FR3001476A1 - 4- or h-shaped building insulation device for covering lower vertical part of building, has block whose side is easily encased with other blocks for ensuring mechanical continuity and continuity of insulation for building - Google Patents

Abstract

The device has parallelepipedic rectangle shaped isolating blocks e.g. superimposed or intersected panels, for ensuring mechanical continuity and continuity of insulation for the building. One of the blocks includes a surface adapted to decorative or utility coatings of the building. The block assures resistance to the impact or to the weight or moisture or to frost for the building. One of the blocks is provided with a machined side such that the side is easily encased with other blocks for ensuring mechanical continuity and continuity of insulation for the building.

Description

TECHNICAL FIELD OF THE INVENTION The expectations of the users of a building are multiple concerning thermal comfort: this building must be well insulated thermally in order to be sober in energy consumption. If possible, a substantial thermal mass must be preserved inside the building in order to avoid heat peaks in the summer inside the building, and to restore some of the energy accumulated during the winter heating period. . This is true for both new buildings and buildings to renovate. This invention is part of this approach: isolate a building while maintaining a thermal mass capable of reducing the peaks of temperature rise of the building in summer or peaks of cold in winter, for the greater comfort of its occupants. This approach can be combined with other work such as setting up a sidewalk, or building small hangars, porch or small storage areas along a building. The building may be a dwelling house, a building, a school, an office building, or any other type of building. 2 / State of the Prior Art For new buildings, two types of insulation solutions are generally recommended: either to isolate the building from the outside, by wrapping it completely with an insulating membrane, including the lower part of the building. (like the floor). But in summer, the thermal masses contained within this thermal envelope (that is to say the interior walls and the interior furniture) may not be sufficient to prevent, by their thermal inertia, the temperature to rise to the interior of the building following high heat, which can lead to install an air conditioning system that is energy-consuming and a source of expenditure. Thus, the solutions currently used for new buildings take into account the insulation component, but not the mass component and thermal inertia. For old buildings, one solution is to insulate the building from the inside, which has the disadvantage of always leaving thermal bridges between the outside and the inside of the building (for example, bridges passing from the outside wall). and from the outside ground to the foundations, then under the building and finally to the floors and to the interior of the building.Another solution for the old buildings is to insulate from the outside, but this one declines rarely at the level of the foundations, and they do not remake the insulation of the floor, which leaves a thermal bridge from the outside ground to the foundations and then under the building and the load-bearing walls, and finally to the floors and In this way, the current solutions for old buildings do not cover the insulation part perfectly, and some work is being done around a building to provide certain elements. Features: Build a peripheral sidewalk to walk around the building on dry foot, or to build some small premises such as shelters to store wood, to put a bike, to lay flower bins, build a porch or any other peripheral addition to the building. These works are generally not designed to contribute to building insulation; our system makes these two approaches compatible. 2 '/ Description of the figures Figure 1: structure of a building and associated thermal leaks The figure on the left is a section showing the main elements of the envelope of a building (Bt): its foundations (FD), its floor lower (PL), its peripheral walls (Mp), its roof (Tt). Also represented is the strip of land surrounding the building (SE: Exterior surface of the land, SSP: subsoil at the periphery of the building) which is a source of cold in winter and heat in summer (see below). The figure on the right represents, by arrows, the cold brought in winter by the atmosphere outside the building. These arrows go from the coldest to the hottest. The 20 arrows at the top of the building show the cold passing through the roof (Tt), the horizontal arrows show the cold passing through the outside wall of the house (Mp); this wall is itself a diffuser of cold. The other arrows that pass through the basement (SE) show the cold that comes from the atmosphere, and that passes by the land periphery of the building (SSP), then which passes under the building as well as by the foundations, and finally, which crosses the floor of the building (PL). These figures are symbolic, their purpose being to make understand the object of this invention. In summer, when the outdoor temperature is higher than the interior temperature of the building, the same arrows may symbolize heat transfer from the outside to the building interior. Figure 2: Building insulated from the outside without / and with our system The figure on the left shows a building whose roof was insulated, and whose peripheral walls were insulated from the outside. The arrows indicate the spread of cold when in winter and the outside temperature is lower than the indoor temperature of the building. It can be seen that the spread of cold has been stopped at the level of the roof and the peripheral walls. On the other hand, the cold always passes through the subsoil which is on the periphery of the building, then by the foundations and also below the foundations, then by the ground located under the floor, then through the floor in the building. The figure on the right shows how, by supplementing the outer insulation of the figure on the left with insulation using our system, we block the supply of cold passing through the subsoil at the periphery of the building; it also blocks the cold transmitted to the lower part of the wall, which weakens its transmission to the foundations Finally, there is very little cold spread in the ground under the building and then through the floor. The figure on the right shows that the floor beneath the building and in the immediate vicinity of the building is isolated from the outside by the system, but remains thermally in contact with the foundations and the floor. It thus forms a thermal mass (zone marked Mth) connected to the interior of the building, mass which will contribute to ensure thermal inertia, preventing large temperature fluctuations in summer as well as in winter inside the building. In summer, when the outdoor temperature is higher than the interior temperature of the building, the same arrows may symbolize heat transfer from the outside to the inside of the building. Figure 3: Building insulated from the outside without / and with our system The figure on the left shows a building whose roof was insulated, and whose peripheral walls were insulated from the inside. The arrows indicate that the spread of cold has been stopped at the level of the roof and the peripheral walls. On the other hand, the cold always passes by the subsoil which is on the periphery of the building, then by the foundations and also under the foundations, the external wall itself leads the cold towards the foundations, then this cold passes by the floor under the floor and then through the floor in the building. The figure on the right shows how, by supplementing the outer insulation of the figure on the left with insulation using our system, the cold supply passing through the subsoil at the periphery of the building is blocked. In the figure on the right, we see that the ground under the building and in the immediate periphery of the building is isolated from the outside by our system. It thus forms a thermal mass (zone marked Mth) which will contribute to ensuring thermal inertia, preventing large temperature fluctuations in summer as well as in winter. - 4 - In summer, when the outdoor temperature is higher than the interior temperature of the building, the same arrows may symbolize heat transfer from the outside to the inside of the building.

Figure 4: Example of realization of the elements of our system The figure shows an example of shapes and dimensions of the basic elements constituting the system. The element (A) is intended to be placed vertically and to cover the bottom of the outer wall of a building. The element (G) occupies the same vertical place, but at the corners of the convex or concave angles of the building. The element (B) is intended to be placed horizontally on the ground located on the periphery of the building. The element (J) occupies the same type of space, but at the concave or convex angles of the building. The element (C) is intended to be placed vertically inside the ground. The profiles named "A-B" and "B-C" allow elements (A) and (B), and elements (B) and (C) to fit into each other. Profiles "A-A", "B-B" and "C-C" allow two identical and adjoining elements to fit into each other. Their shape may be different, the important thing is that they ensure the maintenance of parts between them and they avoid creating thermal leaks between the various elements. The dimensions AL, AH and AE respectively represent the length, the height and the thickness of an element (A). The dimensions BL, BH and BE respectively represent the length, the height and the thickness of an element (B). The dimensions GL and GE respectively represent the length and the thickness of an element (G). The dimensions JL and JE respectively represent the length and the thickness of an element (J). These dimensions are given by way of example, and may vary depending on the type of building and the climate.

Figure 5: Example of the implementation of the home renovation system The first figure shows the implementation of the elements of the system as part of the renovation of a house. The elements (A), (B), (C), (G) and (J) are positioned around the house to be renovated.

The second figure shows how the system, whose primary purpose is thermal insulation, integrates with other expectations concerning renovation. It is compatible with the construction of an open shelter (Abo) or closed (Abf), with the establishment of a trottoit peripheral (Tro) or a terrace (Ter), it can be combined with the creation of flower boxes (Ba) or with the construction of a veranda (Ve). Pe represents a lawn. The invention consists of a modular structure formed on the one hand by 3 insulating elements (A), (B) and (C) surrounding the lower part. a building (see Figure 4), and two elements (G) and (J) on the other hand ensure respectively the continuity of the elements (A) and (B) at the corners of the building. This set of 5 elements has a shape of "4" or "h". The top elements (A) and (G) run along the wall vertically outside, and stop at ground level (or slightly lower down to the foundations) to isolate the lower part of the outer wall. Elements (B) and (J) are arranged horizontally to isolate the strip of land around the building; these elements must be able to withstand, depending on the purpose, a sidewalk, pebbles, earth, people, vehicles or any other covering and any other type of traffic. The element (C) is vertically arranged to complete the insulation. These elements (A), (B), (C), (G) and (J) are assembled together to provide continuity of insulation; the profiles disposed on the surfaces in contact with each other contribute to holding the assembled elements together. In the case of complete insulation from the outside, the element (A) is constituted by the existing external insulation which covers the whole wall; it does not have to be duplicated. The constitution of the insulation can vary according to the region, according to the severity of the climate, according to the humidity, or according to any other consideration. For example, the top of the portion (A), less exposed to moisture, may be made of rock wool, while the bottom of the portion (A) will, for example, consist of moisture-insensitive polyurethane . Part (A) can also have a more complex structure: in addition to an insulating part, it can integrate flower boxes, structures to store a bike or firewood or gas cylinders, it can also be marry with a shelter to hide garbage cans. Part (B) must be capable of supporting a weight that may be variable depending on the intended use (supporting a gravel coating or concrete liner, supporting the passage of pedestrians or vehicles, covering earth or sand or various pipelines), the part (C) which is buried must be impenetrable.

The shape of parts (A), (B) and (C) may vary. Typically, their section is rectangular, the small side of this rectangle corresponding to the thickness of the insulation. But the part (A) could also be less thick at the top, and thicker at the bottom. The areas of contact between parts (A) and (B), between parts (B) and (C), and between two parts of the same type (A) (A), (B) (B) or (C) (C) have a particular profile in order to be able to nest them together, and they can have a profile and cover allowing this assembly to remain insulating even if the building or the ground move slightly over time. - 6 - Their profile and assembly can be studied so that liquid such as rainwater flows from the ground side rather than the building side. The surfaces can be smooth or with a relief, if it makes it easier to accommodate a coating (for example, the part (B) can be structured to accommodate either pebbles, a small strip of land or a slab concrete, or any context-appropriate coating). This approach thermally isolates a mass of land around the building and the mass of land beneath the building. This has four advantages: the first advantage is, thanks to the thermal mass located under the building, to limit thermal fluctuations inside the building during heat peaks external to the building in summer, or during peaks of cold in winter ; the second advantage is the thermal insulation that it provides to the building, the third is that it allows to remove the rainwater from the foundations of the building, the fourth is that this solution is compatible with work seeking to develop the immediate vicinity of the building for other functionalities (building a sidewalk around the building, or seeking to build small annexes around the building such as wood or bicycle shelters, flower boxes, composters, peripheral ducts ). 5 / Detailed description of at least one embodiment of the invention (part structure, composition, operation) FIGS. (5) show one possible application among others of the system as part of the renovation of a poorly insulated house. Blocks (A), (B), (C), (G) and (J) are made of polyurethane. The upper figure shows the laying of the elements around the house, after digging the ground. The lower figure shows the renovated house after laying a sidewalk, a terrace, a shelter, flower boxes, a veranda. 6 / indication of the way in which the invention is susceptible of industrial application: Many houses or buildings will have to be renovated in the next 10 years in order to limit their loss of energy. The number of poorly insulated houses in France is of the order of millions. The device described by this patent makes it possible to achieve this isolation from the outside. This device is compatible with the realization of a "sidewalk" around the building. Elements such as vegetation bins may be affixed to blocks (A), or small spaces such as firewood shelters or shelters for bicycles or any other type of shelter.35 -7--. 7 / Additions: This device makes it possible to ensure a mechanical continuity and a continuity of insulation, and whose resistance to the weight or the humidity or the frost or the roots of the vegetation is adapted to the use, The blocks ( A) and (G) of this device, as described in Figure 4, have a variable size to cover the entire outer wall, if the insulation of this wall is non-existent, or they can be omitted if the wall is already insulated from the outside, Part (C) is omitted if the thermal simulations deem it unnecessary, Each of the parts of the device is cut or recessed to allow access to the devices they cover or protect, or in order to pass wires or pipes or any other device along these blocks (A) (B) (C) or through these blocks, the device described by this patent is associable with other devices on the periphery of the building such as small areas for storing wood or any other material, or s that bicycle garages, containers for growing flowers or plants, terraces, verandas, as explained in Figure 5. The device described by this patent is associated with other devices in the periphery of a building such as underground devices for the treatment or storage of rainwater, waste water or other waste produced in buildings. The panels A, B, C, J or G consist of a single panel or several superimposed or intersecting panels.

Claims (1)

CLAIMS1 / Building insulation device in the form of "4" or "h" continuously covering firstly the lower vertical part of the building with an insulating block (A) rectangular parallelepiped shape or similar shape and thanks to a block (G) used in the corners, as described in Figure 4, having machined edges so that they can fit easily with the other vertical blocks (A) or (G) and with the blocks (B) or (J) described below, thus ensuring a mechanical continuity and continuity of insulation, having a surface adapted to decorative or utilitarian provided coverings, and whose impact resistance or moisture or gel is adapted to the use, secondly the floor adjoining the building through an insulating block (B) of parallelepipedal shape rectangle or similar shape and thanks to a block (J) used in the corners, having machined edges so that they can nt fit easily with the other horizontal blocks (B) or (J), as well as with the blocks (A) and (G) previously described, as well as with the blocks (C) described below, thus ensuring a mechanical continuity and continuity of insulation, having a surface adapted to decorative or utilitarian provided coverings, and whose resistance to shocks or to the weight or moisture or to the gel is adapted to the use, thirdly a trench thanks to an insulating block (C) of rectangular parallelepiped or any other type of section adapted to this function, having machined edges so that it can fit easily with the other vertical blocks (C) or with the horizontal blocks (B) and (J) described above, thus ensuring mechanical continuity and continuity of insulation, and whose resistance to weight or humidity or to the frost or roots of the vegetation is adapted to the use, 2 / Device according to any of the claims characterized in that the blocks (A) and (G) have a variable size to cover the entire outer wall, if the insulation of this wall is non-existent, or they can be omitted if the wall is already isolated from the outside, 3 / Apparatus according to any one of the preceding claims, characterized in that the part (C) is omitted if the thermal simulations consider it unnecessary, 4 / Apparatus according to any preceding claim characterized in that each of the parts is cut or recessed to allow access to devices that they cover or protect, or to pass wires or pipes or any other device along these blocks (A) (B) (C) 5 / Device according to any one of the preceding claims, characterized in that it combines with other devices on the periphery of the building such as small areas 35 for storing wood or any other material. , or t such as bicycle garages, containers for growing flowers or plants, terraces, verandas.-9- 6 / Apparatus according to any preceding claim characterized in that it combines with other devices on the periphery of a building such as underground devices for the treatment or storage of rainwater, waste water or other waste produced in buildings. 7 / Apparatus according to any one of the preceding claims characterized in that each of the panels A, B, C, J or G consist of a single panel or of several superimposed or intersecting panels.