NL2007920C2 - A building having a cavity wall structure, an element for extracting moisture from a cavity wall structure, and a method for installing means for abstracting moisture from a cavity wall structure. - Google Patents

Description

A building having a cavity wall structure, an element for extracting moisture from a cavity wall structure, and a method for installing means for abstracting moisture from a cavity wall structure 5

The invention relates to a building having a cavity wall structure comprising an inner skin, an outer skin and a cavity there between, further comprising means for abstracting moisture from said wall structure, said means 10 comprising a hole in said outer skin, and a duct shaped porous moisture-permeable element fixed in said wall structure extending between said inner skin and said hole in the outer skin, such that an enclosed space is formed by said element in said cavity which is in air communication 15 with the air outside said outer skin, while the cavity between the inner skin and the outer skin is substantially sealed by said element from the air outside said outer skin. A building with such means for abstracting moisture from its cavity wall structure is described in EP-A-0829587, which is 20 incorporated herein by reference.

Cavity walls consist of two skins, being the outer skin and the inner skin, separated by a hollow space or cavity. The skins are commonly masonry, such as brick or concrete block. 25 Different masonry materials can be used on either side of the cavity. The cavity can be empty but can also be partially or completely filled with thermal insulation by various methods. Cavity sizes typically are at least 50 mm to 100 mm. Masonry is an absorbent material, and therefore 30 will slowly draw humidity into the wall. The means for abstracting moisture from cavity walls as described in the prior art cause the moisture present in the cavity to condensate on the outer surface of the duct shaped element, 2 and to escape through the porous moisture-permeable wall of the element into the environment. A problem related to this solution is that depending on the climate and location of the building and the duct shaped elements, moisture also 5 condensates inside the building against the inner skin at the location of the element.

The goal of the invention is to provide better abstraction of moisture from cavity walls, and/or abstraction of 10 moisture with less negative side effects, and/or easier and/or better mounting of the means.

According to a first aspect of the invention said duct shaped element is provided with a corrugated outer surface. 15 Because of the larger surface area a better abstraction of moisture is obtained. The corrugations also make it easier to mount the element in the hole in the outer skin, because it has less friction than a smooth surface and will allow the ridges of some corrugations to break if too much force 20 is exerted, whereby it may be prevented that the element is locked in the hole. It can also be fitted easier in holes which are not exactly the same size as the element as some of the corregations can break when some force is exerted allowing to fit. Furthermore, the corrugations will provide 25 a better adhesive surface, for instance for cement.

Preferably said duct shaped element is also provided with a corrugated inner surface. Said corrugations preferably have a height of at least 2 mm, preferably at least 2.5 mm, more 30 preferably approximately 3 mm. The wall of said duct shaped element preferably has a thickness between 6 and 18 mm, preferably between 10 and 14 mm, more preferably approximately 12 mm. Said duct shaped element is preferably 3 made of a porous ceramic material, such as pottery or brick material. The volume enclosed by said duct shaped element is preferably at least 300 cm3, more preferably at least 450 cm3, still more preferably approximately 600 cm3. Said 5 corrugations preferably extend in the axial direction of said duct shaped element.

According to a second aspect of the invention at least closest to at least one corner of said building, preferably 10 at least the corner closest to the generally climatologic coldest side, said means comprise a pad of heat insulating material which is mounted inside the duct shaped element against the surface of the inner skin. Thereby condensation of moisture inside the building against the inner skin is 15 prevented. The heat insulating capacity of the pad is preferably approximately the same as the heat insulating capacity of the outer skin plus the cavity. The circumference of said pad is preferably substantially identical to the inner circumference of the inner side of 20 the cross-section of the duct shaped element.

Said duct shaped element preferably has a substantially rectangular cross-section. Said duct shaped element preferably has height which is substantially the same as the 25 height of bricks surrounding the element of which said outer skin is built up, for instance a height of approximately 80 mm. Said duct shaped element preferably has width which is equal to or more than half the width of bricks surrounding the element of which said outer skin is built up, for 30 instance a width of approximately 130 mm. Said duct shaped element preferably has a depth which is such that the element extends from the inner skin into the hole in the outer skin, for instance a depth of approximately 100 mm.

4

Said duct shaped element is preferably mounted in said hole in the outer skin, for instance by providing cement between the outer surface of the element and the surrounding outer 5 skin. Said means further preferably comprise an air guiding element mounted in said hole in the outer skin, said air guiding element being structured such that air moving along the outer side of said outer skin is guided in and out of the enclosed space. An example of such an air guiding 10 element is described in EP-A-0829587, which is incorporated herein by reference.

The invention also relates to a duct shaped porous moisture-permeable element, wherein said duct shaped element is 15 provided with a corrugated outer surface.

The invention also relates to a method for installing means for abstracting moisture from a cavity wall structure comprising an inner skin, an outer skin and a cavity there 20 between, said method comprising providing a hole in said outer skin, and mounting a duct shaped porous moisture-permeable element in said wall structure extending between said inner skin and said hole in the outer skin, such that an enclosed space is formed by said element in said cavity 25 which is in air communication with the air outside said outer skin, while the cavity between the inner skin and the outer skin is substantially sealed by said element from the air outside said outer skin, wherein said duct shaped element is provided with a corrugated outer surface.

The invention also relates to a method for installing means for abstracting moisture from a cavity wall structure comprising an inner skin, an outer skin and a cavity there 30 5 between, said method comprising providing a hole in said outer skin, and mounting a duct shaped porous moisture-permeable element in said wall structure extending between said inner skin and said hole in the outer skin, such that 5 an enclosed space is formed by said element in said cavity which is in air communication with the air outside said outer skin, while the cavity between the inner skin and the outer skin is substantially sealed by said element from the air outside said outer skin, wherein at least closest to at 10 least one corner of said building, typically on the coldest side of the building, a pad of heat insulating material is mounted inside the duct shaped element against the surface of the inner skin.

15 The invention will be illustrated by means of a description of a preferred embodiment with reference to the figures, wherein :

Figures 1 and 2 are partial cross sectional perspective 20 views of a wall structure according to the invention; and

Figrues 3A and 3B are perspective views of a duct shaped porous moisture-permeable element and a pad of heat insulating material according to the invention.

25

According to the figures 1 and 2 a cavity wall structure of a building comprises an inner skin 1, an outer skin 2 and cavity 3 there between. The outer skin 2 is for instance made of masonry comprising cement 4 and bricks 5. The inner 30 skin is for instance made of concrete slabs 6 or also of masonry. Insulation material 7 may be provided in the cavity 3.

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The means for abstracting moisture from the cavity wall structure comprise a duct shaped porous moisture-permeable element 8, an air guiding element 9 and a pad 10 of heat insulating material.

5

The duct shaped moisture-permeable element 8 is for instance made from moist-permeable pottery or brick. It has a rectangular cross section, seen from the front of the wall, and consists of a single circumferential wall. The outer 10 surface of the element 8 is corrugated, with the ridges 81 of the corrugations extending in axial direction. The corrugated surfaces enlarge the surface of the element up to double the surface area, whereby the condensation/evaporation capacity of the element is enlarged 15 up to double the capacity. Furthermore the corrugated outer surface forms a good adhesive surface for cement. Also, if the element is inserted in a hole in an existing wall, the corrugations cause less friction than a smooth surface and the ridges of the corrugations are allowed to break when 20 they contact the wall of the hole in order to prevent that the element is locked in the hole before it is in the final position .

The air guiding element 9 is comprised of a rectangular 25 frame 91, for instance made of brick or concrete, said frame defining an opening, a clock shaped body 92 (seen in horizontal cross section) extending inside the opening of the frame 91 such that two oblique air ducts 94 are defined at both sides of the clock shaped body, and a vertical 30 separating wall 93 extending from the back of the body 92. The front of the wider side of the clock shaped body 92 extends at a distance from the front of the frame 91, such that air flowing along the front of the wall is diverted 7 into one of the air ducts 94, as indicated by the arrows.

The cross sections of both elements 8, 9 are rectangular, seen from the front of the wall, and are of comparable size.

5 The heat insulating pad 10 may be made of any suitable heat insulating material and has a generally rectangular shape with dimensions that fit the outer cross section of the duct shaped element 8. The pad 10 is placed between the inner skin 1 and the duct shaped element 8 and may be glued 10 against the backside of the duct shaped element 8 before said element 8 is inserted in the hole.

The means for extracting moisture from the cavity wall can be fixed either in a wall while said wall is being built or 15 in an existing wall, by providing a hole in the outer skin 2 which is slightly larger than the cross sections of the elements 8, 9, seen from the front of the wall. First duct shaped element 8 is placed with one outer end against the surface of the inner skin 1 and the other outer end 20 extending in the hole in the outer skin 2, and is fixed to the outer skin 2 by a layer of cement 11. If necessary, especially near one or more corners of the building, the pad 10 of heat insulating is fixed inside the element 8 against the surface of the inner skin 1. Then the air guiding 25 element 9 is fixed in the hole in the outer skin 2 by a layer of cement 12, such that the front of the frame 91 is in the same plane as the front of the outer skin 2.

The air guiding element 9 guides air flowing outside the 30 outer skin 2 through one of the air ducts 94 into the space enclosed by the element 8, towards the back and around the separating wall 93 and the other air duct 94 (or vice versa), as indicated by the arrows in figure 2. Thereby a 8 cold spot is created in the wall of the element 8, and moist condensates on the moist-permeable element 8. The moist passes through the element 8 into the enclosed space and evaporates into the air flow through the air duct 94. The 5 pad 10 prevents that a cold spot is created in the inner skin 1 of the wall, whereby moist would condensate inside the building on the inner side of said skin 1.

The invention is not limited to the embodiment described 10 above and many modifications are possible for instance with regard to shape, materials and dimensions within the scope of the appended claims.

Claims (15)

A building with a cavity wall structure comprising an inner wall, an outer wall and a cavity therebetween, further comprising means for extracting moisture from the wall structure, the means comprising a hole in the outer wall, and a tubular porous moisture-permeable element that is in the wall is fixed and extends between the inner wall and the hole in the outer wall such that an enclosed space in the cavity is formed by the element in air communication with the air outside the outer wall, while the cavity between the inner wall and the outer wall substantially of the air outside the outer wall is closed off by the element, characterized in that the tubular element is provided with a ribbed outer surface. The building of claim 1, wherein the ridges have a height of at least 2 mm, preferably at least 2.5 mm, more preferably at least 3 mm. 20 3. Building as claimed in claim 1 or 2, wherein the wall of the tubular element has a thickness between 6 and 18 mm, preferably between 10 and 14 mm, more preferably about 12 mm. 25 The building of claim 1, 2 or 3, wherein the tubular element is made of a porous ceramic material, such as earthenware or brick material. 5. Building as claimed in any of the foregoing claims, wherein the ridges extend in the axial direction of the tubular element. 6. Building as claimed in any of the foregoing claims, wherein at least the closest at least one corner of the building, preferably the corner that is closest to the usually climatic coldest side, the means 5 is a mat of heat-insulating material which is mounted in the tubular member against the surface of the inner wall. 7. Building as claimed in any of the foregoing claims, wherein the heat-insulating capacity of the mat is approximately equal to the heat-insulating capacity of the outer wall plus the cavity. 8. Building as claimed in any of the foregoing claims, wherein the tubular element has a substantially rectangular cross-section. 9. Building as claimed in any of the foregoing claims, wherein the tubular element has a depth that is such that the element extends from the inner wall into the hole in the outer wall. 10. Building as claimed in any of the foregoing claims, wherein the tubular element is fixed in the hole in the outer wall, for example by placing cement between the outer surface of the element and the surrounding outer wall. 11. Building as claimed in any of the foregoing claims, wherein the means further comprise an air-conducting element which is fixed in the hole in the outer wall, the air-conducting element being formed such that air flowing in and out of the outer wall of the outer wall enclosed space. 12. Tubular porous moisture-permeable element, characterized in that the tubular element is provided with a ribbed outer surface. 13. Method for installing means for extracting moisture from a cavity wall structure comprising an inner wall, an outer wall and a cavity therebetween, the method comprising providing a hole in the outer wall, and attaching a tubular porous moisture-permeable element extending between the inner wall and the hole in the outer wall such that an enclosed space in the cavity is formed by the element in air communication with the air outside the outer wall, while the cavity between the inner wall and the outer wall is substantially through the element is sealed off from the air outside the outer wall, characterized in that the tubular element is provided with a ribbed outer surface. 14. Building with a cavity wall structure comprising an inner wall, an outer wall and a cavity therebetween, further comprising means for extracting moisture from the wall structure, the means comprising a hole in the outer wall, and a tubular porous moisture-permeable element which is in the wall is fixed and extends between the inner wall and the hole in the outer wall such that an enclosed space in the cavity is formed by the element in air communication with the air outside the outer wall, while the cavity between the inner wall and the outer wall substantially from the air outside the outer wall is sealed by the element, characterized in that at least the closest to at least one corner of the building, preferably the corner that is closest to the usually climatic coldest side, the means mat of a heat-insulating material which is mounted in the tubular element against the surface of the inner wall. 15. A method for installing means for extracting moisture from a cavity wall structure comprising an inner wall, an outer wall and a cavity therebetween, the method comprising providing a hole in the outer wall, and attaching a tubular porous moisture-permeable element extending between the inner wall and the hole in the outer wall such that an enclosed space in the cavity is formed by the element in air communication with the air outside the outer wall, while the cavity between the inner wall and the outer wall is substantially through the element is sealed off from the air outside the outer wall, characterized in that at least closest to at least one corner of the building a mat of heat-insulating material in the tubular element is fixed against the surface of the inner wall.