FR3138456A1 - Building block comprising interface cells and at least one insulation cell filled with a wood fiber board - Google Patents

Abstract

A building block (B) comprising a concrete body (1) extending longitudinally along a first axis (X), laterally along a second axis (Y) and vertically along a third axis (Z), the concrete body ( 1) comprising a plurality of interface cells (2) extending vertically and which are through, the concrete body (1) comprising at least two rows (Ra, Rb) of interface cells (2) spaced apart laterally, each row comprising interface cells (2) aligned longitudinally, the concrete body (1) comprising at least one insulation cell (3), positioned laterally between said two rows (Ra, Rb), the cell insulation (3) being filled with a wood fiber board (4), the interface cells (2) being empty. Abstract Figure: Figure 2

Description

Building block comprising interface cells and at least one insulation cell filled with a wood fiber board

The present invention relates to the field of building blocks, in particular, those incorporating a thermal insulation element. Such building blocks are used in particular for the construction of homes with high energy performance.

In reference to the , an insulated building block 100 is known in the prior art comprising a concrete body 101 extending longitudinally along a first axis X, laterally along a second axis Y and vertically along a third axis Z. The concrete body 101 comprises a plurality of through cells 102 extending vertically. In particular, the concrete body 101 comprises two rows Ra, Rb of through-cells 102 spaced laterally, each row comprising through-cells 102 aligned longitudinally, in particular three cells per row.

In order to improve the thermal performance of such a building block 100, it is known to fill said through cells 102 with a thermal insulation material M1, for example, an expanded polystyrene insert or cement foam. Such a building block 100 has high thermal performance. To reduce the environmental impact of such a building block 100, it has been proposed to replace the thermal insulation material M1 with a “biosourced” insulation material, that is to say, derived from biomass. and having a reduced carbon footprint storing atmospheric carbon and participating in the preservation of natural resources.

Unlike a traditional M1 insulation material, a “bio-sourced” M2 insulation material is sensitive to water, which can lead to the appearance of fungi within the M1 insulation material. When these building blocks are used to construct housing walls, fungus is likely to appear in the housing, which presents a disadvantage to the durability of the wall formed with the building blocks.

An immediate solution is to add a fungicidal agent to the bio-sourced insulation material to reduce the appearance of fungi. In addition to its high price, such a fungicidal agent is not natural, which degrades the environmental performance of the building block.

In addition, a biosourced insulation material has a low pyrolysis temperature compared to a traditional insulation material such as an expanded polystyrene insert, which presents another disadvantage in the event of a fire.

The invention thus aims to eliminate at least some of these drawbacks.

PRESENTATION OF THE INVENTION

The invention relates to a building block comprising a concrete body extending longitudinally along a first axis, laterally along a second axis and vertically along a third axis, the concrete body comprising a plurality of interface cells extending vertically and which are through, the concrete body comprising at least two rows of laterally spaced interface cells, each row comprising interface cells aligned longitudinally, the concrete body comprising at least one insulation cell, positioned laterally between said two rows, the insulation cell being filled with a wood fiber panel, the interface cells being empty.

Thanks to the invention, it is advantageously proposed to use a wood fiber panel as a “biosourced” insulation material between two rows of interface cells which remain empty. Advantageously, the interface cells serve as a barrier against humidity and flames, which prevents the development of fungi and the combustion of the wood fiber panel. The interface cells protect the fiberboard on each side. We can thus form a facade of a building with a building block having high thermal and environmental performances. The wood fiber panel can thus fulfill its insulating function optimally, without risk of condensation in the facades of a building or propagation of fire through said facades.

Preferably, the wood fiber panel has a thermal conductivity of between 0.035 and 0.040W/m.K. Preferably, the insulation cell has a width of between 50mm and 100mm, preferably between 55mm and 65mm. Such parameters ensure efficient thermal insulation.

Preferably, the wood fiber panel is obtained by the dry process.

Preferably, the wood fiber panel has a density of between 105 and 115 kg/m3. Such a density makes it possible to increase the rigidity of the wood fiber panel to promote its insertion into the insulation cell in an industrial manner.

Preferably, the building block has a thermal resistance greater than or equal to 1m2.K/W.

Preferably, the insulation cell is spaced from the interface cells by a lateral distance of between 15 and 23mm. This helps provide effective protection against water condensation and the spread of fire.

Preferably, the interface cells have a lateral thickness of between 5mm and 40mm in order to form an efficient barrier.

Preferably, the cumulative length of the interface cells of a row is greater than 80% of the length of the concrete body. Preferably, the cumulative length is less than 90%, which contributes to the holding of the building block. Thus, protection is ensured over the entire length.

Preferably, the length of the insulation cell is greater than 80% of the length of the concrete body, preferably greater than 90%. Thus, thermal insulation is ensured over the entire length.

According to one aspect of the invention, the concrete body having slots at its longitudinal ends, the wood fiber panel has tongues mounted in the slots at its longitudinal ends. This advantageously makes it possible to avoid the formation of thermal bridges when several building blocks are associated longitudinally.

PRESENTATION OF FIGURES

The invention will be better understood on reading the description which follows, given by way of example, and referring to the following figures, given by way of non-limiting examples, in which identical references are given to similar objects .

There is a schematic representation of a building block with six cells according to the prior art.

There is a schematic representation of a building block according to a first embodiment of the invention.

There is a schematic representation of a building block according to a second embodiment of the invention.

It should be noted that the figures set out the invention in detail to implement the invention, said figures being able of course to be used to better define the invention if necessary.

DETAILED DESCRIPTION OF THE INVENTION

In reference to the , the invention relates to a building block B comprising a concrete body 1 extending longitudinally along a first axis , a lower horizontal face and four vertical faces. Preferably, the concrete body 1 has a length of between 490mm and 600mm, a width of between 180mm and 300mm and a height of between 150mm and 300mm. In this embodiment, the concrete body 1 has a length of 495mm, a width of 200mm and a height of 252mm.

Preferably, the concrete body 1 can be made from different types of concrete, in particular, with common aggregates or lightweight aggregates known to those skilled in the art.

The concrete body 1 comprises a plurality of interface cells 2 which pass through and which extend vertically. By crossing, we mean that the interface cell 2 opens onto the upper horizontal face and the lower horizontal face. The concrete body 1 comprises at least two rows Ra, Rb of interface cells 2 spaced laterally along the second axis Y, each row Ra, Rb comprising interface cells 2 which are through and aligned longitudinally along the first axis X. In this example, with reference to the , the two rows Ra, Rb are spaced laterally according to a lateral distance L1 of between 10cm and 15cm. The interface cells 2 are empty of air, that is to say, free of thermal insulation material. In this embodiment, each interface cell 2 has a rectangular or oblong section.

In this embodiment, the concrete body 1 has only two rows Ra, Rb which are located at the lateral ends. Each row Ra, Rb has three interface cells 2. Preferably, each interface cell 2 has a width defined along the Y axis of between 5mm and 40mm, preferably between 20mm and 40mm, and a length defined along the X axis between 130mm and 150mm. As will be presented subsequently, the interface cells 2 occupy, cumulatively, at least 80% of the length of the concrete body 1. This makes it possible to form a high-performance barrier over the entire length of the building block B. Preferably, the cumulative length of the interface cells 2 is less than 90% of the length of the concrete body 1, which provides good mechanical strength of the concrete body 1.

The concrete body 1 comprises at least one insulation cell 3, which is through and positioned laterally between said two rows Ra, Rb. In this example, the concrete body 1 has a single insulation cell 3 but it could include several, in particular, two separated by a vertical wall. A single insulation cell 3 is nevertheless preferred because it improves thermal performance.

The insulation cell 3 has a width defined along the Y axis of between 50mm and 100mm, preferably between 55mm and 65mm, and a length defined along the X axis of between 400mm and 480mm, preferably between 450mm and 470mm . As will be presented subsequently, the interface cell 3 occupies at least 80% of the length of the concrete body 1, more preferably, at least 90%. This makes it possible to form an efficient thermal barrier over the entire length of the building block B. Preferably, the insulation cell 3 is spaced apart from the interface cells 2 by a lateral distance of between 15 and 23 mm in order to avoid the transmission of humidity and the transmission of flames.

The insulation cell 3 is filled with a “bio-sourced” wood fiber panel 4, that is to say, storing atmospheric carbon and participating in the preservation of natural resources. According to the invention, the wood fiber panel 4 is made more than 90% with resinous woods, in particular, by dry process. This advantageously reduces the risk of condensation and the appearance of fungus.

Preferably, the insulation material 4 has a thermal conductivity (W/mK) of between 0.035 and 0.040. Preferably, the wood fiber panel 4 has a density of between 105 and 115 kg/m ³ . Advantageously, the wood fiber panel 4 can thus be in the form of an insert which can be manipulated by hand or using a machine.

Preferably, the wood fiber board 4 does not need to be treated with a fungicidal agent. However, depending on the level of resistance to fungal development desired in humid conditions, the wood fiber panel 4 may include a fungicidal agent.

To install the thermal insulation material 4, it is moved along the Z axis from the upper horizontal face towards the lower horizontal face of the concrete body 1 in the insulation cell 3. Advantageously, we obtain a building block B whose thermal resistance is at least equal to 1m2.K /W and which stores atmospheric carbon to contribute to the preservation of natural resources. The building block B can be glued in a manner similar to a building block according to the prior art.

Advantageously, the presence of interface cells 2, on either side of the insulation cell 3 in which the wood fiber panel 4 is mounted, makes it possible to protect the wood fibers against humidity, which protects the wood fiber panel 4 against the development of fungi. The interface cells 2 also help protect the wood fibers against fire by limiting the spread of flames. Building block B thus complies with regulatory requirements on fire resistance and the propagation of fire through building facades. The building block B according to the invention offers improved thermal resistance and optimal mechanical strength while being simple to manufacture and implement.

According to another embodiment, with reference to the , the concrete body 1 has slots 1a, 1b at its longitudinal ends. In this example, the slots 1a, 1b extend vertically from the upper horizontal surface of the building block B. The wood fiber panel 4 has at its longitudinal ends tongues 4a, 4b mounted in the slots 1a, 1b. Such tongues 4a, 4b make it possible to ensure continuity of thermal insulation when several building blocks B are associated longitudinally with each other. Thermal bridges are thus reduced. Advantageously, the presence of tabs 4a, 4b also makes it possible to guide the insertion of the wood fiber panel 4 into the insulation cell 3.

Claims (11)

Building block (B) comprising a concrete body (1) extending longitudinally along a first axis (X), laterally along a second axis (Y) and vertically along a third axis (Z), the concrete body (1 ) comprising a plurality of interface cells (2) extending vertically and which are through, the concrete body (1) comprising at least two rows (Ra, Rb) of interface cells (2) spaced laterally , each row comprising interface cells (2) aligned longitudinally, the concrete body (1) comprising at least one insulation cell (3), positioned laterally between said two rows (Ra, Rb), the cell d the insulation (3) being filled with a wood fiber panel (4), the interface cells (2) being empty. Building block (B) according to claim 1, wherein the wood fiber board (4) has a thermal conductivity (W/m.K) of between 0.035 and 0.040. Building block (B) according to one of claims 1 to 2, in which the insulation cell (3) has a width of between 50mm and 100mm, preferably between 55mm and 65mm. Building block (B) according to one of claims 1 to 3, in which the wood fiber panel (4) is obtained by dry processing. Building block (B) according to one of claims 1 to 4, in which the wood fiber panel (4) has a density of between 105 and 115 kg/m ³ . Building block (B) according to one of claims 1 to 5, in which the building block (B) has a thermal resistance greater than or equal to 1m ² .K/W. Building block (B) according to one of claims 1 to 6, in which the insulation cell (3) is spaced from the interface cells (2) by a lateral distance of between 15 and 23mm. Building block (1) according to one of claims 1 to 7, in which the interface cells (2) have a lateral thickness of between 5mm and 40mm. Building block (1) according to one of claims 1 to 8, in which the cumulative length of the interface cells (2) of a row (Ra, Rb) is greater than 80% of the length of the concrete body (1). Building block (1) according to one of claims 1 to 9, in which the length of the insulation cell (3) is greater than 80% of the length of the concrete body (1), preferably greater at 90%. Building block (1) according to one of claims 1 to 10, in which the concrete body (1) has slots (1a, 1b) at its longitudinal ends, the wood fiber panel (4) has at its ends longitudinal ends of the tongues (4a, 4b) mounted in the slots (1a, 1b).