WO2010089359A1 - Feed-through of tubular elements through flat building constructions - Google Patents

Abstract

The invention relates to a feed-through (10) of tubular elements (20) through flat building constructions, such as room ceilings and roofs, having a base element (11), at least one intermediate piece (13) and an end piece (14) having a common axis (A), wherein the base element (11) has an upper bearing surface (111) and the at least one intermediate piece (13) has a lower bearing surface (131) and an upper bearing surface (132), wherein the lower bearing surface (131) of the intermediate piece (13) is arranged in a rotating fashion on the upper bearing surface (111) of the base element (11), the end piece (14) has a lower bearing surface (141) that is arranged in a rotating fashion on the upper bearing surface (132) of the at least one intermediate piece (13) and the lower bearing surface (131) of the at least one intermediate piece (13) is inclined under a first angle (a13) to the upper bearing surface (132) of the at least one intermediate piece (13) and the lower bearing surface (141) of the end piece (14) intersects the axis (A) under a second angle (a14) not equal to 90°.

Description

 Passage of tubular elements through flat building constructions

The invention relates to a realization of tubular elements by flat building structures, such as ceilings and roofs, with a base member, at least one intermediate piece and an end piece, which have a common axis, wherein the base member has an upper support surface and the at least one intermediate piece a lower support surface and an upper support surface, the lower support surface of the intermediate member being rotatably disposed on the upper support surface of the base member, the end member having a lower support surface rotatably disposed on the upper support surface of the intermediate member, and the lower support surface of the intermediate member at a first angle is inclined to the upper bearing surface of the intermediate piece.

Bushings are devices by means of which linear elements, such as rods, ventilation pipes, chimney pipes, light pipes, antennas and other, in particular, pipe-like constructions, are passed through surfaces, for example ramps, walls, ceilings or roofs, in a normal or inclined manner. In particular, in the case of inclined roofs, roof ducts specially adapted to the particular roof pitch and the elements to be passed are generally produced for this purpose. These are each individual pieces, which are therefore also correspondingly expensive in their production. Such a construction is shown for example in US 7,114,301 B2, wherein a base member is provided with a frusto-conical attachment whose base is adapted to the roof pitch, while the upper bearing surface of the attachment is carried out substantially horizontally.

Therefore, solutions have been sought that allow the use of a larger number produced implementation for different areas. EP 0 992 638 A1 describes a roof penetration through the apex area of a dome-shaped dome of a roof covering, which has a tilt-adjustable, through the apex area of the dome led roof vent pipe, wherein the roof vent pipe is connected to a form-fitting designed to Dom and resting on the outside of the dome hood part , A disadvantage of this construction is that due to the given geometry of the implementation of the inclination angle can be adapted only in one plane and for the particular case, a separate adapted to the cathedral molding must be made. A similar implementation can also be found in EP 0 370 074 B1. be men. Bushings of the type mentioned above with a base element, at least one intermediate piece and an end piece are also described in US 686,323 and US 1,693,410.

It is therefore an object of the invention to provide an implementation that eliminates the above-mentioned disadvantages of the prior art and allows individual adaptation to different inclinations.

This object is achieved by an implementation of the type mentioned above in that the lower support surface of the tail intersects the axis at a second angle not equal to 90 °. By in the simplest embodiment of the invention, three-piece construction, the implementation of the invention can be continuously adapted to all kinds of inclined surfaces, especially roof pitches, with the rotatability of the spacer and tail in conjunction with the inclination of the spacer and tail to the base surface a precise alignment of a through the implementation passed element, such as an exhaust pipe or an antenna is made possible. By rotating the individual elements, the individual parts of the roof duct according to the invention are arranged to each other such that a common axis, which is usually aligned vertically, is obtained. In the context of this application, "end piece" is understood to mean that element which is arranged furthest away from the base element within the roof penetration and whose rotation has an influence on the alignment of the common axis. Any end pieces of the implementation, which may be rotated, but do not affect the orientation of the roof penetration, for example, annular elements with parallel upper and lower edge or dome-shaped end elements and the like, do not fall in this sense under the term "tail".

The adaptation is improved in a preferred embodiment of the invention in particular by the fact that the at least one intermediate piece is rotatable about a first axis of rotation perpendicular to the upper support surface of the base element and the end piece about a second axis of rotation normally on the upper support surface of the intermediate piece. Depending on requirements, two different variants of this three-level positioning result here: In a first variant, the first axis of rotation runs parallel to the (roof) plane, whereby it has been found that it is more suitable for large tube cross-sections of 100 mm to 800 mm. In the second variant, the first plane of rotation is not parallel, but inclined at an acute angle to or from the fall line. So even this angle takes over a proportion of the roof pitch. This is where issued that this design is more suitable for smaller pipe cross-sections of 20 mm to 100 mm.

A further increase in the accuracy of fit is achieved if the at least one intermediate piece and the end piece are substantially continuously rotatable.

Preferably, in a further embodiment of the invention, the end piece on a guide for receiving the substantially tubular element, wherein the normal on the axis of the guide, the lower support surface of the tail intersects at a second angle not equal to 90 °. The guide fixes the tube-like element within the passage and can also act as a seal at the same time.

In order to facilitate the installation of the implementation of the invention in existing roofs, the base member in a first embodiment of the invention has a substantially plate-shaped base body, which forms the plane of the first bearing surface. This plate-shaped base body is inserted for example as a so-called connection plate in the roof, wherein the lower support edge of the at least one intermediate piece is rotatably arranged on the plate-shaped base body.

Alternatively, it is provided in a further embodiment, that the base member has a substantially plate-shaped base body with an essay whose upper edge forms the plane of the upper support surface, wherein preferably the upper support surface of the essay intersects the plane of the plate-shaped base body at a third angle. Advantageously, in this case the article is made in one piece with the base plate in order to reduce the number of elements of the implementation of the invention.

The two variants of the bushings according to the invention described above are created by the shape of the base element and the position of its bearing surface to the base element. Thus, the advantages of both designs can be exploited for the particular application. Both constructions can be used optimally at inclinations of 0 ° - 50 °. With the same construction, but with a different angle distribution, adjustments up to 70 ° are also possible. Thus, depending on the design of a variety of surfaces with different inclination, pipe cross-sectional sizes, tightness requirement and Modularitätsvariabilität a suitable implementation can be provided.

The implementation of the invention has been found to be particularly suitable for the installation of pipes, in particular ventilation pipes with diameters of 20 mm to 800 mm. The invention is explained in more detail below with reference to non-limiting embodiments with associated figures. Show in it

Figure 1 is an exploded perspective view of a first variant of the implementation of the invention, wherein the first axis of rotation is parallel to a roof plane.

FIGS. 2a to 2c show three different installation positions in a schematic, sectional view without a built-in element;

FIGS. 3a to 3c show three different installation positions of a further embodiment with a built-in element in a view which corresponds to the principle of FIGS. 2a to 2c;

FIGS. 4a to 4c show three different mounting positions of a further embodiment of the invention in an axonometric view without a built-in element;

FIGS. 5a to 5c show three different schematic mounting positions of the passage from FIGS. 4a to 4c in a sectional view;

6a to 6c show three different schematic mounting positions of a further embodiment of the invention in a perspective view without a built-in element;

Fig. 7 shows an application of a further embodiment of the invention in a sectional view, which consists of an outer and an inner roof duct;

8a and 8b show an application example with two different roof inclinations in a sectional view;

9 is a schematic representation of possible settings of the implementation according to the invention by turning the individual elements;

10a and Fig. 10b two application examples of a further embodiment of the invention in a sectional view.

As shown in FIG. 1, the device 10 according to the invention has a base element 11 designed as a connection plate 112, which can be integrated in a roof in a manner known per se. In the following, a base element 11 with a substantially plate-shaped main body 112 is always referred to as "connection plate 112". The base member 11 has an opening 12 with circular cross section through which an element 20, for example, a vent tube can be passed. An intermediate piece 13 is rotatably mounted (double arrow) on the opening 12 of this connection plate 112, wherein the connection plate 112 has an upper bearing surface 111 extending around the opening 12. The intermediate piece 13 has a substantially frusto-conical shape, wherein a lower bearing surface 131 of the intermediate piece 13 is supported on the upper bearing surface 111 of the base member 11, while an upper bearing surface 132 of the intermediate piece 13 to the lower bearing surfaces 131 of the intermediate piece 13 at an angle αl3 (Fig 2c) is inclined.

The upper support surface 132 of the intermediate piece 13 forms a support surface for a likewise substantially frusto-conical end piece 14, which in turn is arranged with its lower support surface 141 on the upper support surface 132 of the intermediate piece 13, wherein the end piece 14 has an upper end surface 142, which also under a second angle αl4 (Fig. 2c) is inclined to the lower support surface 141 of the end piece 14. The inclination of the upper bearing or end surfaces 132, 142 to the respective lower bearing surfaces 131, 141 in this embodiment of the roof duct 10, for example, each 25 °.

Figures 2a to 2c and 3a to 3c show the adaptation of the implementation of the invention 10 to different roof pitches, each of the upper end surface 142 of the tail 14 is aligned horizontally, ie parallel to the base of the building. In Fig. 2a and 3a, the installation of the bushing 10 in a flat roof, ie in a roof without roof pitch, shown, wherein the intermediate piece 13 along a first plane of rotation Dl corresponding to that level in which the lower support surface 131 of the intermediate piece 13th and the upper bearing surface 111 of the base member 11 touch each other, is rotatable. Regardless, the end piece 14 is also rotatable along a second plane of rotation D2 passing through the plane in which the upper bearing surface 132 of the intermediate piece 13 and the lower bearing surface 141 of the end piece 14 contact each other. Through these two planes of rotation, a continuous adjustment of the feedthrough 10 according to the invention to the respective roof inclination is made possible.

In the configurations shown in FIGS. 2 b and 3 b, the roof has an inclination δ of approximately 35 °, whereby the horizontal alignment of the upper end surface 142 can again be achieved by suitable rotation of the intermediate piece 13 and end piece 14 along the two planes of rotation D 1, D 2 the end piece 14 and thus a vertical alignment of the arranged in the passage 10 element 20 is achieved. In the application shown in Figures 2c and 3c, the roof pitch δ is about 50 °.

In the embodiment of the bushing 10 according to the invention shown in FIGS. 4a to 4c and 5a to 5c, the base element 11 has an attachment 113 projecting from the connection plate 112, the upper support surface 111 of which is inclined at an angle all the way to the plane of the connection plate 112 the support surface for the lower support surface 131 of the intermediate piece 13 and thus simultaneously forms the first plane of rotation Dl for the intermediate piece 13. In the figures 5a to 5c, the roof in turn has different inclinations δ, for example, 10 °, 15 ° and 40 °, which in turn by suitable rotation of spacer 13 and tail 14 a substantially horizontal orientation of the upper end surface 142 of the tail 14 is achieved ,

In a further variant of the bushing 10 according to the invention shown in FIGS. 6a to 6c, the intermediate piece 13 and the end piece 14 are likewise each in the form of an obliquely cut circular truncated cone, but with the respective upper bearing or closing surfaces 132, 142 of the intermediate piece 13 or of the end piece 14, in contrast to the embodiments described above, do not leak into an acute angle with the respective lower bearing surfaces 131, 141 of the intermediate piece 13 or of the end piece 14. Of course, it may also be provided that, for example, the intermediate piece 13 has an upper bearing surface 132 which almost touches the lower bearing surface 131, while at the end piece 14, the upper end surface 142 ends spaced from the lower bearing surface 141 (see in particular Figures 3a to 3c).

FIG. 7 shows the installation of the feedthrough 10 according to the invention into an inclined roof 30, an insulation made of two different materials 41, 42 being arranged between the feedthrough 10 and the tubular element 20. The tubular element 20 is in this case fixed in a guide 143, which at the same time serves to seal the passage 10, for example, against the ingress of rainwater. As can be clearly seen in the figure, the two planes of rotation Dl, D2 are inclined at two angles αl3, αl4 different from one another relative to the axis A. The intermediate piece 13 is in this case rotatable about a normal to the upper support surface 111 of the base member 11 normal rotation axis dl and the end piece 14 about a normal to the upper support surface 111 of the intermediate piece 13 normal rotation axis d2.

In Figs. 8a and 8b, another rain resistant embodiment of the invention is shown, also installed in two roofs with different inclinations is. In this case, the base member 11 also has an integrally formed with the attachment plate 112, which is designed as a roof tile essay 113, while the end piece 14, a tubular element 21 which projects through the passage 10 has. End piece 14 and tube member 21 are also preferably made in one piece. Between the attachment 113 and the end piece 14, an intermediate piece 13 is again arranged so that again two planes of rotation Dl, D2 are obtained, along which intermediate piece 13 and end piece 14 are continuously turned until the desired adaptation to the respective roof pitch is obtained.

As shown in FIG. 9, the end surface 142 of the end piece 14 does not necessarily have to be horizontally aligned. Transferred to a Cartesian coordinate system with the axes x, y, the axis A in the horizontal alignment of the end face 142 of the tail 14 to the value y = 0, falls, ie with the y-axis of the coordinate system together. By rotating the intermediate element 13 and the end piece 14, however, the alignment of the axis A can be made to another point in special cases, but this point must be due to the geometry of the implementation 10 within a spherical sector 50.

FIGS. 10a and 10b show another bushing 10 similar to that of FIG. 7, installed in roofs 30 with different inclinations, for example 20 ° and 50 °, respectively.

It is understood that the embodiments described above are not to be considered as limiting. Essential for the implementation of the invention is that both an intermediate piece is rotatably mounted on a base member, and further arranged on the intermediate piece tail independently of the twisting availability of the intermediate piece is in turn rotatable. The bushing may be made of any suitable material, such as metal or plastic. Depending on the tightness requirement, the implementation of the invention is windproof by means of sealing elements and / or rainproof executed by means of drip rings to seal them, for example, against the roof in a known per se. Thus, for example, in Fig. 7, the outer shell rainproof and the inner shell made windproof. Likewise, it may be provided that not only an intermediate piece, but for example, two, three or more intermediate pieces are provided in order to allow optimum adaptation of the implementation of the invention to the respective roof pitch.

Claims

PATENT CLAIMS 1. passage (10) of tubular elements (20) through flat building structures, such as ceilings and roofs, with a base element (11), at least one intermediate piece (13) and an end piece (14), which has a common axis (A) have, wherein the base member (11) an upper support surface (111) and the at least one intermediate piece (13) a lower support surface (131) and an upper support surface (132), wherein the lower support surface (131) of the intermediate piece (13) the upper support surface (111) of the base member (11) is rotatably arranged, the end piece (14) has a lower support surface (141) rotatably disposed on the upper support surface (132) of the at least one intermediate piece (13), and the lower Support surface (131) of the at least one intermediate piece (13) at a first angle (αl3) to the upper support surface (132) of the at least one intermediate piece (13) is inclined, characterized gekennzeich net, that the lower bearing surface (141) of the end piece (14) intersects the axis (A) at a second angle (αl4) not equal to 90 °. 2. bushing (10) according to claim 1, characterized in that the at least one intermediate piece (13) about a normal on the upper bearing surface (111) of the base member (11) stationary first axis of rotation (dl) and the end piece (14) around a normal to the upper support surface (132) of the intermediate piece (13) standing second axis of rotation (d2) is rotatable. 3. bushing (10) according to claim 1 or 2, characterized in that the at least one intermediate piece (13) and the end piece (14) are continuously rotatable. 4. bushing (10) according to one of claims 1 to 3, characterized in that the end piece (14) has a guide (143) for receiving a substantially tubular element (20), wherein the normal to the axis (A) of Guide (143), the lower support surface (141) of the end piece (14) at a second angle (αl4) not equal to 90 ° intersects. 5. bushing (10) according to one of claims 1 to 4, characterized in that the base element (11) has a substantially plate-shaped base body (112) which forms the plane of the upper bearing surface (111). 6. bushing (10) according to any one of claims 1 to 4, characterized in that the base element (11) has a substantially plate-shaped base body (112) with an attachment (113) whose upper edge of the plane of the upper support surface (111 ). 7. bushing (10) according to claim 6, characterized in that the upper bearing surface (111) of the attachment (113) intersects the plane of the plate-shaped base body (112) at a third angle (all). 8. bushing (10) according to any one of claims 1 to 8, characterized in that the base element (11) has a connection plate (112) for installation in inclined surfaces such as roof or ceiling constructions with an inclination of 0 ° - 70 ° serves. 2010 02 05 Ha