NL2012238C2 - DEHUMIDIFYING DEVICE AND WALL WITH SUCH DEHUMIDIFYING DEVICE. - Google Patents

Abstract

The present invention relates to a moisture extraction device configured to extract moisture from a wall. The moisture extraction device comprises a tube, an inner wall and a central axis, in which tube a partition extends parallel to the central axis, with both long sides closely abutting against the inner wall of the tube. The moisture extraction device further comprises a closing device which is in contact with an end side of the partition and which partially closes the tube, defining a ventilation channel on either side of the partition, so that air can flow into the tube via one of the ventilation channels, into a first subchannel between the partition and the inner wall of the tube, to the other side of the partition into a second subchannel between a second surface of the partition remote from the first surface and the inner wall of the tube and out of the tube via the other ventilation channel. The tube has a circular cross-section.

Description

Short indication: Dehumidifier and wall provided with such a dehumidifier

Description

According to a first aspect, the present invention relates to a dehumidifier, adapted to extract moisture from a wall, the dehumidifier, comprising a tube with a length L1, an inner wall and a center line, wherein a partition is arranged in the tube parallel to the center line. and with both longitudinal sides at least substantially close-fitting against the inner wall of the tube over a length L2 <L1 in the cup, the dehumidification device further comprising a closing device which is in contact with an end face of the partition and the tube on partially closing the corresponding head end, defining at least one ventilation channel connected to the interior of the sleeve on either side of the partition, so that air can flow into the sleeve via one of the ventilation channels, in a first subchannel defined by a first face of the bulkhead and the corresponding part of in the inner wall of the tube, and subsequently at the head end of the tube not closed by the closing device to the other side of the partition in a second subchannel, defined by a second second plane of the partition remote from the first plane and the corresponding part of the inner wall of the duct to flow out of the duct via the other ventilation duct.

Such a dehumidifying device is known from BE 1010625A3. The known dehumidification device has a tubular element of cured clay with a rectangular cross-section, which when used in a rectangular recess of an outer wall is placed in a cavity wall. A plate with a sealing surface, the outer circumference of which corresponds to the outer circumference of the tubular element, partially closes a head end of the tubular when used, leaving a rectangular through hole centrally. In use, a rectangular frame and a bell-shaped body with a baffle, which divides the tubular element into a left and a right subchannel, are inserted into the rectangular through hole, with between the frame and the bell-shaped body on the left and the right side of the hole. bell-shaped body a ventilation channel has been released In use, the tubular element is inserted through an outer wall of a cavity wall, with its end opposite the frame against an inner wall, so that the relevant end is closed off by the inner wall. When air flows in through a ventilation channel in the tubular element and ultimately through the other ventilation channel, air is refreshed in the tubular element. If the wall is moist, the air in the tubular element will absorb moisture, with the result that relatively moist air is always displaced by relatively dry air, which during its stay in the tubular element can in turn absorb moisture before it is displaced again.

A drawback of the known dehumidification device is that leakage currents arise in the tubular element, in particular when the tubular element is made of a porous, moisture-permeable material, such as cured clay. The reason is that the tubular element, which has been manufactured by shortening a long tube of clay made by means of extrusion and then curing the clay, has relatively large tolerances. The bulkhead must therefore be made slightly narrower on average than the clear dimension of the tubular element, with the result that leakage currents arise during use. Another drawback of the known device is that the tubular element and the frame often do not connect well to the cavity in the wall, so that a gap must be lubricated with mortar.

The present invention therefore has for its object to provide, in accordance with the first aspect, a dehumidification device according to the introduction, wherein the degree of leakage currents, and / or at least the chance of leakage currents, is reduced with respect to the known dehumidification device. This object is achieved according to the present invention in that the sleeve has a circular cross section. A sleeve with a round cross-sectional shape has a greater resistance to deformation during the trimming of a long sleeve than a known sleeve with a rectangular cross-sectional shape, which is slightly pressed down by a knife when trimming. Thus, the tolerances of the tubes according to the present invention are considerably smaller than with the rectangular cross-sectional shape. Thus, at least in the case of materials which do not automatically return to their starting shape after deformation, it is made possible to have a baffle to be inserted into the tube correspond more precisely with the inside but of the tube. This results in a better connection between the side edges of the partition and the inner wall of the tube, which in turn results in smaller leakage currents, and / or a smaller risk of leakage flows, between the partition and the inner wall of the tube. This ensures, at least better than with the known device, that as much air as possible travels as long as possible through the duct, that is, from the one ventilation duct, through the first sub-duct, over the entire length of the partition, and again back through the second subchannel and the other ventilation channel and can absorb a maximum amount of moisture. Thus the advantage of the present invention has been achieved.

Another advantage of the present invention is that it can be used both in a configuration in which the wall is a cavity wall and in a configuration in which the wall is a brick wall without a cavity. In the first case the sleeve is preferably a pipe piece, while in the second case the sleeve can either be a pipe piece or be formed by the wall surrounding the bulkhead. In the case of a separate tube in the form of a pipe section, the closing device may have an outer circumference corresponding to that of the outer circumference of the tube, the closing device being located against the relevant end face of the tube. In the case where the wall forms the sleeve, the outer circumference of the sealing device may correspond to the clear cross-section of the sleeve, or the cylindrical hole in the wall, an outer edge of the sealing device closely abutting the inner wall of the sleeve (wall)

In a preferred embodiment of the present invention, the sleeve is made of a porous, moisture-permeable material. The wall of the sleeve preferably at least substantially prevents air from flowing from the cavity into the sleeve, or vice versa from flowing from the sleeve into the cavity. Preventing an air flow does not necessarily mean that no air can enter the duct from the cavity, or vice versa. But it does mean that no so-called gust of wind can penetrate the wall of the tube. The moisture-permeable property supports the removal of moisture from the wall, because moisture can be transported from outside to inside through the moisture-permeable wall of the tube.

It is thereby preferred that the sleeve is made of ceramic material, preferably clay. Ceramic material, and in particular hardened clay, is excellent as a porous moisture-permeable material that can transport moisture and thus helps to prevent strong airflow from passing through the material unimpeded.

According to a second aspect, the present invention relates to a cavity wall with at least one dehumidifier, and preferably a plurality of dehumidifiers. A wall with the known dehumidifier device suffers from the disadvantages described earlier in relation to the first aspect of the invention. In order to provide a solution to the disadvantages, the invention provides a wall comprising an inner wall and an outer wall and between them a cavity with a depth D, and at least one device for the dehumidification device for mounting on the wall arranged in a hole in the outer wall. moisture extraction, the dehumidifier comprising a tube sleeve with length L1 'defining an air guide channel located between two ventilation channels extending in different directions, an inner wall and a center line, wherein a partition parallel to the center line and at least at least on both longitudinal sides is present in the tube extends substantially tightly against the inner wall of the sleeve over a length L2 '<L1' with L1 '> D, so that the sleeve forms on the one hand a sealing wall between said hole and the surrounding cavity and on the other hand over at least a length L3 <the thickness extends from the outer wall into the outer wall, which tube is partially closed by a closing device A device as defined in the first aspect of the invention, characterized in that the sleeve has a circular cross section. Due to the reduced chance of leakage currents occurring in the dehumidifier, it will be possible to dehumidify a wall faster and / or to a greater extent than a wall with a comparable number of known dehumidifier devices.

According to a third aspect, the present invention relates to a wall designed as a stone wall comprising at least one dehumidifier device arranged in a hole in the outer wall for extracting moisture from the wall, the dehumidifier device comprising a ventilation ducts located between two in different directions air guide channel defining a cylindrical hole with length L4, an inner wall and a center line, wherein in the cylindrical hole a partition parallel to the center line and on both longitudinal sides extends at least substantially closely against the inner wall of the sleeve over a length L2 ”<L4 with which cylindrical hole is partially closed by a closing device as defined in the first aspect of the present invention. It is true that the problem of an inaccurate clear dimension of a tube with a rectangular cross section does not arise here. Here there is a corresponding problem of an inaccurate clear dimension of a hole with a rectangular cross-section that is in the wall, or at least has to be made. It is much easier and more accurate to drill round holes than to save rectangular holes from a wall. It is thereby preferred that a dehumidifying device according to the first aspect of the invention is provided in the hole.

When the closing device protrudes from the outer wall on the side remote from the tube, and thus provides a protruding part between the two ventilation ducts, wind flowing along the relevant outer wall is more easily fed into the tube via one of the ventilation ducts. Moreover, the protruding part can simply be designed by a person skilled in the art in such a way that it is likely that an air flowing through the outer wall at the height of the protruding part causes a Venturi effect, whereby the flow of the dehumidifier is improved and the dehumidification is further supported.

The present invention will be further explained below with reference to the accompanying drawing, in which:

Figure 1 shows a perspective side view of a preferred embodiment of a dehumidifier device according to the present invention;

Figure 2 shows a horizontal cross-sectional view through the axis of the sleeve of the dehumidifier of Figure 1;

Figure 3 shows a vertical sectional view through the center line of the tube of the dehumidifier of Figure 1;

Figure 4 shows a horizontal sectional view of the dehumidifier device of figures 1-3, incorporated in a cavity wall.

Figure 5 shows a horizontal sectional view through the center line of the tube of the dehumidifier of figures 1-3, incorporated in a stone wall.

In this document, unless explicitly stated otherwise, orientations are related to the state of use of the dehumidifier, that is to say, a tube arranged horizontally in a wall with a baffle extending vertically into the tube. Turning now to Figures 1 to 3, a dehumidifier 1 as an exemplary embodiment of a dehumidifier according to the present invention is shown in perspective view, horizontal section view and vertical section view, respectively. The dehumidifier 1 has a cylindrical sleeve 2 of dried clay with a length L1 of 10 cm, an inside diameter of 5.6 cm and an outside diameter of 7.6 cm. Tube 2 is open at both ends, however, at one of both ends tube 2 is partially closed by means of a plug 3 as a closing device. Plug 3 has a cylindrical wall 4, the outer circumference of which has a diameter of 7.6 cm and corresponds thereto, that is to say substantially aligned, with the outer circumference of sleeve 2. On the end face of the plug directed towards the sleeve 2 3, a plastic plate 5 extends as a partition into tube 3. Plate 5 has a width of 5.5 cm and thus closely connects on its longitudinal sides 6a, 6b against the inner wall 7 of tube 2 and extends over a length L2 of 9.5 cm through almost the entire length of sleeve 2. As such, two subchannels 9a, 9b are formed in the interior of sleeve 2. On the side remote from plate 5, plug 3 has an end wall 8 which extends at right angles to a center line of cylindrical wall 4 and from which a wedge-shaped element 10 extends diverging away from the sleeve 2. Between each of the two diverging sides and the cylindrical wall 4 of plug 3, there is an opening of respective ventilation ducts 11a, 11b extending through plug 3. Ventilation channel 11a is communicatively connected to subchannel 9a and ventilation channel 11b is communicatively connected to subchannel 9b. As such, an air flow channel is formed which extends from ventilation channel 11a to subchannel 9a via a space left clear by plate 5 in tube 2 through subchannel 9b and then ventilation channel 9b.

Figure 4 shows in a horizontal cross-sectional view the dehumidifier 1 of figures 1 to 3 which is accommodated in a wall with an inner wall 21, an outer wall 22 and a cavity 23 between them. The cavity is shown here as a cavity , but can also be filled with an insulation material. The space for the dehumidifier 1 can be easily provided by drilling a hole in the outer wall 22 with a cross section of, for a dehumidifier 1 from this exemplary embodiment, 76 mm. An advantage of the round cross-section is that a round hole for dehumidifiers according to the present invention is easier to provide than a rectangular hole for a previously known dehumidifier device. This reduces installation costs. Subsequently, the sleeve 2 can be slid into the hole until its leading end side makes contact with the inner wall 21, so that the leading end side of the sleeve 2 is at least largely closed off by the inner wall 21. It is important that the sleeve 2 has a length that is greater than the depth of the cavity 23 and smaller than the depth of the cavity 23 plus the thickness of the outer wall 22. In this exemplary embodiment, the sum of the length of sleeve 2 comes and the length of the cylindrical wall 4 of the plug 3 corresponds to the sum of the thickness of the outer wall 22 and the depth of the cavity 23. After the insertion of sleeve 2, plug 3 with plate 5 is aligned vertically in the cavity pushed until the head side of cylindrical wall 4 of plug 3 comes into contact with the head side of sleeve 2. By applying an adhesive sealant to the outside of cylindrical wall 4 prior to insertion of plug 3, after curing of the adhesive sealant a tightly sealed connection between the wall and the dehumidifier 1. If there is wind on the outside of the outside wall 22, the wedge-shaped element 10 will penetrate air along the outside wall 22 into a ventilation duct, in this case In this case, guide the ventilation channel 11a in the duct 2, in particular in the sub-channel 9a. The air is forced to follow sub-channel 9a as far as the end of the tube 2, in order to then be guided at the end of the tube 2 via the inner wall 21 sealing the tube 2 into sub-channel 9b. There, the air then flows back to the outer wall 22 and then out via ventilation channel 11b. This air flow is enhanced by the occurrence of a Venturi effect near the outlet of ventilation duct 11b. The air flow is shown with arrows in Figure 4.

If there is a damp wall, the inner wall 21, and thus the part of the inner wall 21 that closes the end face of the tube 2, is moist. The sleeve 2 also absorbs moisture on the outside, which is distributed over the entire thickness of the sleeve 2 by the moisture-absorbing and moisture-permeable property and is thus transported to the inner wall 7 of the sleeve 2. On the inner wall 7 of the tube 2, moisture is delivered to the air in the tube 2. That relatively moist air is continuously refreshed by the air flow described above and replaced by relatively dry air. A continuous dehumidification process is thus provided. It is irrelevant from which direction the wind blows, because with an opposite wind direction an air flow will occur in the opposite direction, naturally with the same effect.

It is of course possible that a leakage current occurs in the dehumidifier according to the invention because the side edges 6a, 6b of plate 5 often do not connect completely sealingly to the inner wall 7 of the tube 2. But the (average) leakage current is considerably smaller than that of the known devices.

Figure 5 shows a horizontal cross-sectional view of a dehumidifier 31 according to the present invention incorporated in a stone wall 25. The reference numerals have been increased by 30 for elements corresponding to figures 1 to 4 in order to prevent a repeat of a detailed introduction of elements. In this exemplary embodiment, a cavity 24 is drilled into the stone wall 25. The cavity 24 has a depth of 14 cm, so that here too the 9.5 cm long plate 35 of the plug 33, if the end wall 38 of the plug 33 is aligned with the outside of the stone wall 25, is up to approximately 0.5 a distance from the end of the cavity 24 into the cavity. A difference between dehumidifier 31 and dehumidifier 1 is that a separate tube is missing. The cavity 24 in stone wall 25 itself fulfills the function of a tube. As a result, plate 35 is wider than plate 5 of dehumidifier 1, and as wide as the outer diameter of the cylindrical wall 34. Thus, the side edges 36a, 36b of the plate 35 (not visible in Figure 5) fit closely against the inner wall of cavity 24. The operation of dehumidifier 35 largely corresponds to that of dehumidifier 1, although there is no need for transfer of moisture via a separate tube.

The invention is illustrated in the figures and the above description with reference to exemplary embodiments. It is to be understood, however, that the figures and the description have no limiting influence on the protection. Many variants, whether or not obvious to those skilled in the art, are conceivable within the scope of the present invention, which is defined by the following claims. Dimensions and materials can be selected differently than those mentioned in the examples. With cavity walls, it is possible to fit a longer sleeve into the cavity, for example with a length corresponding to the depth of the cavity and the thickness of the outer wall, wherein the plug with its cylindrical outer wall fits snugly against the inner wall of the sleeve in the cavity. sleeve is brought. It is also possible to provide a stone wall with a hole whose diameter is offset, such that the plug can be received in a relatively wide part of the hole with the leading end face against a staircase of the hole to a part of the hole with a relatively small diameter corresponding to the width of the plate of the plug.

Claims (8)

A dehumidifier, adapted for extracting moisture from a wall, the dehumidifier comprising a tube with a length L1, an inner wall and a center line, wherein a partition is arranged in the tube parallel to the center line and with both longitudinal sides at least substantially at least substantially tightly against the inner wall of the sleeve over a length L2 & L1 extends into the sleeve, the dehumidification device further comprising a closing device which is in contact with an end face of the partition and partially closes the sleeve at the corresponding end of the end, thereby defining at least one ventilation channel connected to the interior of the tube on each side of the partition, so that air can flow into the tube via one of the ventilation channels, in a first sub-channel defined by a first plane of the partition and the corresponding part of the inner wall of the sleeve, in order to then not pass through the shut-off The device terminates the end of the tube closed to the other side of the partition in a second subchannel, defined by a second second plane of the partition remote from the first plane and the corresponding part of the inner wall of the tube through the other ventilation duct. to flow into the sleeve, characterized in that the sleeve has a circular cross section. 2. Dehumidifier according to claim 1, characterized in that the sleeve is made of a porous, moisture-permeable material. 3. Dehumidifier according to claim 2, characterized in that the tube is made of ceramic material, preferably clay. 4. Wall comprising an inner wall and an outer wall and between them a cavity with a depth D, and at least one dehumidifier arranged in a hole in the outer wall for extracting moisture from the wall, the dehumidifier comprising one between two air duct channel defining ducts with length L1 ', an inner wall and a center line located in air ducts, wherein a baffle is parallel to the center line and on both longitudinal sides at least substantially closely fitting against the inner wall of the duct over a length L2' &lt; L1 'extends with L1' &gt; D, so that the sleeve forms on the one hand a sealing wall between said hole and the surrounding cavity and on the other hand extends over at least a length L3 &lt; the thickness of the outer wall extends into the outer wall, which sleeve is partially closed by a closing device as defined in claim 1, characterized in that the sleeve has a circular cross section. 5. Wall-shaped wall comprising at least one dehumidifier device arranged in a hole in the outer wall for extracting moisture from the wall, the dehumidifier device comprising a cylindrical hole with length L4 defining air ducts extending between two different directions, a hole inner wall and a center line, wherein a partition parallel to the center line and on both longitudinal sides extends at least substantially close-fittingly against the inner wall of the tube over the length L2 "& Lt", with which cylindrical hole is partially closed, in the cylindrical hole by a closing device as defined in claim 1. Wall according to claim 4 or 5, characterized in that a dehumidifying device according to one of claims 1 to 3 is arranged in the hole. 7. Wall as claimed in claim 6, characterized in that the closing device, if dependent on claim 5 on the side remote from the tube, protrudes out of the outer wall, and thus provides a protruding part between the two ventilation ducts. 8. Wall as claimed in claim 7, characterized in that the protruding part is of wedge-shaped design, wherein the point of the wedge is directed in the direction of the sleeve or the cylindrical hole.