SE515183C2 - Takventilationsdon - Google Patents

Description

25 30 35 40 siš 183 2 with the hinge axis of the ventilation pipe, that the locking connecting elements are fi-resilient and that the longitudinal axis of the connection socket runs at approximately a right angle to the plane of the base plate.

The ceiling ventilation device according to the invention mainly consists of only two components, namely the base plate and the ventilation pipe. After the base plate has been mounted, the ventilation pipe is threaded over the cap. After the ventilation pipe has been directed vertically, it is locked by being pressed in so that the locking connecting elements fall into locking. The roof ventilation device can absorb high torques thanks to the fact that the first locking connection elements have a sawtooth-shaped profile in the longitudinal section. The free distance between two roof battens is utilized by a connecting socket with a large diameter in that the longitudinal axis of the connecting socket runs at approximately a right angle to the plane of the base plate.

An embodiment which allows a particularly large area for the mouth opening of the cap consists in that the first locking connecting elements are arranged in approximately the same horizontal plane as the hinge axis, at right angles thereto, on the outside of the cap and on the inside of the bowl.

In this way, without further shape details, the greatest possible distance is obtained between the first locking connecting elements and the hinge shaft. This minimizes the forces that need to be transmitted to absorb the torque when the ventilation pipe is loaded with snow from the ridge side.

The pivotability of the ventilation pipe relative to the base plate can be achieved in that the first barrier connecting elements have at least on the outside of the cap facing the eaves a stepped barrier recess which at least one barrier lug arranged on the inside of the bowl can fall into. A torque acting on the ventilation pipe is diverted without transverse forces by the surfaces corresponding to the steps of the steps in the locking recesses and on the locking lugs emanating from the hinge shaft and containing it. A further stabilization can be obtained by the crane transfer plane seen in the longitudinal section having a undercut in the same way as the saw teeth on a circular saw blade. Thanks to the sawtooth or step-shaped profiling of the first locking elements, the ventilation pipe can be switched on during installation in a position sloping away from the roof ridge with the locking elements joined together. Then the ventilation pipe is swung in the direction of the ridge until its longitudinal axis points vertically. It has been found that blocking steps with a distance corresponding to 2.5 ° are sufficient in that a deviation of at most 1.25 ° from the vertical plane is not visible to the naked eye. A finer division would mean that the power-transmitting surfaces would be smaller.

According to one embodiment, a large pivot angle area for the ventilation pipe relative to the base plate is achieved by arranging two locking lugs diametrically opposite on the inside of the bowl in different transverse planes relative to the longitudinal axis of the ventilation pipe. In this case, the ventilation pipe can be inserted into the other locking elements in two different positions by rotating 180 ° about its longitudinal axis. The open end of the Ventilation tube bowl is in this case asymmetrically designed. Seen from the hinge axis, one half is shorter than the other. For weaker roof slopes, put on the ventilation pipe with the longer half facing the ridge, for stronger roof slopes with the shorter half facing the ridge. In this way, one and the same ventilation pipe can be used, for example, for roof slopes between 13 ° and 34 ° in one position and roof slopes between 34 ° and 55 ° in the other position. If the division of the steps 3 in the first blocking elements is 2.5 °, it is sufficient in this case to arrange 8 blocking steps.

An embodiment which provides particularly simple and stable locking connecting elements consists in that other locking connecting elements are also arranged concentrically with the hinge axis of the ventilation pipe.

The other barrier connecting elements are preferably designed as projections emanating from the cap, surrounding the hinge shaft and as depressions arranged on the inside of the bowl of the ventilation pipe in which the projections can fall into a barrier. The design can of course also be the other way around.

The above-described arrangement of projections on the outside of the cap has the advantage that the depressions on the inside of the bowl can be designed as openings through to the outside.

In this case, during assembly, it is possible to determine by direct observation that the other locking connecting elements have completely collapsed.

The base plate does not have to consist of delar your parts if it corresponds to a roof tile in terms of its size and the profile of its top outside the socket. During installation, an existing roof tile is removed at the desired location and replaced with the base plate.

In the case of roofs with fabric underlays, the connecting piece is preferably designed as a separate part, which is attached to the base plate. In this case, a hole can be cut in the fabric for the passage of the connecting piece before the base plate is applied. If necessary, a special ring with an inner diameter adapted to the outer diameter of the connecting piece can be mounted tightly in the fabric.

An embodiment which allows the mounting on a covered roof in its entirety to take place from the outside consists in that the connecting piece at its upper end has a protruding collar, which can lie against the mouth edge of the base plate cap. The connection piece can be locked to the connection piece with additional locking elements.

Especially in cold weather, condensation from moist exhaust air can form on the inside of the ventilation pipe. This liquid is not led back into the connection piece but flows along the outside of the cap to the outside of the base plate if drains for liquid that run down the inside of the ventilation pipe are arranged in the bowl or cap. This is especially important if the ceiling ventilation device is used to discharge room air from an exhaust air ventilation system.

It has been found that in rainy weather with strong winds, water can be driven upwards along the outside of the ventilation pipe to its mouth. Water of this kind can be prevented from penetrating into the ventilation pipe by arranging at least one circumferential outward fl end at the upper mouth of the ventilation pipe. Thereby the water is led from the wind to the reading side, where it flows down along the outside of the ventilation pipe.

Rain is prevented from penetrating into the upper mouth of the ventilation pipe because the roof ventilation device has a weather hood, which can be fitted to the upper mouth of the ventilation pipe.

In this case, a roof ventilation device that can be used for roof slopes between 13 and 55 ° consists of only four components, namely the base plate, the connection piece, the ventilation pipe and the weather hood.

The invention will now be explained in more detail with reference to an exemplary embodiment shown in the drawing. Fig. 1 shows a roof ventilation device according to the invention in a perspective view, Fig. 2 the roof ventilation device according to fi g 1 in cross section, Fig. 3 a section of fi g 2 in the vestibule, 15 25 g 4 the roof ventilation device according to fi g 1 i longitudinal section and Fig. 5 a section from fi g 4 in magnification.

Fig. 1 shows a roof ventilation device 10 according to the invention in perspective view. The roof ventilation device 10 has a base plate 12 with a socket 14 on its upper side, a ventilation pipe 16 with a weather hood 18 and a tubular connection socket 20. The base plate 12 has the same dimensions as a roof tile and its upper side outside the socket 14 has the same profile as a roof tile. The nozzle 14 tapers like a spherical cap 22 in the direction of its open mouth. The ventilation pipe 16 widens at its lower end like a spherical bowl 24, so that the bowl 24 can be threaded over the cap 22 and form a joint with the aid of which the ventilation pipe 16 can always be directed vertically on a sloping roof. Resilient locking connecting elements 26, 28 with which the ventilation pipe 16 can be locked to the base plate 12 are arranged in the hinge area.

Fig. 2 shows the ceiling ventilation device 10 according to Fig. 1 in cross section, while Fig. 3 shows an enlarged section of Fig. 2. In the area around the hinge shaft 30, the ventilation pipe 16 is connected to other barrier connecting elements, which are arranged mirror-symmetrically on both sides. In Fig. 3, the other barrier connecting elements 26 located to the right of Fig. 2 are shown in magnification. They are arranged concentrically relative to the hinge shaft 30 of the ventilation pipe 16 and have a projection 32 emanating from the cap 22, which surrounds the hinge shaft 30 concentrically and is designed as a hollow pin. A recess 34, in which the projection 32 can fall in lockingly, is arranged on the inside of the bowl 24 of the ventilation pipe 16. The recess 34 on the inside of the bowl 24 is designed as an opening through to the outside.

The connecting piece 20 is designed as a separate part and has at its upper end a collar-shaped part 36, which abuts against the mouth edge of the base plate 12 of the base plate 12 and surrounds the mouth edge in a hook-shaped manner. An upwardly directed strip 38 is arranged on the upper side of the collar-shaped part 36 for discharging liquid running down along the inside of the ventilation pipe 16 to the outside of the cap 22 in discharges 40 arranged on the inside of the bowl 22, which are arranged in connection with the locking elements 26. The only lugs 42 are arranged below the collar-shaped part 36 and fall in reading into locking depressions 44 emanating from the inside of the stub 14 when the collar-shaped part 36 abuts tightly against the mouth edge of the cap 22, whereby the connecting piece 20 is locked to the base plate 12.

In fi g 4 the roof ventilation device according to fi g 1 is shown in longitudinal section, while fi g 5 shows an enlarged section from fi g 4. From fi g 4 it appears that the longitudinal axis 46 of the connecting piece 20 is approximately perpendicular to the plane of the base plate 12. Since the base plate 12 replaces a roof tile in the roofing, the base plate will be slightly fl thicker than the average roof slope due to the roof tile-like overlap of the roof tiles. In order for the longitudinal axis 46 of the connecting piece 20 to form a right angle to the roof slope, the longitudinal axis of the connecting piece slopes with the overlapping inclination angle 4.5 ° relative to a line perpendicular to the plane of the base plate 12. The angle between the plane of the base plate 12 and the longitudinal axis 46 of the connecting piece 20 is therefore 85.5 ° on the ridge side.

The first locking connecting elements 28 appear from fi g 4 and from the magnification in fi g 5.

They are arranged at a radial distance from the hinge shaft 30 and are located approximately in the horizontal plane of the hinge shaft 1015. Furthermore, they have a sawtooth-shaped profile in the longitudinal section. Several step-shaped locking recesses 48 are arranged on the outside of the cap 22 facing the eaves. A locking lug 50 arranged on the inside of the bowl 24 can be brought into engagement with the locking recesses 48. A first locking lug 54 is diametrically opposed relative to the locking lug 50 on the inside of the bowl 24 and is located in a transverse plane higher with respect to the longitudinal axis 56 of the ventilation pipe 16.

Two outward-facing, circumferential 57 ends 57, 58 are arranged at the upper mouth of the ventilation pipe 16. Furthermore, annular, lattice-like filling bodies 60 are arranged in the upper mouth portion of the ventilation pipe 16 in order to provide a suction effect together with the weather hood 18.

Claims (12)

10 15 20 25 30 35 40 515 183 6 Patent claims Roof ventilation device (10) for supply and exhaust air ventilation of a pipeline in a building, with at least one ventilation pipe (16), a base plate (12), which can be built into a roof covering, and a tubular connection socket (20), wherein the ventilation pipe (16) so that its longitudinal axis (56) can be directed vertically on a sloping roof can be pivotally connected to the base plate (12) in a joint and the base plate (12) to form the joint has a stub (14) located on its upper side, which is tapered in the form of a spherical cap (22) in the direction of the upwardly open orifice, and the ventilation tube (16) at its lower end is widened in the form of a spherical cup (24) in such a way that the bowl (24) can be threaded over the cap (22) and is pivoted about the hinge shaft (30), and wherein the first locking connecting elements (28) are arranged at a radial distance from the hinge shaft (30) and can lock the ventilation pipe (16) to the base plate (12), characterized in that they the first locking connecting elements (28) are arranged at least on the outside of the cap (22) facing the eaves and on the inside of the bowl (24) and has a longitudinally serrated contour in the longitudinal section, that other locking connecting elements (26) are arranged concentrically with the hinge shaft (30) of the ventilation pipe (16), ) are resiliently designed and that the longitudinal axis (46) of the connecting piece (20) runs at approximately a right angle to the plane of the base plate (12). Ceiling ventilation device according to Claim 1, characterized in that the first locking connecting elements (28) are arranged in approximately the same horizontal plane as the hinge axis (30), at right angles thereto. Ceiling ventilation device according to Claim 2, characterized in that the first locking connecting elements (28) have several stepped locking recesses (48) in which at least one locking lug arranged on the inside of the bowl (24) can (50, 54) fall in, plane steps corresponding to the plane (52) of the locking recesses (48) and the locking lug (50, 54) emanate from the hinge shaft (30) and contain it. Ceiling ventilation device according to Claim 8, characterized in that two locking lugs (50, 54) are arranged diametrically opposite on the inside of the bowl (24) in different transverse planes relative to the longitudinal axis (56) of the ventilation pipe (16). Ceiling ventilation device according to one of the preceding claims, characterized in that the second locking connecting elements (26) are designed as projections (32) emanating from the cap (22) and surrounding the hinge axis (30) and as on the inside of the bowl (24) of the ventilation pipe (16). recesses (34) in which the projections (32) can fall into the barrier. Ceiling ventilation device according to Claim 5, characterized in that the depressions (34) on the inside of the bowl (24) are designed as openings through to the outside. Ceiling ventilation device according to one of the preceding claims, characterized in that the base plate (12) corresponds to a roof tile in terms of its size and the profile of its upper side outside the stub (14). Ceiling ventilation device according to one of the preceding claims, characterized in that the connecting piece (20) is designed as a separate part which can be fastened to the base plate (12). Ceiling ventilation device according to Claim 8, characterized in that the connecting piece (20) has at its upper end a projecting collar (36) which can lie against the mouth edge of the cap (22). Ceiling ventilation device according to one of the preceding claims, characterized in that conduits (40) for liquid flowing down the inside of the ventilation pipe (16) are arranged in the bowl (24) or the cap (22). Ceiling ventilation device according to one of the preceding claims, characterized in that at least one circumferential, outwardly directed ns end (57, 58) is arranged at the upper mouth of the ventilation pipe (16). Ceiling ventilation device according to one of the preceding claims, characterized in that it has a weather cap (18) which can be fitted to the upper mouth of the ventilation pipe (16).