FR3087212A1 - INSULATING INSERT FOR CONCRETE BUILDING BLOCK - Google Patents

Abstract

Insulating insert for concrete building block The present invention aims to significantly improve the insulation coefficient of a concrete building block commonly called hollow block (100) by compressing and introducing into each of the cells (110) of said block (100), an insulating insert (200) consisting of a support plate (216) and a rigid counter plate (230), enclosing an compressible insulating block (220) such as, for example, glass wool, rock wool, hemp wool, wadding cellulose, heat-reflective cellular insulation with high insulation coefficient etc. said insulating insert (200) deploying inside said cell (110) to occupy all of its available volume, except in the case where the insulating block (220) is in thermo-reflective celled insulation with a high insulation coefficient where in this case, the support plate (216) is replaced by a support plate arranged so as to leave a free space between the internal face of the hollow block cavity (110) (100) and said fitted support plate. Figure of the abstract: Figure 2

Description

Description

Title of the invention: Insulating insert for building concrete block The present invention relates to an insulating and compressible insert intended to be introduced into each of the cells of a manufactured concrete block, to significantly improve its ability to insulation and subsequently reduce the cost and size of the insulation materials commonly reported on the walls and walls made of these building blocks. Indeed, the significant improvement in thermal insulation performance made to the building blocks making up a wall makes it possible to reduce the thickness of the internal insulation of a building and thus increase its living area.

We know that the concrete blocks more generally designated as concrete blocks which constitute most of the walls of our dwellings, were designed to present two opposite smooth faces in order to simultaneously realize two opposite faces of a wall. Variable in size and also in its design (more than 150 references), the concrete block is most often used in its original form, that is to say that of a hollow parallelepiped whose internal volume is compartmentalized in several alveoli of the same dimensions and most often six in number.

This fundamental element of masonry called chipboard in common parlance of the profession, is a block of molded concrete which hollow or not offers the best value for money. Regular in shape, extremely resistant and economical, it is the main component of the exterior walls of conventional constructions. It is used alone, especially in the construction of hangars, enclosure walls, etc. or joined with other identical units with a layer of mortar to strengthen the strength of the construction. It is one of the building materials with a high thermal mass.

The walls composed of an assembly of many blocks are commonly covered on their exposed surface outside of a coating, most often colored, with metal, wood or plastic cladding or split by the addition of decorative brick facing in certain regions or countries.

Several qualities of blocks are proposed and chosen according to the type of construction envisaged or the quality sought.

The most common blocks are made of cement or terracotta and poor thermal and sound insulation. However, the alveolar terracotta blocks make it possible to comply with thermal regulations when they are very thick.

Light concrete blocks can incorporate sparse aggregates such as expanded clay, pumice, expanded shale or pozzolan to improve their thermal insulation but without great convincing results.

The aerated concrete blocks have characteristics almost identical to those of the above categories but have a more homogeneous material.

According to the latest regulations in force, the dimensions of concrete blocks in France are fixed at a height of 25 cm, a length of 50 cm and a variable thickness from 10 cm to 20 cm depending on the intended uses.

The concrete block in common use is generally composed of 87% of aggregate (stones, gravel, sand), 7% of cement and 6% of water. Its composition generally requires interior or exterior insulation. Being 100% mineral, it is obviously completely recyclable.

In addition to its resistance characteristics which vary according to the load to be supported, the thermal conductivity of the most used concrete blocks, ie with ordinary aggregates, oscillates between 1.07W / mK and 2.71 W / mK, depending on its density. , indoor or outdoor use.

The thermal resistance is determined according to a coefficient R imposed by the French standards in force, according to the thicknesses and the destination of the walls.

Sensitized by the problems encountered in terms of thermal and sound insulation of constructions, the author of the present patent has imagined a flexible and compressible insert of suitable shape and dimensions to be introduced without particular effort, in all simplicity and speed, inside a cell of a building block.

To fully understand the invention and given the number of different models of this type of material, the drafting of this patent will focus exclusively but without this being exhaustive, towards a standard hollow block most used in France, offering in a parallelepiped 25 cm high, 50 cm long and 20 cm thick six cells of the same dimensions designated below: standard hollow block.

According to one of the configurations of the invention, the flexible and compressible insert of the invention, hereinafter referred to as an insulating insert mainly consists of at least two fundamental elements, on the one hand, an element called a support plate consisting of '' a smooth or fitted flat plate of small thickness, of shape and dimensions adapted to penetrate effortlessly and by simple sliding inside a cell of a standard hollow block hereinafter designated hollow block and on the other hand a block of compressible insulating material called insulating block made for example of glass wool, rock wool, hemp wool, cellulose wadding, thermo-reflective cellular insulation with high insulation coefficient or any other insulating material capable of being compressed for significantly reduce the volume.

According to the preferred configuration of the invention, the insulating insert comprises three elements associated functionally with one another: a first element called a support plate consisting of a smooth or fitted flat plate of small thickness, of shape and dimensions suitable for penetrate effortlessly and by simple sliding inside a cell of a hollow block, a second element called insulating block made of compressible insulating material made for example of glass wool, rock wool, hemp wool, cotton wool cellulose, thermo-reflective cellular insulation with high insulation coefficient or any other insulating material capable of being compressed to reduce its volume appreciably, and a third element known as against plate consisting of a smooth flat plate of small thickness, of shape and dimensions adapted to penetrate effortlessly and by simple sliding inside a cavity of a concrete block hollow. According to this preferred configuration of the invention, the support plate is secured by hot or cold bonding or any other means of definitive association, to one of the faces of the insulating block and the counter plate is secured by hot bonding or cold or any other means of definitive association, with the other opposite face of the insulating block, in such a way that said insulating block associated integrally by one of its faces with the support plate and by the other of its faces with the against plate, can compress and relax freely between said plates to reach its maximum volume.

In this preferred configuration of the invention, the support plate of the insulating insert, preferably made of rigid cardboard, is permanently secured by one of its faces, to one of the faces of an insulating block made in particular of wool. glass thickness around 7 to 7.5 centimeters, compressible material commonly used today in construction. The other face of said insulating block is then associated with one of the faces of a counter plate, preferably of the same material, shape and dimensions as the support plate, in such a way that said insulating block thus formed can compress freely relax between said plates to reach its maximum volume.

In this configuration of the invention, the external dimensions (width and height) of the support plate of the insulating block and of the counter plate are close and determined so that once the insulating insert is compressed and introduced inside a hollow concrete block cell, the insulating block, sandwiched between the support plate and the counter plate can relax and fill the interior of said cell, without any of the three elements constituting the insulating insert does not protrude from the upper plane of the hollow block.

According to a different configuration of the invention, the external dimensions (width and height) of the support plate, the insulating block and the counter plate are determined so that, once the insulating insert is compressed and introduced inside a hollow concrete block cell, the insulating block sandwiched between the support plate and the counter plate can relax and fill the interior of said cell, leaving it protrude above the upper plane of the concrete block hollow an excess part of insulation to optimize by compression the development of the insulating block inside the cell during the stacking of the hollow blocks one on the other. In another configuration of the invention, the support plate of the insulating insert is arranged on its free face opposite the insulating block, so that once placed opposite and resting on the internal face of a hollow concrete block cell, it reserves a free hollow space called free space between on the one hand the internal face of said cell of said hollow concrete block and its free formed face, thus constituting a sufficient volume of air to improve the coefficient d insulation of the insulating insert.

According to a mode of manufacture of this configuration of the invention, the support plate has on its free face opposite the face integral with the insulating block, an arrangement consisting of the presence over all or part of its height and on the two longest sides of its main plane of two perpendicular edges raised, called the support edge, so that once the support plate is placed facing and resting on the internal face of a cell of a hollow block, by this arrangement, it reserves a free space between on the one hand the internal face of said cell of said hollow concrete block and its fitted face, thus constituting a volume of air sufficient to improve the insulation coefficient of the insulating insert.

According to another method of manufacturing this configuration of the invention, the support plate has on its free face opposite the face integral with the insulating block, an arrangement consisting of the presence over all or part of its height and on the two longest sides of its main plane of two added strips, said support strip, of width and thickness determined in such a way that once the support plate is placed facing and in abutment on the internal face of a cell d '' a hollow concrete block, this reserves a free space between on the one hand the internal face of said cell of said hollow concrete block and its fitted face thus constituting a sufficient volume of air to improve the insulation coefficient of the insulating insert .

According to a different manufacturing method from this configuration of the invention, the support plate has on its free face opposite the face integral with the insulating block, an arrangement consisting of the presence over all or part of its height and preferably near the longest sides of its main plane of two folds called support ply, so that once placed facing and resting on the internal face of a hollow concrete block cell, it reserves a free hollow space between on the one hand the internal face of said cell of said hollow block and its arranged face thus constituting a volume of air sufficient to improve the insulation coefficient of the insulating insert.

According to another method of manufacturing this configuration of the invention, the support plate has on its free face opposite the face integral with the insulating block, an arrangement consisting of a free and closed volume of support volume formed by a main plane parallel and opposite to the support plate preferably of identical surface and connected to the latter by means of two opposite parallel side planes, so that once placed opposite and in abutment on the internal face of a cell of a hollow concrete block, it reserves a free space but in a determined limited space between on the one hand the main plane, the support plate and the lateral planes, thus constituting an air volume sufficient to improve the insulation coefficient of The insulating insert.

According to a different manufacturing mode from this configuration of the invention, the insulating block is retained inside a compressible space called compressible space limited at the periphery by the support plate and the counter plate joined by their upper edge and their lower stop by means of two so-called foldable planes, the support plate itself carrying on its free surface, an arrangement consisting of a free volume and closed at the periphery said support space constituted by a main plane parallel and opposite to said support plate preferably of identical surface and connected to the latter by means of two planes known as opposite parallel abutment plane, said abutment plane, thus constituting with the support plate and its opposite plane, a volume of air sufficient to improve the coefficient of insulation of the insulating insert.

According to another method of manufacturing this configuration of the invention, the support plate has on its free face opposite the face integral with the insulating block, an arrangement consisting of the presence preferably near each corner, d '' at least one boss said support boss so that once placed facing and resting on the internal face of a cell of a hollow block, it reserves a free space between on the one hand the internal face of said hollow concrete block cell and its fitted face, thus constituting a volume of air sufficient to improve the insulation coefficient of the insulating insert.

According to a different manufacturing mode from this configuration of the invention, the insulating block consists of a combined heat-reflective insulating honeycomb combining a succession of thin sheets of insulation not exceeding the surface limits of the plates support and counter plate of the insulating insert, for example of the extruded polystyrene or insulated bubble film type, each thin plate of insulator forming a succession of folds and being associated integrally with another identical insulating plate by the top of each fold , by bonding or welding an intermediate aluminum film.

Thus, the thin insulating plates opposite to each other, constitute a succession of layers of cells filled with air when the insulating block relaxes inside a hollow concrete block cell and empty of air when the insulating block is compressed between the support plate and the counter plate.

In this manufacturing method, the insulating block is kept in a compressed state to facilitate its transport before use, by means of a link called insert link easily broken after the introduction of the insulating insert into a cell of a hollow block, of a stirrup enclosing the insulating block between the two plates integral with its end planes and easily removed after the introduction of the insulating insert into a cell of a hollow block, of a bag called insert bag easily removed after the insertion of the insulating insert into a cell of a hollow block, or any other means of compression for single use, easily and quickly extractable and disposable.

The device here described in the specific case of a particular application, is in no way limited to this single application, it can be implemented in other applications and according to other manufacturing methods.

The following description with reference to the accompanying drawings by way of nonlimiting examples will allow a better understanding of how the invention can be put into practice.

[Fig. 1] is a perspective view showing the installation of the insulating insert in a hollow concrete block cell.

[Fig.2a] is a partial view of a hollow concrete block in two cells of which the insulating inserts of the invention have been introduced reserving a free space between the internal surface of the cell and the support plate of said inserts.

[Fig.2b] is a partial view of a hollow concrete block in two cells from which the insulating inserts of the invention have been introduced without reserve of free space between the internal surface of the cell and the support plate of said cells inserts.

[Fig.3a] is a perspective view showing the three elements of the dissociated insulating insert, the design of the support plate not reserving free space.

[Fig.3b] is a perspective view showing the three elements of the insulating insert dissociated, the support plate being arranged to reserve a free space between itself and the internal surface of the cell.

[Fig.3c] is a perspective view showing the three elements of the associated insulating insert, the insulating insert of the invention being compressed to reduce its size before introduction into the cell of a concrete block.

[Fig.4] is a perspective view of a cellular heat-reflective insulation used in the manufacture of a configuration of the insulating insert.

[Fig.5] is a perspective view from above of an insulating insert, the three elements of which are dissociated and using the cellular heat-reflective insulation used in the manufacture of a configuration of the invention.

[Fig.6] is a perspective view of an insulating insert without the presence of free space.

[Fig.7] is a perspective view of an insulating insert showing an arrangement of the support plate consisting of two raised longitudinal edges.

[Fig.8] is a perspective view of an insulating insert, showing an arrangement of the support plate consisting of a closed space between two opposite main planes and joined together by two lateral planes.

[Fig-9] is a perspective view of an insulating insert without insulating block, showing an arrangement of the support plate consisting of a compressible closed space protecting the insulating block and an arrangement of the counter plate consisting of a space closed rigid to constitute a free space.

[Fig.10] is a perspective view of an insulating insert, showing an arrangement of the support plate consisting of two raised longitudinal folds.

[Fig.l 1] is a perspective view of an insulating insert, showing an arrangement of the support plate consisting of a plurality of bosses.

[Fig. 12] is a perspective view of an insulating insert, showing an arrangement of the support plate consisting of two added longitudinal strips.

[Fig. 13] is a top view showing an insulating insert deployed and consisting of an insulating block, the counter plate and the unsupported support plate and not reserving free space.

[Fig. 14] is a top view showing an insulating insert deployed and made up of an insulating block of heat-reflective insulating honeycomb, the counter plate and the support plate arranged to reserve a free space.

[Fig. 15] is a perspective view showing the insulating insert maintained in the compressed position by a stirrup enclosing the two plates.

[Fig. 16] is a perspective view showing the insulating insert maintained in the compressed position by a link enclosing the two plates.

[Fig. 17] is a perspective view showing the stack of a plurality of insulating inserts according to the invention.

According to one of the configurations of the invention, the flexible and compressible insert of the invention, hereinafter referred to as an insulating insert (200) mainly consists of at least two fundamental elements, on the one hand, a so-called plate element. support (210) (211) (212) (213) (214) (216) (217) consisting of a smooth flat plate (216) or fitted (210) (211) (212) (213) (214) ( 217) of small thickness, of shape and dimensions adapted to penetrate effortlessly and by simple sliding inside a cell (110) of a standard hollow block hereinafter designated hollow block (100) and on the other hand a block of compressible insulating material called an insulating block (220) made, for example, of glass wool, rock wool, hemp wool, cellulose wadding, heat-reflective cellular insulation with high insulation coefficient or any other insulating material capable of '' be compressed to significantly reduce the volume. See figure 1.

According to the preferred configuration of the invention, the insulating insert (200) comprises three elements associated functionally with one another: a first element called the support plate (210) (211) (212) (213) (214) ( 216) (217) consisting of a smooth flat plate (216) or fitted (210) (211) (212) (213) (214) (217) of small thickness, of shape and dimensions adapted to penetrate effortlessly and by simple sliding inside a cell (110) of a hollow block (100), a second element called insulating block (220) made of compressible insulating material made for example of glass wool, rock wool, wool of hemp, cellulose wadding, cellular heat-reflective insulation with a high insulation coefficient or any other insulating material capable of being compressed to reduce its volume appreciably, and a third element called counter plate (230) consisting of a flat plate smooth of low thickness, shape and dimensions adapted to penetrate effortlessly and simply by sliding inside a cavity (110) of a hollow block (100). See Figures 2b, 3a, and 6.

According to this preferred configuration of the invention, the support plate (210) (211) (212) (213) (214) (216) (217) is secured by hot or cold bonding or any other means of definitive association with one of the faces of the insulating block (220) and the counter plate (230) is joined by hot or cold bonding or any other means of definitive association with the other opposite face of the insulating block (220 ), so that said insulating block (220) joined integrally by one of its faces to the support plate (210) (211) (212) (213) (214) (216) (217) and by the other of its faces against the plate (230) can compress and relax freely between said plates to reach its maximum volume. See Figures 3a, 3b, 5, 13, and 14).

In this preferred configuration of the invention, the support plate (216) of the insulating insert (200) preferably made of rigid and smooth cardboard, is permanently secured by one of its faces, to one of the faces d 'An insulating block (220) consisting in particular of glass wool of a thickness close to 7 to 7.5 centimeters, compressible material commonly used today in construction. The other face of said insulating block (220) is then associated with one of the faces of a counter plate (230) preferably of the same material, shape and dimensions as the support plate (216), in such a way that said insulating block (220 ) thus formed can compress and relax freely between said plates to reach its maximum volume. See Figures 2b, 3a, 6 and 13).

In this configuration of the invention, the external dimensions (width and height) of the support plate (210) (211) (212) (213) (214) (216) (217), of the insulating block (220 ) and of the counter plate (230) are close and determined so that once the insulating insert (200) is compressed and introduced inside a cell (110) of a hollow block (100) , the insulating block (220), sandwiched between the support plate (210) (211) (212) (213) (214) (216) (217), and the counter plate (230) can relax and fill the interior of said cell (110), without any of the three elements constituting the insulating insert (200) projecting from the upper plane (150) of the hollow block (100). See Figures 1, 2a, 2b).

According to a different configuration of the invention, the external dimensions (width and height) of the support plate (210) (211) (212) (213) (214) (216) (217), of the insulating block ( 220) and of the counter plate (230) are determined so that, once the insulating insert (200) is compressed and introduced inside a cell (110) of a hollow block (100), the insulating block (220) sandwiched between the support plate (210) (211) (212) (213) (214) (216) (217), and the counter plate (230) can relax and fill the interior of said cell (110) by allowing an excess part of insulation to protrude above the upper plane (150) of the hollow block (100) to optimize by compression the deployment of the insulating block (220) inside the cell (110) when stacking the hollow blocks (100) one on the other.

In another configuration of the invention, the support plate (210) (211) (212) (213) (214) (217), of the insulating insert (200) is arranged on its free face opposite to the insulating block (220), so that once placed opposite and in abutment on the internal face of a cell (110) of a hollow block (100), it reserves a free hollow space called free space (215 ) on the one hand between the internal face of said cell (110) of said hollow block (100) and its fitted face, thus constituting a volume of air sufficient to improve the insulation coefficient of the insulating insert. See Figures 3b, 7, 8, 9, 10, 11 and 12).

According to a mode of manufacture of this configuration of the invention, the support plate (211), has on its free face opposite the face integral with the insulating block (220), an arrangement consisting of the presence on all or part of its height and on the two longer sides of its main plane of two perpendicular edges raised called the support edge (250), so that once the support plate (211) placed facing and resting on the internal face of a cell (110) of a hollow block (100), it reserves by this arrangement a free space (215) between on the one hand the internal face of said cell (110) of said hollow block (100) and its fitted face, thus constituting a volume of air sufficient to improve the insulation coefficient of the insulating insert (200). See Figures 1, 2a, and 7.

According to another mode of manufacture of this configuration of the invention, the support plate (217) has on its free face opposite the face integral with the insulating block (220), an arrangement consisting of the presence on all or part of its height and on the two longest sides of its main plane of two attached strips called support strip (280), of width and thickness determined so that once the support plate (217) placed opposite and resting on the internal face of a cell (110) of a hollow block (100), this reserves a free space (215) between on the one hand the internal face of said cell (110) of said hollow block (100) and its fitted face thus constituting a volume of air sufficient to improve the insulation coefficient of the insulating insert (200). See figure 12).

According to a different mode of manufacture of this configuration of the invention, the support plate (210) has on its free face opposite the face integral with the insulating block (220), an arrangement consisting of the presence on everything or part of its height and preferably near the longest sides of its main plane of two folds called support ply (240), so that once placed facing and resting on the internal face of a cell (110) of a hollow concrete block (100), it reserves a free space (215) between on the one hand the internal face of said cell (110) of said hollow concrete block (100) and its arranged face thus constituting a volume of sufficient air to improve the insulation coefficient of the insulating insert (200). See the figure. 10).

According to another mode of manufacture of this configuration of the invention, the support plate (212) has on its free face opposite the face integral with the insulating block (220), an arrangement consisting of a free volume and closed said support volume (285) constituted by a main plane (212a) parallel and opposite to the support plate (212) preferably of identical surface and connected to the latter by means of two opposite lateral planes (212b) parallel, such so that once placed facing and resting on the internal face of a cell (110) of a hollow concrete block (100), it reserves a free space (215) but in a determined space limited between on the one hand the main plane (212a), the support plate (212) and the lateral planes (212b), thus constituting a volume of air sufficient to improve the insulation coefficient of the insulating insert (200). See figure 8.

According to a different manufacturing mode from this configuration of the invention, the insulating block (220) is retained inside a compressible space called compressible space (290) limited at the periphery by the support plate (213) and the counter plate (230) joined by their upper edge and their lower edge by means of two so-called foldable planes (260), the support plate (213) itself carrying on its free surface an arrangement consisting of a free volume and closed at the periphery said support space (295) constituted by a main plane (213a) parallel and opposite to said support plate (213) preferably of identical surface and connected to the latter by means of two planes called abutment plane (213b) parallel opposite, said abutment plane (213b), thus constituting with the support plate (213) and its opposite plane (213a), a volume of air sufficient to improve the insulation coefficient of the insulating insert (200). See figure 9.

According to another mode of manufacture of this configuration of the invention, the support plate (214) has on its free face opposite the face integral with the insulating block (220), an arrangement consisting of the presence preferably at proximity of each corner, of at least one boss said support boss (270) so that once placed opposite and resting on the internal face of a cell (110) of a hollow block (100 ), it reserves a free space (215) between on the one hand the internal face of said cell (110) of the hollow block (100) and its fitted face, thus constituting a sufficient volume of air to improve the insulation coefficient of the insulating insert (200). See figure 11.

According to a different manufacturing mode from this configuration of the invention, the insulating block (220) consists of a combined heat-reflective insulating honeycomb combining a succession of thin insulating plates (221) not exceeding the surface limits of the support plates (210) (211) (212) (213) (214) (217), and against the plate (230) of the insulating insert (200), for example of the extruded polystyrene or bubble film type isothermal, each thin insulating plate (221) forming a succession of folds and being joined together with another insulating plate (221) identical by the top of each ply, by gluing or welding an intermediate aluminum film (222).

Thus, the thin insulating plates (221) opposite to each other, constitute a succession of layers of cells (223) filled with air when the insulating block (220) relaxes inside a cell (110) of hollow block (100) and voids of air when the insulating block (220) is compressed between the support plate (210) (211) (212) (213) (214) (217) and the counter plate ( 230). See Figures 4, 5, 14.

In this manufacturing method, the insulating block (220) is kept in a compressed state to facilitate its storage and transport before use, by means of a link called insert link (224) easily broken after the introduction of the '' insulating insert (200) in a cell (110) of a hollow block (100), or of a stirrup (225) enclosing the insulating block (220) between the two plates secured to its end planes and easily removed after the introduction of the insulating insert (200) into a cell (110) of a hollow concrete block (100), or of a sachet called an insert sachet (not shown) easily removed after the introduction of the insert insulator (200) in a cell (110) of a hollow block (100), or any other means of compression for single use, easily and quickly extractable and disposable. See Figures 15, 16, and 17).

Claims (1)

Claims [Claim 1] Insulating insert for building concrete block, characterized in that it mainly consists of three elements associated functionally with one another: a first element called a support plate (210) (211) (212) (213) (214), (216 ) or (217) consisting of a smooth flat plate (216) or fitted (210) (211) (212) (213) (214) or (217), a second element called an insulating block (220) made of insulating material compressible made of glass wool, rock wool, hemp wool, cellulose wadding, cellular heat-reflective insulation with high insulation coefficient or any other insulating material capable of being compressed to significantly reduce its volume, and a third said element against plate (230) consisting of a flat and smooth plate of small thickness made of a rigid material, in particular cardboard, said insulating insert (200) being compressed and inserted inside a cell (110) of a hollow block (100). [Claim 2] Insulating insert for building concrete block according to claim 1, characterized in that the support plate (210) (211) (212) (213) (214) (216) or (217) is joined by hot or cold bonding or any other means of final association, to one of the faces of the insulating block (220) and the counter plate (230) is joined by hot or cold bonding or any other means of final association, to the other opposite face of the insulating block (220), such that said insulating block (220) joined integrally by one of its faces to the support plate (210) (211) (212) (213) (214) (216) or (217) and by the other of its faces against the plate (230), can relax freely between said plates to reach its maximum volume. [Claim 3] Insulating insert for concrete building block according to claims 1 and 2, characterized in that the external dimensions (width and height) of the support plate (210) (211) (212) (213) (214) (216) or ( 217) of the insulating block (220) and of the counter plate (230), are determined so that none of the three elements constituting the insulating insert (200) protrude from the upper plane (150) of a hollow block ( 100), when the insulating insert (200) is introduced into a cell (110) of said hollow block (100). [Claim 4] Insulating insert for building concrete block according to claims 1 and 2, characterized in that the external dimensions (width and height) of the support plate (210) (211) (212) (213) (214) (216) or ( 217), from insulating block (220) and against the plate (230), are determined so as to allow a surplus part of the insulating material to protrude above the upper plane (150) of a hollow block (100) in order to optimize the development by compression insulating insert (200) inside the cell (110) when stacking the hollow blocks (100) one on the other. [Claim 5] Insulating insert for a concrete building block according to any one of the preceding claims, characterized in that the support plate (210) (211) (212) (213) (214) or (217) of the insulating insert (200) is arranged on its free face opposite the insulating block (220), so as to constitute a free space (215) between on the one hand the internal face of the cell (110) of a hollow block (100) and its face fitted, when the insulating insert (200) is introduced into a cell (110) of a hollow block (100). [Claim 6] Insulating insert for a concrete building block according to claim 5, characterized in that the arrangement of the free face of the support plate (210) consists of two folds (240) made over all or part of its height, the arrangement of the free face of the support plate (211) consists of two perpendicular edges (250) raised over all or part of its height, the arrangement of the free face of the support plate (212) consists of a free and closed volume constituted by a parallel and opposite main plane (212a) connected to the latter by means of two opposite parallel lateral planes (212b), the arrangement of the free face of the support plate (213) consists on the one hand in a free and closed volume at the periphery said support space (295) opposite to a compressible space (290) limited at the periphery retaining the insulating block (220), the arrangement of the free face of the support plate (214) consists of at least one boss ( 270) near each corner and the arrangement of the free face of the support plate (2017) consists of two attached strips called support strip (280), each of the support plate (210) (211) (212) (213) (214) and (217) reserving a free space (215) between on the one hand the internal face of the cell (110) of a hollow block (100) and its fitted face. [Claim 7] Insulating insert for building concrete block according to claims 1 to 4, characterized in that the support plate (216) of the insulating insert (200), in particular made of rigid and smooth cardboard, is permanently joined by one of its faces , to one of the faces of an insulating block (220) made in particular of glass wool of similar thickness from 7 to 7.5 centimeters, compressible material commonly used today in construction, the other face of said insulating block (220) then being associated with one of the faces of a counter plate (230) of the same material, shape and dimensions as the "support plate" (216), so that said insulating insert (200) thus formed can compress and relax freely between said plates to reach its maximum volume. [Claim 8] Insulating insert for concrete building block according to any one of claims 1 to 6, characterized in that the insulating block (220) consists of a combined heat-reflective insulating honeycomb combining a succession of thin plates d insulation (221) not exceeding the surface limits of the support plates (210) (211) (212) (213) (214) (217) and against the plate (230) of the insulating insert (200), in particular of the extruded polystyrene or insulated bubble film type, each thin insulating plate (221) forming a succession of folds and being joined together with another insulating plate (221) identical by the top of each ply, by gluing or welding '' an intermediate aluminum film (222) to form a succession of cell layers (223) filled with air when the insulating block (220) relaxes and empty of air when the insulating block (220) is compressed between the support plate (210) (211) (212) (213) (214) or (217) and the counter plate (230). [Claim 9] Insulating insert for building concrete block according to claim 1, characterized in that the insulating block (220) is kept in compression to facilitate its storage and transport before use, by means of a link (224) easily broken after the insertion of the insulating insert (200) into a cell (110) of a hollow block (100) or of a stirrup (225) enclosing the insulating block (220) between the two plates secured to its planes d ends, easily removed after the introduction of the insulating insert (200) into a cell (110) of a hollow block (100), or of a sachet said sachet insert easily removed after the introduction of the insulating insert (200) in a cell (110) of a hollow block (100), or any other means of compression for single use, easily and quickly extractable and disposable.