AT502485B1 - Roof fan for draining condensation has a drain for perspiration water on a roof ventilator of a cover/coupling type with an adjustable-angle - Google Patents

Abstract

A duct (2.1) passes through a roof from below and terminates in a lower section of a space enclosed by a coupling (1.2). A connector surface (2.3) extends from a lower piece of the inside of the coupling's interior towards an outer surface of the duct. On the lowest lying contact area of the connector surface with the coupling surface, the coupling surface is pierced by an outlet opening (1.5).

Description

2 AT 502 485 B1

The invention relates to a ventilation device which is fastened to the roof surface and projects upward therefrom, which is typically used as an air connection for the sewage system in a building. DE 298 02 784 U1 describes a ventilation device protruding above the roof surface, according to which a pipe made of plastic leads from below through an opening through the roof tile. At the top of the roof tile, it is covered by the outlet pipe of a ceramic material projecting further beyond the roof surface. At the end face of the plastic pipe leading through the roof, the outlet pipe has a bore for discharging the condensate on the eaves side, that is to say in the fall line of the roof on the underside.

A disadvantage of this design is that the inclination of the outlet pipe can not be adapted to the roof pitch, and that a considerable part of the condensate does not flow from the designated outlet opening, but on the end face of the roof through the roof plastic pipe into the interior of the roof vent line , This is especially very much when, due to great cold in conjunction with snow, ice and alternating strong heating by the vent pipe, the bore for discharging the condensate is temporarily laid on the outside. 20 AT 412 793 B describes a roof ventilator, which also consists of plastic protruding over the roof surface. It consists of a roof plane penetrating the pipe, from a roof plate from which a dome with open top surface protrudes, and a hood arranged above, which rests with its lower edge on the outer surface of the dome, and with its upper edge in the further upward Outlet pipe 25 opens. The hood is pivotable on the dome around a horizontal, normal axis lying on the fall line of the roof, whereby the outlet pipe can be adjusted vertically regardless of the inclination of the roof surface. The pipe which penetrates the roof surface is connected at its upper end to the edge of the opening at the upper side of the dome. The hood surrounds this area while maintaining a gap through which condensate, which flows down from the outlet pipe, can flow to the outside of the dome, and thus to the top of the roof panel. A disadvantage of this design is that the pipe which penetrates the roof also extends a considerable distance beyond the roof surface, and that thus that condensate, which is reflected as a result of lower temperature in this longitudinal region on the inner surface of this tube, not to the outside 35 is discharged, but flows into the interior of the roof vent line.

DE 200 21 051 U1 also describes a dome and hood comprehensive inclination adjustable roof vent made of plastic. In the process, the pipe penetrating the roof surface, from which condensate can only flow inwards, reaches even a considerable "piece beyond the top of the dome.

The object underlying the invention is to provide a tilt adjustable roof vent, according to the dome-hood design, in which compared to known devices of this kind, much less condensate, which is reflected on the 45 often forced inner surfaces of the roof vent, in the Interior of the leading to this roof vent from the inside building pipe drains.

The object is achieved in accordance with the features mentioned in the characterizing part of claim 1 in the following manner: 50

The roof surface from below piercing tube ends in the volume enclosed by the dome approximately in the plane of the roofing. A connecting surface extends from the lower part of the inside of the dome inwards to the outer surface of this tube. At the eaves-side edge region of this connection surface, the dome surface is pierced by an outlet opening.

Claims (9)

The invention will become more apparent with reference to the drawings: FIG. 1: shows a schematic diagram of the invention in a lateral sectional view. Fig. 2: shows the embodiment of Fig. 1, the pipe penetrating the roof surface and the connecting surface integrally adjoining thereto in a perspective view. According to Fig. 1, the dome 1.2 is integrally formed with the lying in the roof level roof panel 1.1 io. It bulges up from the level of the roof panel. It is provided with an upper opening 1.3, over which the - not shown here - hood part is slipped. The bushing 2.1 penetrates from the inside of the building, the level of the roofing and ends just above this in the bottom area of the enclosed by the dome 1.2 volume. The connection surface 2.3 is made in the example shown in one piece with the feedthrough tube 2.1. It extends from the outer circumferential surface of the feedthrough tube 2.1 to the lower edge region of the dome 1.2 and is there welded via a protruding welding surface 2.4 with a protruding from the roof plate 1.1 welding surface 1.4. Of course, other types of connections such as bonding, or screw using a sealing liner, etc. are conceivable. With proper preparation, welding is a very cost-effective, industrially applicable method, and it results in a very robust, secure-tight connection. The bushing 2.1 protrudes beyond the level of the roofing only with a very short length range 2.2, whereby only a very small portion of the inner surface area is exposed to the precipitation of condensate compared to the previously known construction methods. Condensate, which precipitates on the inside of the dome 1.2 and in a further 'consequence flows down, is collected at the upper side of the connection surface 2.3 and continues to flow to the eaves-side outlet opening 1.5 at the bottom of the dome 1.2. Through this opening 30 it reaches the outside of the roof panel 1.1 as intended. Also flows condensate, which is reflected at the leading beyond the dome part or parts of the roof duct, and flows from there into the interior of the dome, through this outlet opening 1.5. Due to the fact that the upper end face of the feedthrough tube 2.1 projects beyond the region of the connection surface 2.3 lying around the feedthrough tube, no condensate can flow into the feedthrough tube from the ridge-side region of the connection surface. Due to the fact that the eaves-side edge region of the upper end face of the feedthrough tube is 2.1 at a distance from the outlet opening 1.5 and above it, and in that the Ver connecting line between feedthrough 2.1 and 2.3 connecting surface is at a distance from the upper end face of the feedthrough tube, is buffer storage space for Gained condensate. This can be advantageous, for example, if temporarily more condensate accumulates than can flow out. This is e.g. then possible when dome 1.2 and roof plate 1.1 have cooled significantly below freezing point, and suddenly a lot of moist, warm air rises from the inside of the building. Temporarily condensate can then freeze at the opening 1.5 and narrow or close this. If there was no buffer storage space for condensate, this would drain through the bushing in the pipes in the building. 50 Patent claims: 1. Roof ventilator, which protrudes from a roof plane penetrating the pipe, from a roof plate from which a dome with open top surface on the roof surface, 55 and arranged above it, pivotally relative to the dome hood, characterized AT 502 485 B1 characterized in that the duct (2.1) penetrating the roof surface from below penetrates below the dome area in the volume enclosed by the dome (1.2), a connecting surface (2.3) between the lateral surface of the duct (2.1) on the one hand and the underside of the roof slab (1.1) or the non-5 deren surface area of the dome (1.2) on the other hand extends, and that over the connecting surface (2.3) lying surface of the dome (1.2) or the roof panel (1.1) close to the lowest point of the contact line with the connection surface (2.3) through an outlet opening (1.5) is broken io 2. Roof ventilator according to claim 1, characterized in that the upper "end of the feedthrough tube (2.1) is located in the bottom area of the dome (1.2). 3. roof ventilator according to claim 1 or 2, characterized in that the connecting surface (2.3) in the foot region of the dome (1.2) bears against this. 15 4. Roof ventilator according to one of claims 1 to 3, characterized in that the upper end face of the feedthrough tube (2.1) projects beyond the area lying around the feedthrough tube area of the connection area <2.3). 5. roof ventilator according to claim 4, characterized in that the connecting line between the feedthrough tube (2.1) and connecting surface (2.3) on the outer circumferential surface of the feedthrough tube (2.1) at a distance from the upper end face of the feedthrough tube (2.1). 6. Roof ventilator according to one of claims 1 to 5, characterized in that the lowest point of the upper end face of the feedthrough tube (2.1) is above the level of the outlet opening (1.5). 7. Roof ventilator according to claim 6, characterized in that the distance of the end face of the duct (2.1) from the outlet opening (1.5) is greater than the distance to the outlet opening (1.5) opposite the region of the dome (1.2). 8. Roof ventilator according to one of the preceding claims, characterized in that the outlet opening (1.5) is located on the eaves-side foot area of the dome (1.2). 35 9. Roof ventilator according to one of the preceding claims, characterized in that the feedthrough tube (2.1) and connecting surface (2.3) are a common part. 10. roof ventilator according to one of the preceding claims, characterized in that the 40 connecting surface (2.3) with the roof panel (1.1) or with the dome <1.2) is welded. For this purpose 2 sheets of drawings 45 50 55