ITMI20120474A1 - MODULAR VENTILATION SYSTEM TO REDUCE HUMIDITY IN PARTS OF UNDERGROUND BUILDINGS, AND BUILDING PROVIDED WITH THIS VENTILATION SYSTEM - Google Patents

Description

MODULAR VENTILATION SYSTEM TO REDUCE HUMIDITY IN PARTS OF UNDERGROUND BUILDINGS, AND BUILDING EQUIPPED WITH

THIS VENTILATION SYSTEM

Field of the invention

[1] The present invention relates to a system and a method for reducing humidity from walls and other underground structures, such as for example foundation walls and underground garages.

State of the art

[2] In the past, systems have been conceived to reduce humidity in the underground walls of foundations or garages, trying to create air currents around the wall itself. The system of this type described in the document GB 1 057 642 comprises a set of prefabricated components which can be assembled in a modular manner so as to form a second wall interposed between the ground and the underground wall of the actual building. The second wall forms inside a plurality of internal ventilation ducts which, in the intentions of the creator, should be crossed by convective air flows in order to remove the humidity in the walls of the building.

[3] This modular system, however, has several drawbacks, among which the following.

The internally perforated blocks are made of concrete, and therefore their internal ventilation ducts have inevitably limited passage sections. Furthermore, the concrete of which the internally perforated blocks are made is porous so as to make them deliberately permeable to both air and water.

Document GB 1 057 642 also suggests assembling the second wall without mortar, so that it can be easily disassembled in case of need.

These three factors make the modular system of the GB 1 057 642 quite ineffective in eliminating moisture and on the other hand too expensive. Therefore, we do not know that it has spread and is currently being used.

[4] An object of the present invention is to obviate the drawbacks of the system for reducing the humidity in underground walls known from the document GB 1 057 642, with particular reference to the effectiveness in removing the humidity and to the production and installation costs.

Summary of the invention

[5] This object is achieved, in a first aspect of the present invention, with a having the characteristics according to claim 1.

In a second aspect of the invention, this object is achieved with a building having the characteristics of claim 12.

Further characteristics of the device are the subject of the dependent claims.

[6] The advantages achievable with the present invention will become more evident to the skilled in the art from the following detailed description of a particular non-limiting example of embodiment, illustrated with reference to the following schematic figures.

List of Figures

Figure 1 shows a perspective view of four panel elements, hooked together to each other of a modular ventilation system according to an embodiment of the invention;

Figure 2 shows a perspective view of a septum element of the modular ventilation system of Figure 1; Figures 3 and 4 show respectively a first and a second perspective view of an angular element of the modular ventilation system of Figure 1;

Figure 5 shows a sectional view, according to the vertical section plane VI-VI, of a portion of the foundations of a building covered by a part of the modular ventilation system of Figure 1;

Figure 6 shows a perspective view of the foundations and the ventilation system of Figure 5;

Figure 7 shows a sectional view, according to the horizontal section plane VII-VII, of the foundations and the ventilation system of Figure 5, with a septum element that helps to form a labyrinth ventilation path.

Detailed description

[7] Figures 1-7 relate to a modular ventilation system for reducing humidity in walls and other underground parts of buildings, according to a particular embodiment of the invention.

According to an aspect of the invention, the modular ventilation system, indicated with the overall reference 1, comprises a plurality of panel elements 3, each of which in turn comprises: - a panel portion 5 which forms a prepared containment wall to lean against the ground T that surrounds or in any case faces the underground part of the building) to be dehumidified;

-one or more spacer elements (7, 7 ') through which the panel portion) and / or the containment wall can rest against the wall, or other at least partially underground portion of the building (P) to be dehumidified.

As shown in Figure 1, each panel portion 5 can have the overall shape of a flat plate, preferably square or rectangular.

Advantageously, as shown in the attached Figures, the perimeter edges of each panel portion have shapes such that they can be mechanically connected, for example by hooking or interlocking, to the perimeter edges of another panel portion.

[8] As shown in Figure 1, each spacer element 7, 7 'can be formed or comprise for example of a cylindrical leg, which extends perpendicular to the surface where the panel portion 5 lies. More generally, the legs of the elements spacers 7, 7 'can have the shape of bars or beams extending perpendicularly, or in any case transversely to the surface where the panel portion 5 lies and / or to the wall of the building to be coated and dehumidified.

Preferably the legs are internally hollow, so as to simplify the production of the panel element 3 by injection molding, in particular by allowing an entire panel element 3 to be molded in plastic material with a mold without movable drawers; also this last expedient contributes to considerably reducing the production costs of the panel 3.

Preferably, as shown in Figures 1, 5, each leg 7, 7 'has a free end designed to rest against the wall P or other part of the building to be dehumidified.

The presence of these free ends simplifies the mechanical structure of the panel elements 3, makes it possible to facilitate the flow of ventilation air through the legs 7, 7 'and to reduce the production costs of the elements 3 themselves, both by reducing the quantity of necessary material is simplifying, for example, injection molding. Preferably these free ends are closed or in any case substantially impermeable to water and humidity.

Preferably, the legs 7, 7 'have circular, oval, elliptical or in any case rounded cross sections so as to reduce the load losses in the air flow that laps the legs. Alternatively, however, the cross sections of the legs can be in the shape of a regular polygon, convex polygon, square, rectangle, rhombus, T or H-shaped.

Preferably, the modular system 1 further comprises one or more partition elements 9 and / or one or more corner elements 11.

[9] Each partition element 9 can comprise a preferably oblong flat panel or wall, for example rectangular (Figure 2). Preferably, one of the longitudinal edges 90 of the element 9 is shaped such that it can be mechanically fixed, for example by hooking or interlocking, to the perimeter edges of a panel portion 3 (Figures 5, 7).

Advantageously, along the other longitudinal edge 92 of the element 9 there is a sealing gasket 94 whose function will be described later (Figures 2, 7). As in Figures 2, 7, the gasket 94 can have a substantially tubular shape.

The overall shape of each corner element 11 is preferably oblong, and its longitudinal edges 110, 112 have a shape that can be mechanically fixed, for example by hooking or interlocking, to the perimeter edges of a panel portion 3 (Figures 3, 4).

[10] For this purpose the longitudinal edges 110, 112 of the corner element 11, as well as one of the longitudinal edges 90 of the element 9, can form longitudinal folds having substantially constant U or S cross sections (Figures 2-5, 7).

The corner elements 11 can optionally be strengthened by suitable longitudinal ribs 114 and transverse 116.

As exemplified in Figure 4, advantageously on the internal side of each corner element il there is a suitable seat designed to receive and rest against the edge of the wall MA, or other masonry element to be covered. Preferably, as in Figure 4, this seat is substantially the negative cast of the corner of the wall MA.

Each panel element 3 has a width Li preferably between 6-12 dm, more preferably between 7-10 dm and even more preferably between 8-9 dm.

The length L2 of each panel element 3 is preferably between 7-20 dm, more preferably between 9-16 dm and even more preferably between 12-13 dm.

These dimensions Li, L2 make the panels smaller and more manageable, allowing to significantly reduce the costs of the molds without compromising the performance of the panels themselves. The particular choice of the length L2, in particular if between 12-13 dm, allows to reduce to a minimum the waste obtained by trimming the part of the panels which, once installed, exceeds the desired height.

Preferably at least part of the legs, or other spacer elements 7, protrudes from the containment wall of the panel portion 5 for a height HG equal to or greater than 1 dm, more preferably equal to or greater than 2 dm and, even more preferably, equal to or greater than 3 dm. These heights allow for good thermal insulation and sufficient ventilation between the ground and the building wall. The diameter or the maximum width or length of the cross sections of each leg or other spacer element 7, is preferably comprised between one fifth and one quarter of the height HG of the relative leg or other spacer element 7.

[il] The lengths L3 and L4 respectively of the septum elements 9 and of the corner elements il are preferably equal to the lengths L2 of the panel elements 3. The width L5 of the septum elements 9 preferably varies between one third and one eighth of the length L3 of the septum elements, and more preferably it is equal to about one sixth of the length L3.

The legs or more generally the spacer elements 7, Ί 'have such dimensions that the ratio between A) the overall volume that can be occupied by the air flowing through a panel element 3, and B) the volume obtained by multiplying the surface of a panel portion 5 for the height HG of the spacer elements 7, 7 'is sufficiently close to 1, for example preferably between 0.6 and 1, more preferably between 0.7 and 1 and, even more preferably, between 0.8 and 1.

The volume obtained by multiplying the surface of a panel portion 5 by the height HG of the spacer elements 7, 7 'gives an indication of the overall external dimensions of a panel element 3.

[12] Advantageously, the various panel elements 3, the partition elements 9, the corner elements 11 are made of materials which are substantially impermeable to water, such as for example polyethylene, polypropylene or other non-expanded and substantially non-perforated plastic materials. Advantageously, these plastic materials are chosen so as to give the panel sufficient flexibility so as to adapt to any irregularities and geometric imperfections of the walls to which they are applied.

[13] An example of assembly and operation of the modular ventilation system 1 described above is now described.

Several panel elements 3 are inserted vertically in a suitable empty space excavated between the underground portion of the building P that is to be kept drier and the ground T that surrounds it or in any case faces it (Figures 5, 6). The underground portion of the building P can be for example the foundation wall of the building, the wall of a cellar, warehouse, garage or other basement room. The panel portions 5 are rested against, or in any case facing towards, the ground T while the legs or other spacer elements 7, 7 'are rested against the wall or other portion of the building P. The panel elements 3 thus form a support and a containment barrier against the ground, ensuring the presence of an empty cavity 15 - or in any case occupied at least mainly by air - between the outermost walls of the building P and the ground. This interspace 15 is closed at the bottom and at the top by an appropriate number of septum elements 9 so as to form an air box which sufficiently contains the leaks. The various panel elements 3 are interconnected by hooking together the respective longitudinal and / or transverse perimeter edges.

Possibly the element or the partition elements 9 'which close the empty interspace 15 at the top are protected and covered by a layer of earth, a concrete slab or other structural element capable of supporting the required loads.

Advantageously, as shown in Figures 6, 7, one or more septum elements 9 are mounted so as to extend inside the interspace 15 inside the spacer elements 7, 7 'so as to suitably guide the air flow in the cavity. In the example of Figure 6, a plurality of septum elements 9 are arranged so as to form a substantially serpentine path followed by most of the air flowing into the interspace 15.

The sealing gaskets 94 of the various septum elements 9, 9 ', if present, improve the tightness and efficiency of the system by resting against the wall P -or the walls P. The section of Figure 7 shows a particularly advantageous example of interlocking the edge U-folded of a septum element 9 with the folded edges of two adjacent panel elements 3: the interlocking edge 90 is interposed between the folded edges of the panel elements 3. The edges, in particular the right-angled edges of the various edges advantageously allow to constrain not only (at least) some translations, but also the rotation of the partition element 9 with respect to the adjacent panel elements with which it is fitted.

Any corners and dihedrals of the underground part of the building P can be covered with one or more corner elements 11 hooked, or otherwise mechanically connected, to an appropriate number of panel elements 3.

Preferably the ventilation system 1 'is provided with one or more air inlets 17, and with one or more air delivery openings 19.

As shown in Figure 6, the air inlets 17 and the delivery outlets 19 can be respectively the inlet and outlet of suitable tubular ducts 21, 23, respectively.

Advantageously, the air intake or intakes 17, and the delivery mouth or mouths 19 are located in such positions as to favor the formation of air flows by natural convection through the interspace 15.

For this purpose, again as shown in Figure 6, the delivery mouth or mouths 19 can be located at a significantly higher height than the air intake or air intakes 17, for example at least 0.2 meters, and more preferably at least 0.4 meters above the air inlets 17.

Alternatively, the delivery mouth or outlets 19 can be located on a side or facade of the building, different from the side or facade in which the one or more air intakes 17 are located, by positioning for example a delivery outlet 19 on a facade. of the building facing south and an air vent 17 on a facade facing north.

An example of possible operation of the ventilation system 1 'of Figures 5-7 is the following.

In Figure 6 the dotted and dashed arrows indicate the path of the air in the coil of the ventilated cavity.

Due to the different temperature of the external air near the delivery mouth 19 and the air intake 17, the air from the external environment is sucked into the latter by natural convection, reaching the interspace 15 between the wall P of the building and the panel portions 5 of the various elements 3 that cover it. After passing through the coil formed by the septum elements 9, the ventilation air escapes from the delivery port 19. Crossing the underground cavity, the convective air stream very effectively removes the humidity present in the ground T or in the building P by expelling it into the external environment.

[14] The various elements 5, 7, 7 'of the modular ventilation system 1 described above are particularly suitable for being made of plastic material, for example by injection molding, with relatively low wall thicknesses, for example varying between 4- 8 mm and more preferably around 5 mm, and therefore with equally low production costs.

[15] The various elements 3, 9, 11, 13 of the modular ventilation system 1 can have a very simple mechanical construction, and therefore be made of plastic material at very low costs.

[16] The panel elements 3 are suitable for being made with a very high ratio between A) the overall volume that can be occupied by the air in transit within the portion of cavity 15 inside a panel element 3, and B) the volume of the overall dimensions of the same panel element 3, considerably reducing the pressure drops of the air flowing between the legs 7 of the panel element and thus considerably increasing the draft and the dehumidifying capacity of the ventilation system 1 .

[17] The fact that at least the panel elements 3 are made of materials which are substantially impermeable to water, the elements 3 constitute a mechanical barrier against the infiltration of water from the ground. More specifically, the water from the ground stops against the walls of the panel elements 3 and runs downwards along them, penetrating only a small part through the joints, not necessarily watertight, between the edges of the various panel elements 3. The water and water vapor which nevertheless manages to penetrate inside the empty interspace between the building P and the panel portions 5 of the various elements 3 is evacuated into the external environment by the convective air flows previously described .

[18] By creating relatively low turbulence, the circular, or in any case rounded and chamfered, cross sections of the legs 7, 7 'or of the other spacer elements 7, 7' help to reduce the pressure drops of the air flowing through the empty cavity 15. The interlocking edges previously described allow the ventilation system 1 to be quickly mounted, firmly fixing the various panel elements 3 together.

In conclusion, thanks to the previous teachings it is possible to realize a modular ventilation system according to the invention which is a good compromise between operating efficiency and production and installation costs.

[19] The embodiments described above are susceptible to various modifications and variations without departing from the scope of protection of the present invention. For example, in embodiments not shown, the panel portions can form shell portions as a whole, even if they are not flat. The lower panel portions 5 can rest not only on partition elements 9 arranged horizontally, but also for example on bare ground.

Furthermore, all the details can be replaced by technically equivalent elements. For example, the materials used, as well as the dimensions, may be any according to the technical requirements. The examples and lists of possible variants of this application are intended as non-exhaustive lists.

Claims (15)

CLAIMS 1) Modular ventilation system (1) to reduce humidity in underground walls or other underground parts of buildings (P), where the system (1) includes at least one panel element (3) which in turn includes: - a panel portion (5) which forms a containment wall designed to rest against the ground (T) which surrounds or in any case faces the underground part of the building (P) to be dehumidified; -one or more spacer elements (7, 7 ') through which the panel portion (5) and / or the containment wall can be leaned against the wall, or other at least partially underground portion of the building (P) to be dehumidified . 2) System according to claim 1, wherein the containment wall is substantially flat. 3) System according to claim 1, wherein each spacer element (7, 7 ') comprises a leg which extends perpendicularly, or in any case not parallel, to the plane or other surface in which the containment wall lies. 4) System according to claim 1, where at least part of the spacer elements (7, 7 ') protrudes from the containment wall of the panel portion for a height (HG) equal to or greater than 1 dm. 5) System according to claim 1 or 3, where at least part of the spacer elements (7, 7 ') and / or of their legs have cross sections with a shape chosen from the following: circular, oval, elliptical, regular polygon, polygon convex, square, rectangular, rhomboid, T-shaped, H-shaped. 6) System according to claim 1, where at least part of the spacer elements (7, 7 ') each have a shape chosen from the following: cylindrical, conical, frustoconical, pyramidal, truncated pyramid, prismatic, the shape of a beam, the shape of a substantially oblong solid of revolution. 7) System according to claim 1, wherein the panel portion (5) has a substantially rectangular or square perimeter. 8) System according to claim 4, where the spacer element or spacer elements (7, Ί ') have dimensions such that the ratio between: A) the overall volume that can be occupied by the air flowing through a panel element (3); And B) the volume obtained by multiplying the surface of a panel portion 5 by the height (HG) of the spacer elements (7, 7 '); is between 0.6 and 1. 9) System according to claim 1, where each panel element (3) is provided with a plurality of spacer elements (7, 7 ') aligned along at least two orthogonal or transverse directions, for example arranged according to a square mesh grid , rectangular, rhomboid, triangular or quincunx. 10) System according to claim 1, where at least one panel element (3) is provided with perimeter edges designed to be fixed by hooking or interlocking with the perimeter edges of other similar panel elements (3), and the cross sections of the perimeter edges of the at least one panel element (3) are bent substantially in an S or U shape. 11) System according to claim 1, wherein the cross sections of the perimeter edges of the at least one panel element (3) form substantially right-angled folds. 12) Building at least partially underground, comprising a modular ventilation system (1) according to claim 1, where: -the containment wall of the at least one panel element (3) rests against the ground (T) that surrounds or in any case faces the part of the underground building (P) to be dehumidified; - the plurality of spacer elements (7, 7 ') rests against the portion of the building (P) at least partially underground, to be dehumidified; -1 'at least one panel element (3) forms and contributes to maintaining a cavity (15) occupied at least mainly by air between the ground (T) and the underground part of the building (P) to be dehumidified. 13) Building according to claim 12, where the one or more panel elements (3) combine to form a serpentine duct inside the modular ventilation system, where air can flow through the at least one serpentine duct in order to ventilate the underground part of the building (P) to be dehumidified. 14) Building according to claim 12, where the modular ventilation system (1) is provided with: - at least one air intake (17) designed to allow or facilitate the flow of air from the external environment into the interspace (15 ); And at least one delivery mouth (19) designed to allow or facilitate the outflow of air from the interspace to the external environment; where the at least one air intake (17) and the at least one delivery mouth (19) are positioned so as to produce or facilitate, at least mainly by natural convection, an air flow through the interspace (15). 15. Building according to claim 14, where the at least one delivery mouth (19) is arranged at least 0.2 meters higher than the air intake (17).