IT201600074455A1 - STRUCTURE AND METHOD TO DEHUMIDIFY A WALL / CEILING OF A BUILDING - Google Patents

Description

"STRUCTURE AND METHOD FOR DEHUMIDIFYING A WALL / CEILING OF A BUILDING"

The present invention relates to a structure and a method for dehumidifying a wall and / or a ceiling of a building; to which the following discussion will explicitly refer without losing generality.

As is known, the layers of plaster that cover the masonry walls of buildings are often subject to an accumulation of water / humidity inside. In particular, humidity can creep into the walls due to a capillary rise due to the absorption of water from the ground and / or in the presence of hygroscopic salts in the plaster, which, as is known, tend to absorb the water contained in the ambient air. .

However, during crystallization, the hygroscopic salts present inside the plaster layer increase their volume up to sixteen times compared to the initial condition. This expansion generates a pressure of the crystallized salts towards the material that surrounds them of about 600-800 atmospheres, causing localized de-cohesion in the plaster layer that determine their detachment from the wall.

For this purpose, various methods have been devised to drain / reclaim the moisture from the wall. For example, a very common method involves making holes in the wall, arranging externally storage tanks for chemical resins equipped with supply ducts and inserting the ducts into the holes to feed the chemical resin into the holes themselves.

This method has a series of technical drawbacks such as, for example, complexity of execution, high costs, particularly long execution times, and the release of unpleasant odors from the chemical resins.

The Applicant has therefore carried out an in-depth study with the aim of identifying a solution relating to a method and a structure for dehumidifying a wall or a ceiling of a building which is simple, inexpensive, and eliminates the emanation of unpleasant odors.

The object of the present invention is therefore to provide a solution which allows to achieve the above indicated objective.

The object of the present invention is therefore to provide a structure for drying (weight) humidity, ie dehumidifying, a wall or a ceiling of a building.

This object is achieved by the present invention as it relates to a method for dehumidifying a masonry wall / ceiling of a building comprising the steps of: making one or more holes in said wall / ceiling extending along respective longitudinal axes, of inserting inside at least one hole at least a first tubular spring structured in such a way as to convey the ambient air towards the internal wall of the hole so as to dehumidify it.

Preferably, the method comprises the step of telescopically engaging a second tubular spring inside said first tubular spring.

Preferably, the method comprises the step of extracting the second tubular spring from said first tubular spring when the second tubular spring reaches an operating condition in which the second spring is axially deformed by the hygroscopic salts accumulated inside it, and separating the hygroscopic salts from the second tubular spring.

Preferably, the second tubular spring has an external diameter which approximates by default the internal diameter of said first tubular spring and an axial length greater than or equal to the length of said first tubular spring.

Preferably, the first tubular spring is constituted by a helical wire spring.

Preferably, the second tubular spring is constituted by a helical wire spring.

The invention also relates to a structure for dehumidifying a masonry wall / ceiling of a building comprising one or more holes which are made in said wall / ceiling and extend along respective longitudinal axes; one or more first tubular springs which are inserted into said holes and are structured in such a way as to allow the ambient air to come into contact with the internal wall of said hole through the space present between the coils / links forming the springs themselves .

Preferably, the structure comprises a second tubular spring telescopically and axially engaged inside said first tubular spring.

Preferably, the second tubular spring is structured in such a way as to expand / deform axially along said axis with respect to said first spring between a rest condition, and an operating condition in which it indicates an accumulation of hygroscopic salts inside it.

Preferably, the first tubular spring has an external diameter which approximates by default the internal diameter of said hole and an axial length greater than or approximately equal to the depth of said hole along the relative axis.

Preferably, the first tubular spring can have an external diameter comprised between 0.2 mm and 10 mm.

Preferably, the first tubular spring can have an external diameter comprised between 0.3 and 0.5 mm.

Preferably, the first tubular spring is structured in such a way as to deform axially on the basis of the quantity of hygroscopic salts accumulated inside it, between a rest condition, in which the first tubular spring is not subjected to deformation, and an operating condition, in wherein the first tubular spring is axially elongated and exhibits a deformation indicative of a condition of filling the hole by the crystallized hygroscopic salts.

The present invention will now be described with reference to the attached drawings, which illustrate a non-limiting example of embodiment in which:

Figure 1 is a schematic front view of a portion of a masonry wall provided with a structure for dehumidifying a wall made according to the dictates of the present invention;

Figure 2 is a section I-I of a portion of the wall shown in Figure 1, in which a device for dehumidifying the wall included in the structure shown in Figure 1 is visible;

Figures 3 to 8 are schematic views which represent as many operating steps of the method for dehumidifying a wall provided according to the dictates of the present invention;

Figure 9 is a schematic vertical sectional view of the dehumidifying structure according to an embodiment; while

Figure 10 is a schematic front view of a portion of a masonry wall provided with a structure for dehumidifying a wall, made according to a variant embodiment.

With reference to Figures 1 and 2, the number 1 indicates as a whole a system that is a dehumidifying structure designed to drain the humidity (weight) and the hygroscopic salts present in a masonry wall 2 (shown only partially and in a schematic) of a building. It is understood that the term "wall" 2 means both a vertical wall and a horizontal wall, for example a ceiling.

The wall 2 (or the ceiling) can comprise at least one layer of plaster 3 fixed to a load-bearing structure 4. In the non-limiting example shown in Figure 2, the wall 2 generally comprises a central load-bearing structure 4, covered externally by opposite bands from two layers of plaster 3. The supporting structure 4 of wall 2 is known and will not be further described except to specify that it can generally be formed by bricks, and / or concrete and / or stones and / or terracotta and / or wood or similar materials, while the coating layer 3 can comprise a solid mixture based on lime and calcium carbonate or similar materials.

With reference to a preferred embodiment shown in Figure 1, the system or the dehumidifying structure 1 comprises a plurality of dehumidifying members 5, which are engaged in respective holes 6, which are in turn obtained on the wall 2 and extend along a longitudinal axis A.

The dehumidifying members 5 comprise tubular springs 7 having an external diameter which approximates by default the internal diameter of the hole 6 and an axial length greater than or equal to the depth of the hole 6 along the relative axis A. The hole 6 can be a blind hole or a through hole and sized in such a way as to pass through at least one layer of plaster 3 and / or the load-bearing structure 4.

According to a preferred embodiment, each tubular spring 7 adapted to be engaged in a hole 6 and consists exclusively of a helical wire spring provided with a plurality of coils / links which rest on the inner wall of the hole 6. Preferably, the adjacent coils / links of the wire helical spring can be conveniently spaced apart along the longitudinal axis of the tubular spring 7 in such a way as to allow the ambient air flowing inside the spring 7 to come into contact with the internal wall hole 6.

The Applicant has found that the tubular spring 7, thanks to its structure with preferably open coils, i.e. spaced apart from each other, puts the internal wall of the hole 6 in communication with the air flowing from the external environment to the wall 2, conveniently determining a localized dehumidification of the layer of plaster 3 surrounding the hole 6.

The Applicant has therefore found that by making a plurality of holes 6 at least on the plaster layer 3 and inserting the tubular springs 7 therein, aeration and drainage ducts are obtained which favor the expulsion of the humidity contained in the plaster layer 3 towards the 'external.

During the expulsion, the humidity conveniently drags the hygroscopic salts outwards. The humidity that flows from the wall 2, preferably from the plaster layer 3, is deposited in the tubular spring 7 and tends to dry thanks to the contact with the air passing through the spring 7 and at the same time the salts crystallize, increasing their volume. In this condition, unlike the plaster layer 3 which is rigid and tends to de-cohesion during the formation of crystallized salts, the tubular spring 7 deforms / stretches axially in a controlled manner under the pressure due to the expansion of the salts, causing the same of the axial micro displacements in the hole 6 which tends to push them progressively towards the outside of the hole 6 itself. Furthermore, during the deformation of the tubular spring 7 its coils / links are further distanced from each other, thus increasing the contact area between the salt expelled and recovered / contained in the spring 7 and the wall of the hole 6 thus determining part of the salt a progressively increasing increase in the absorption of water from the plaster layer surrounding the hole 6 itself.

The tubular spring 7 can preferably have a circular cross-section to the axis A and be made of metallic material, such as for example steel (stainless steel) or titanium, aluminum or copper or any similar metal alloy. It is understood that the tubular spring 7 could be made of carbon fiber or plastic material and / or based on mixtures of epoxy and / or polyurethane resins. The tubular spring 7 can also be dimensioned according to the depth of the hole 6. Preferably, the tubular spring 7 can have an axial length along the axis A which approximates excessively the depth of the hole 6 along the same axis.

The method therefore provides for making one or more blind or through holes 6 on the wall 2 in such a way as to pass through at least the layer of plaster 3 and / or the supporting structure 4, and to engage the helical tubular spring 7 flush in the relative hole 6 , and to extract the tubular spring 7 from the hole 6 when the tubular spring 7 has accumulated inside it a certain quantity of crystallized hygroscopic salts.

The Applicant has found that during the extraction of the tubular springs 7 from the hole 6, accidental rubbing of the inner wall of the hole 6 and damage to the same can occur in some cases.

In order to eliminate the rubbing condition of the internal wall of the hole 6, each dehumidifier member 5 can comprise an additional internal tubular spring 8 telescopically coupled inside the tubular spring 7 in such a way as to be able to slide along the axis A. Internal tubular springs 8 can be dimensioned in such a way as to have an external diameter which approximates by default the internal diameter of the tubular springs 7 so as to be able to be engaged / fitted in a stable but easily removable manner in the tubular springs 7 themselves.

Preferably, each tubular spring 8 is constituted by a helical wire spring with links / coils preferably spaced apart, which is telescopically engaged in the helical wire spring forming the tubular spring 7.

Preferably, each tubular spring 8 is structured in such a way as to deform elastically on the basis of the quantity of hygroscopic salts accumulated inside it, between a rest condition (shown in Figure 3) in which the tubular spring 8 is not subjected to deformation and the links / coils are mutually spaced by a first predetermined distance, and an operating condition (shown in Figure 6), in which the tubular spring 8 is elongated along the axis A, i.e. the links / coils are spaced apart by a second distance greater than first distance, and shows a deformation indicative of a condition of filling of the spring 8 / hole 6 by the crystallized hygroscopic salts. The method also provides for the step of axially extracting / removing the tubular spring 8 from the tubular spring 7, cleaning the tubular spring 8 from the hygroscopic salts accumulated inside it (Figures 7 and 8), and re-engaging the tubular spring 8 inside of the tubular spring 7 after cleaning, to carry out a new accumulation of the expelled hygroscopic salts. It should be pointed out that the tubular spring 8 conveniently performs the function of collector / container / storage tank of the hygroscopic salts drained from the wall which allows a continuous cleaning of the salts that accumulate in the hole 6 carried by the expelled humidity of the wall 2.

According to a preferred exemplary embodiment, the tubular spring 7 can conveniently have an external diameter comprised between 0.2 mm and 10 mm, preferably between 0.3 and 0.5 mm. The Applicant has found that the use of a tubular spring 7 with a diameter between 0.3 and 0.5 mm is particularly convenient for the dehumidification of some types of walls, such as for example walls provided with superimposed / stratified frescoes, in which it is necessary to contain the impact caused by the holes. It is understood that the internal diameter of the hole 6 approximates in excess of the diameter of the spring 7.

The tubular spring 8 can preferably have a circular cross-section to the axis A and be made of metallic material, such as for example steel (stainless steel) or titanium, aluminum or copper or any similar metal alloy. It is understood that the tubular spring 8 could be made of carbon fiber or plastic material and / or based on mixtures of epoxy and / or polyurethane resins. The tubular spring 8 can also be sized according to the depth of the hole 6. Preferably, the tubular spring 8 can have a length along the axis A which approximates in excess of the length of the tubular spring 7.

According to this embodiment, the method therefore provides for making the holes 6 on the wall 2, engaging the tubular springs 7 in the holes 6, and engaging the tubular springs 8 in the tubular springs 7. With reference to Figure 3, the ambient air flows into the duct inside the tubular spring 8 and comes into contact with the internal wall of the hole 6 through the openings between the spaced loops / coils of the springs 7 and 8. The heat exchange caused by the air in the hole 6 with the internal wall of the same causes the expulsion of the humidity from the layer of plaster 3 surrounding the hole 6. The expelled humidity passes through the spaced meshes of the spring 7 and of the spring 8 so as to gradually deposit / accumulate in the spring 8 (Figure 4). The expelled humidity accumulated in the spring 8 contains hygroscopic salts which are progressively crystallized by the ambient air which continues to flow through the spring 8 itself. During crystallization, the salts expand their volume causing an axial deformation of the tubular spring 8 along the axis A. In particular, the crystallization of the salts spreads / expands the coils / meshes of the spring 8, conveniently causing an increase in the contact area between the air flowing in the hole 6 and the inner wall of the hole 6 itself.

According to a preferred embodiment in which it is provided to apply the dehumidifying structure 1 to a horizontal wall corresponding to a ceiling (not shown), a portion of the tubular springs 7, preferably a distal end present in the innermost part of the hole 6, can be made integral with the wall 2 through a fixing / gluing material. Preferably, the fixing / gluing material can conveniently comprise a liquid mixture composed of one or more crystallizing resins, such as for example epoxy resins and / or polyurethane resins. The Applicant has found that by exclusively fixing an end portion of the tubular spring 7 to the inner wall of the hole 6 by injecting a certain amount of fixing / gluing material into the hole 6 itself, the remaining part of the tubular spring 7 is free to deform longitudinally thus favoring an increase in the contact area between the air / salt in the hole 6 itself and the internal wall of the latter.

The Applicant has also found that it is possible to amplify the dehumidifying action by the dehumidifying members 5 of the dehumidifying structure 1. With reference to the vertical schematic section of the wall 2 shown in Figure 9, the dehumidifying member 5 can comprise three holes communicating with each other. at the relative internal ends, in which a first hole corresponding for example to the hole 6 hosting the tubular springs 7 and 8 can have its axis A about horizontal, while a second hole 16 and a third hole 18 have their respective axes B and C inclined by an angle a and β respectively with respect to axis A in a vertical plane passing through axis A itself. Preferably, the second 16 and third hole 18 can be obtained on the wall 2 in such a way as to be arranged above and respectively below the hole 6 so as to lie on the same (vertical) plane of the hole 6 and have an angle a of approximately 45 ° and respectively an angle β of approximately 45 ° with respect to axis A. The Applicant has found that by making the two additional holes 16 and 18 an increase in ventilation in hole 6 is obtained (similar to a chimney effect) and consequently a greater dehumidification of the same. It is understood that according to a different embodiment the holes 6, 16 and 18 can be through rather than blind. It is also understood that an intermediate solution provides for the realization of two holes instead of three holes, in which a first hole corresponding to the hole 6 having the axis A horizontal while the second hole can correspond to the lower hole 16 having the axis B inclined.

Tests carried out by the Applicant have shown that a dehumidifying structure 1 made on a terracotta wall is extremely efficient in drying if the holes 6 are distributed on the wall at the intersection points of a lattice so that the holes 6 present along two vertical lines and adjacent horizontals are preferably offset from each other (Figure 1).

With reference to the example shown in Figure 1, the Applicant has found, through the tests carried out, that it is convenient to size the dehumidifying structure, in terms of the external diameter of the tubular spring 7 and the center distance Di present between the adjacent holes 6 belonging to two vertical lines of the grating, as a function of the thickness of the wall 2 so as to obtain the maximum degree of drying thereof. In particular, the Applicant has found that the dehumidifying structure 1 applied to a terracotta wall can be conveniently sized in such a way that if the thickness of the wall is about N * 10 cm, the center distance Di between the holes 6 is about N * 10 cm and the outer diameter of the spring 7 is approximately N / 2 mm. For example, if the thickness of the wall is about 10 cm, the center distance Di between the adjacent holes 6 is conveniently about 10 cm and the external diameter of the spring 7 is about 5 mm; if the thickness of the wall is about 20 cm, the distance between the holes Di is about 20 cm and the external diameter of the spring 7 is about 10 mm; if the thickness of the wall is about 30 cm, the distance between the holes Di is about 30 cm and the external diameter of the spring 7 is about 15 mm. The Applicant has also found that the dehumidifying structure 1 applied to an ancient ceiling made mainly of lime-based mortar supported by cellars, i.e. strips having an average thickness of 6 cm, can be dimensioned in such a way that if the thickness of the wall is about 3 cm, the center distance Di between the holes is about 10 cm and the external diameter of the spring 7 is about 3 mm; if the wall thickness is about 6 cm, the distance between the holes Di is about 20 cm and the external diameter of the spring 7 is about 5 mm; if the wall thickness is about 10 cm, the center distance Di between the holes is about 10 cm and the external diameter of the spring 7 is about 5 mm.

With reference to Figure 10, the Applicant has also found that if the dehumidifier structure 1 is applied to a wall subject to a "thermal bridge" it is possible to distribute a series of holes 6 along relative concentric circumferences whose center of symmetry is arranged in correspondence with the area of the wall 2 subjected to the greatest thermal flow. In this case the holes 6 can preferably be distributed on each circumference in such a way as to be radially aligned each with a hole 6 present in the adjacent circumference.

The advantages of the dehumidifying structure described above are as follows. The springs define a passage of air that allows the drying of the ponderal humidity. During drying, the salt dries inside the spring forming in turn a tubular shape which absorbs the weight moisture of the wall causing it to dry.

Finally, it is clear that modifications and variations can be made to the dehumidifier structure and the method for dehumidifying a wall described above according to what is established by the claims without thereby departing from the scope of the present invention.

Claims (10)

R IV E N D I C A C IO N I 1. Method for dehumidifying a masonry wall (2) of a building; said method comprising the step of making in said wall / ceiling (2) one or more holes (6) which extend along respective longitudinal axes (A); said method being characterized in that it comprises the step of engaging inside at least one hole (6) at least a first tubular spring (7) structured in such a way as to allow the ambient air to come into contact with the internal wall of said hole (6) so as to dehumidify it. Method according to claim 1, wherein said first tubular spring (7) has an external diameter which approximates by default the internal diameter of said hole (6) and an axial length greater than or equal to the depth of said hole (6) along its axis (A). Method according to claims 1 or 2, comprising the step of telescopically engaging a second tubular spring (8) inside said first tubular spring (7) present in said hole (6) so as to accumulate the hygroscopic salts expelled from the wall (2). Method according to claim 3, wherein said second tubular spring (8) is structured in such a way as to expand / deform axially along said axis (A) with respect to said first tubular spring (7) between a rest condition, and a operating condition in which the deformation is indicative of a state of accumulation of hygroscopic salts inside the second tubular spring (8). Method according to claims 3 or 4, comprising the step of extracting the second tubular spring (8) from said first tubular spring (7), and cleaning the second tubular spring (8) from the hygroscopic salts accumulated inside it. Method according to claim 3, wherein said second tubular spring (8) has an external diameter which approximates by default the internal diameter of said first tubular spring (7) and an axial length greater than or equal to the length of said first tubular spring (7). Method according to claim 1, wherein said first tubular spring (7) consists exclusively of a helical wire spring. Method according to claim 3, wherein said second tubular spring (8) consists exclusively of a helical wire spring. 9. Dehumidifying structure (1) to dehumidify a masonry wall / ceiling (2) of a building characterized by the fact of including: one or more holes (6), which are made in said wall / ceiling (2) and extend along respective longitudinal axes (A); one or more first tubular springs (7), which are engaged in said holes (6) and are structured in such a way as to cause the ambient air to come into contact with the inner wall of said hole (6). 10. Dehumidifying structure according to claim 9, comprising one or more second tubular springs (8) able to be telescopically engaged inside the respective first tubular springs (7) in a stable but removable way to accumulate inside them the hygroscopic salts expelled from the wall (2).