NL9400059A - Roof tile for ventilation purposes. - Google Patents

Description

Roof tile for ventilation purposes.

The invention relates to a roof tile for ventilation purposes, in particular a hollow plastic roof tile, with which spaces below a roof tile covering of a building and the outside air can be connected to each other.

Such a roof tile is known from British patent application 2,262: 295. The known extrusion molded roof tile comprises a top plate and a bottom plate which are spaced apart to define a laterally closed hollow space between which the hollow space is longitudinally extending from the roof tile and to the open end face bottom edge of the roof tile communicates with the outside air and at the top top edge of the roof tile communicates with the space between the tiles and the underlying roof construction. The known roof tile has the advantage that a bidirectional ventilation means is provided, which moreover will hardly or hardly stand out in a tiled roof: only the open, lower end edge of the known tile forms a deviation from the adjacent tiles.

The known pan, the hollow space of which extends over the full length of the pan, may optionally be provided with transverse ribs or similar thresholds on the inside of the bottom plate to prevent moisture / water from being blown through the hollow space to the top opening. and the space below the pans. Such ribs, which reduce the flow cross-section, can cause an undesired impediment to the air flow in the hollow pan, while, if they do release a sufficient flow area, they are insufficiently high salts to prevent air entrainment of deposited water to the top opening. .

The object of the invention is to improve on this and to that end provide a roof tile of plastic, comprising a top plate and a bottom plate, which are spaced apart to define a hollow space closed in lateral directions, with a bottom opening, which is provided in the end bottom edge of the pan, for passage of air to and from the cavity and discharge of moisture from the cavity, and with an upper opening, at least partly provided in the bottom plate, for passage of air to and from from the hollow space to or from the spaces located below the roof tile in the situation of use of the roof tile, wherein the bottom plate is designed such that an expansion chamber is formed in the hollow space for air entering via the bottom opening.

The expansion chamber, which widens the flow-through profile of at least the air flowing in from the outside, provides a retardation area for the moisture- and dirt-bearing air, so that the water particles and dirt particles, which fall in dripping form or as the roof tile runoff, coming in the vicinity of the bottom opening and being fed into the hollow space with the air entering, having the opportunity to deposit on the bottom of that room.

Preferably, in the roof tile according to the invention, the deposited moisture is collected by the expansion chamber, for which purpose the bottom plate in a part thereof, which is located at a distance from the bottom opening and the top opening, forms a container defined by a lowered bottom, the top plate in the longitudinal direction of the roof tile straightens. The precipitated water is thus kept out of the main air flow. Excess water can drain from the container and leave the hollow pan through the bottom opening.

Preferably, the expansion chamber also forms an enlargement of the flow cross section relative to the top opening. In fact, the upper opening hereby forms a constriction with respect to the expansion chamber, whereby an acceleration area for the largely moisture-free inflowed air is realized, while, moreover, a threshold is raised against any accumulated water in the expansion chamber.

The hollow space preferably extends over at least substantially the full width of the pan. This allows the air currents in the cavity to equalize in the transverse direction, so that as much as possible a uniform flow occurs and local large, water-entraining accelerations are avoided. In addition, the ease of manufacture of the hollow roof tile is enhanced by the absence of longitudinal dividers, such as are found in the roof tile according to British patent application 2,262,295. If necessary, local protrusions may be formed in the bottom plate, on the top of which the top plate can rest.

The hollow space thereby preferably extends in an at least almost uninterrupted manner from one longitudinal side to the other longitudinal side of the roof tile.

In order to keep the mutual distance of the bottom plate and the top plate as small as possible, at least as much as possible according to the thickness of the surrounding tiles, the bottom opening extends over at least substantially the full width of the roof tile.

According to a first further development of the roof tile according to the invention, the top opening is arranged in the end top edge of the tile. This top opening preferably extends over at least substantially the full width of the pan. The roof tile is therefore ideal for exchanging air between the environment and the space directly below the roof tiles.

According to a second further development of the roof tile according to the invention, the top opening is arranged in the bottom plate, namely above the part thereof which forms the bottom of the expansion chamber. This top opening is preferably defined by a downwardly projecting pipe stub. This embodiment of the roof tile according to the invention is in particular suitable for connection to a mechanical ventilation system or a sewer release pipe, in which both cases the roof tile must be connected to a roof passage or a pipe located directly below the roof covering. In the case of exhaust of air from the spaces of a building located below the roof, the expansion chamber is advantageous because it prevents excessive build-up of pressure due to wind and allows the discharge function to be maintained for longer. The expansion chamber also works in the moisture transport inhibiting manner already described above, namely by preventing the passage of moisture from outside the roof to the mechanical ventilation system.

The roof tile according to the invention is further preferably characterized in that the bottom plate is step-shaped near the top edge of the roof tile to define bearing surfaces for support on a tile batten. The roof tile according to the invention can then be laid quickly, whereby the tile batten will lie between the expansion chamber and the step-shaped part of the bottom plate. The spaces between the battens can then place at the bottom of the expansion chamber of the roof tile.

It is advantageous if the top end edge of the top plate is substantially straight. This is advantageous in particular if the roof tile is to have a corrugated appearance, because the corrugated top plate can then connect to the bottom plate via a straight edge, making the production of the top plate easier and the length of the connection area of the top edges easier. of the bottom plate and the top plate is kept at a minimum. In addition, the same top plate can be used for the two further developed types of roof tile described above.

In the embodiment of the roof tile with the step-shaped bottom plate area near the top edge and the straight top end edge of the top plate, it is advantageous if the top end edge of the top plate is flush with the edge of the step, which plane is substantially parallel on the main surface of the roof tile. The airflow through the cavity is then displaced downwards and flows out of the roof tile in an area close to the roof covering, so that the incoming flow is slowed less by the protruding parts of other roof tiles present in the immediate vicinity.

The invention will now be described in more detail with reference to a number of exemplary embodiments shown in the accompanying drawing.

Shown in: figure 1 is a perspective view of a first preferred embodiment of the roof tile according to the invention; figure 2 shows a side view of the roof tile of figure 1; figure 3 shows a front view, at the lower front edge, of the roof tile of figure 1; figure 4 shows a perspective, schematic bottom view of the roof tile of figure 1, but the length has been shortened; figure 5 shows a schematic representation of the roof tile of figure 1 in a position placed in a tiled roof; figure 6 shows a perspective, schematic bottom view of a second preferred embodiment of the roof tile according to the invention, on a scale departed in the same manner as figure 4; and figure 7 shows a schematic representation, according to figure 5, of the roof tile of figure 6 in a position placed in a tiled roof.

The hollow roof tile 1 shown in figure 1 consists of a plastic top plate 2 and a plastic bottom plate 3, both of which are made of, for example, polycarbonate, for example by vacuum forming or injection molding. The perimeter of the roof tile 1 corresponds to that of a tile that will be adjacent to it.

The top plate 2 has a color (not shown) which corresponds to the color of the roof tiles which will adjoin them in use situation. The shape of the top plate 2 is also in accordance with the roof tiles connecting in the use situation. The top plate 2 may therefore have a flat or a corrugated top surface 10.

The top plate 2 further has an upper edge 5, a lower edge 6, a side edge area 7 and an opposite side edge area 8. The top edge 5 extends straight and forms the end of a horizontally running portion 36, which connects smoothly to end wall areas 4, which also smoothly transition into the corrugated top surface 10 of the top plate 2.

The lower edge 6 of the top plate 2 has a wave-like shape, corresponding to the cross-sectional shape of the top surface 10 of the top plate 2.

The side edge area 8 has a drooping longitudinal edge and has a cross-sectional profile 9 similar to that of ordinary roof tiles to provide support and resistance to lateral displacement for the adjacent ordinary roof tile.

The other side edge area 7 also has a hanging longitudinal edge and is intended to rest on the profiled side edge area of the adjacent ordinary roof tile and to be restrained against lateral displacement.

The top plate 2 has, at the bottom edge 6, adjoining the side edge regions 7 and 8, still hanging parts 11 and 12, which serve to define a downwardly opening receiving channel for the side edge strips of the bottom plate 3 yet to be described, in cooperation with the drooping longitudinal edges of the edge regions 7 and 8.

The bottom plate 3 has a shape that differs from the bottom shape of conventional roof tiles. As can also be seen in figure 2, a striking feature of the bottom plate is the presence of a box-shaped part 19, which is delimited in longitudinal section by a strongly sloping wall 22, gently sloping walls 20 and 21, and again a more sloping wall 23. Such as can be seen in figure 1, the tray 19 extends over almost the full width of the roof tile 1 and is bounded in the lateral direction by substantially upright side walls 32 and 33.

The wall portion 22 connects to the lower portion 35, which, viewed in cross-section, is formed substantially in accordance with the cross-section of the top plate 2, because this portion is intended to rest in a tiled roof on top of an ordinary roof tile situated below it. The wall portion 22 will then lie directly above the top end edge of that ordinary roof tile, as is also shown in figure 5.

At the top, the wall 2 3 changes via a kink into a transverse strip area 24, which together with the edge 26 and the transverse strip area 25 connected thereto form a step. The space defined by wall portion 23 and cross-strip areas 24 and 25 is suitable for receiving a tile batten, as shown with tile battens 42 in Figure 5.

Via a kink, the transverse strip area 25 merges into transverse strip area 27, the top edge 13 of which forms the front edge of the bottom plate 3. This edge 13 extends from one side edge of the bottom plate to the other side edge thereof such that it runs horizontally over a small area adjoining the side edge strip 15 of the roof tile, then runs downwards and then over almost the full width of the roof tile running to the other side thereof, parallel to the edge 5 of the top plate 2, then bent vertically upwards again, is finally to end again in a substantially horizontal part connecting to the other side edge strip 16. The straight edge 5 of the top plate 2 and the edge 13 of the bottom plate 3 define a wide rectangular air passage opening, as can be seen in figure 4, which is actually located next to the top plate 2, i.e. only one-sidedly through the top plate 2 is determined.

At the lower end of the roof tile 1, the bottom edge 14 of the bottom plate 3 and the bottom edge 6 of the top plate 2 define a corrugated gap 30 extending over at least the full width of the roof tile 1, through which air enters and exits the space can flow between the top plate 2 and bottom plate 3.

The hollow space between the top plate 2 and the bottom plate 3 is only interrupted by an elevation 17 formed with the bottom plate 3, the top surface 18 of which (see also figure 3) can serve as support for the top plate 2. In cooperation with the strength proprietary -shelves as a result of the corrugated profile of the top plate 2, this guarantees the preservation of the hollow space between the top plate 2 and the bottom plate 3, while the flow-through profile, which is preferably at least as large as 70 cm2, is not significantly reduced . In addition, it is also possible to exchange (partial) flows of air in the sideways direction over most of the length of the roof tile. The flow-through profile is at least 70 cm2 in the lower opening 30, is increased at the location of the tray 19 to, for example, approximately 150 cm2, in order to then again be at least 70 cm2 at cross strip 24 and cross strip 27, as well as opening 31.

The substantially horizontally extending, folded side edge strips 15 and 16, respectively, can be received in the aforementioned downwardly opening channels in the side edge areas of the top plate 2.

At the top end of the bottom plate 3, these edge strips 15 and 16 are folded downwards by means of regions 28, to subsequently be bent again in a substantially horizontal direction in areas 37 connecting directly to the end edge 13 of the bottom plate 3. the edge areas 15 and 16 extend the areas 28, 37 in the same manner as the areas 4, 36 of the top plate 2.

After the top plate 2 and the bottom plate 3 have been formed, they can be simply attached to each other by means of glue, the glue being applied at the areas 28, 37 and 15, 16. Another possibility is the two plates 2 and 3 in those areas by heat welding or fusion. Yet another possibility is to form the roof tile by means of blow molding, whereby the roof tile is then formed as a whole. A further possibility is to form the top plate and bottom plate by the "twin sheet" method, whereby the two plates are formed simultaneously and oppositely by vacuum forming and fuse together along parts of their edges designated for that purpose. Also, the roof tile can be formed by an injection molding method.

The plastic roof tile 1 according to the invention is then ready to be included in a tiled roof construction, as is schematically shown in figure 5. It can be seen that the roof tile 1 with the area 35 rests on a contiguous ordinary roof tile 43a lying below and with the upper region of the upper surface located near the upper edge provides support to the underside of the adjacent ordinary roof tile 43b situated above it. The roof tile 1 is hereby kept against displacement along the roof, of which rafter 40 and cover 41 are shown, and also with its top surface at the correct height, so that the surfaces in which the tops of the waves of the tiles 1 and 43a, b are located are parallel to each other and the tile roof appearance will be as regular as possible. However, it is also possible to make the box 19 so deep that the vertical distance from the top surface of the roof tile 1 to the cover 41 corresponds to the required distance, and the strongly inclined wall 22 in cooperation with the end top edge of the ordinary roof tile. 43a to ensure that the roof tile 1 is held in the inclined direction.

It can be seen from figure 5 that through the hollow roof tile 1 according to the invention an air flow from outside can occur to the space between the roof tiles and the roof covering 41, the air flow entering the bottom opening 30 in the direction A1, then in a space suddenly created by wall 22, formed by the tray 19, ends up there and gives water particles and dirt particles the opportunity to settle on the bottom of the tray 19 as a result of delay phenomena of the air flow. The airflow continues in the direction A3 to exit via a kinked path in the direction A2 through the top opening 31. This top opening 31 is due to the kink shape, which shape is achieved because, as shown in Figure 2 the top edge 5 of the top plate 2 in one plane, which is parallel to the top plate 2, is located with the edge 26 of the step, close to the cover 41, so that the flow A2 can be more effective. The effectiveness of the inflowing air is further enhanced by the reduced outflow of air in the A2 direction caused by the neck realized relative to the edge 26 of the tread 31 reduced. Reversed flow is also possible, according to directions B1, B3 and B2, from the space under the roof tiles to the space outside the roof.

Figures 6 and 7 show a roof tile 101, which substantially corresponds to the roof tile 1 shown in Figures 1-5, but is provided with a roof lead-through for connection to a sewer release pipe or a mechanical ventilation pipe. Corresponding parts are indicated by corresponding reference numerals, increased by 100. The difference with the roof tile 1 is formed by the fact that the top opening 31 is no longer present: there is an end wall 152 formed with the bottom plate 3 therein. The top edge 113 thus runs completely straight, whereby the contiguous area, corresponding to area 37 of roof tile 1, may optionally be one continuous straight continuous strip to form a continuous bearing surface for the edge area of top plate 102 corresponding to edge area 36 of roof tile 1. Note that the top plate 102 can be identical to the top plate 2, and so that for the changing design of the roof tile 101 relative to the roof tile 1, only the bottom plate needs to be changed.

The bottom surface of the bottom plate 103 is interrupted to form a circular opening 150, which is delimited by a pipe stub 151, which is co-formed with the bottom plate 103. The pipe stub 151 is configured to form a roof passage for, for example, a mechanical ventilation system.

Figure 7 shows the situation in which the roof tile 101 can be accommodated in a tile roof, wherein the tile slat 142 'at the location of the pipe stub 151 is interrupted. In the adjoining areas, the step 124, 125 also formed in the bottom plate 103 forms for the roof tile 101 on the adjacent parts of the tile batten 142 'so that a stable position of the roof tile 101 is ensured.

When the roof tile 101 is used for venting in connection with sewer relaxation, air may enter in the direction C1, lose its water and debris in the tray 119 and flow in the direction C3, and then flow further in the direction C2 to conduit connected to pipe stub 151.

In a mechanical exhaust system, air may flow in the direction D1 from the mechanical ventilation pipe through the pipe stub 151, continue to flow in the direction D3 and finally exit outward in the direction D1. The chamber 119 hereby ensures that the air flow entering through the pipe stub 151 can only be influenced to a small extent by wind attacks in which air is pushed up in the direction Cl.

It will be seen that the roof tile according to the invention can easily be fitted into a roof tile system and, at least in the embodiment of figures 1-5, can be treated in the same way as the other ordinary roof tiles, without special provisions being required for this. Moreover, the roof tile according to the invention takes up little space. The versatility of the roof tile according to the invention is guaranteed because the construction can be shielded from the desired ventilation effect by simply adjusting the bottom plate.

Claims (15)

A plastic roof tile, comprising a top plate and a bottom plate, which are spaced apart to define a cavity closed in lateral directions therebetween, with a bottom opening provided in the end bottom edge of the tile for passage of air to and from the hollow space and discharge of moisture from the hollow space, and with an upper opening, which is at least partly provided in the bottom plate, for passage of air to and from the hollow space from respectively into the use situation of the roof tile spaces below the roof tile, wherein the bottom plate is designed such that an expansion chamber is formed in the hollow space for air entering via the bottom opening. Roof tile according to claim 1, wherein the bottom plate in a part thereof, which is spaced from the bottom opening and the top opening, forms a tray defined by a lowered bottom, and the top plate extends in the longitudinal direction of the roof tile. Roof tile according to claim 1 or 2, wherein the expansion chamber also forms an enlargement of the flow section relative to the top opening. Roof tile according to any one of the preceding claims, wherein the hollow space extends over at least substantially the full width of the tile. Roof tile according to any one of the preceding claims, wherein the hollow space extends at least in a continuous manner from one longitudinal side to the other longitudinal side of the roof tile. Roof tile according to any of the preceding claims, wherein the bottom opening extends over at least substantially the full width of the roof tile. Roof tile according to any one of the preceding claims, wherein the top opening is arranged in the end top edge of the tile. Roof tile according to claim 7, wherein the top opening extends over at least substantially the full width of the tile. Roof tile according to any one of the preceding claims, wherein the top opening is arranged in the bottom plate, above the part thereof which forms the bottom of the expansion chamber. Roof tile according to claim 9, wherein the top opening is defined by a downwardly projecting pipe stub. Roof tile according to any one of the preceding claims, wherein the bottom plate is step-shaped near the top edge of the roof tile to define bearing surfaces for support on a tile batten. Roof tile according to any one of the claims, wherein the top end edge of the top plate is substantially straight and preferably the top plate has a transversely corrugated course. Roof tile according to claims 11 and 12, wherein the upper end edge of the top plate is flush with the edge of the step, which surface is substantially parallel to the main surface of the roof tile. Roof tile according to any of the preceding claims, formed by blow molding. Roof tile according to any one of claims 1-14, formed by "twin sheeting", wherein the top plate and bottom plate are simultaneously formed by vacuum forming opposite each other and subsequently fused with their edges together.