a constant pitch p and that from one successive row to another, the solid material (14) are offset with respect to each other by the value of a half step p / 2. 20 / building block according to the preceding claim, characterized in that the rows of solid (14) material, upper, lower and optionally intermediate, two successive grooves (13) are respectively shifted from one to the other d a value equal to half a pitch spacing. 21 / building block according to any one of claims 18 to 20, characterized in that the upper and lower rows of solid material (14) are spaced respectively from the horizontal faces (11) upper and lower of the building block. 22 / Building block according to the preceding claim, characterized in that the value of the spacing between two rows of solid material (14) of the same groove (13) is substantially equal to or close to twice the gap between the axis of each row of the horizontal face (11) which is closest thereto. 23 / building block according to any one of claims 18 to 22, characterized by material studs (15), reported between the slices (1a) 25 of material (1a) and fixed thereto by gluing. 24 / building block according to the preceding claim, characterized in that the pins (15) of material are thermally insulating. 25 / Building block according to any one of claims 18 to 24, characterized in that at least one of the grooves (13) in contact with the slices (1a) carrying the vertical side faces (10) of the block is more wide than the others. 26 / Building block according to any one of claims 18 to 25, characterized in that the grooves (13) open into the end faces (12) of the block. 27 / Building block according to any one of claims 18 to 26, comprising two side edges (1a) of material carrying the side faces (10) and at least one intermediate slice (1a) of material, characterized in that the at least one of the two side slices (1a) is thicker than the intermediate slice or slices. 28 / Angle structure formed by two building blocks according to any one of claims 18 to 27, characterized by a through perforation (16) formed at the junction between the two blocks, parallel to the intermediate slices of one block segments. 29 / Wall characterized in that it is made by blocks and angular structure according to any one of claims 18 to 27. 30 / Mur according to the preceding claim, characterized in that it has a succession of blades d air formed by the grooves (13) of the blocks, each groove (13) of each block being communication relationship with the groove (13) homologous to the or each adjacent block. 31 / Wall according to the preceding claim, characterized in that at least the air knife closest to the outer face of the wall is in communication relation on the one hand, in the lower part, with a heat exchanger 20 type Canadian well (17) formed in the ground, and secondly, in the upper part, with an air extractor (18) to be put into circulation.