EP0147502A1 - Roof with at least a movable roof part - Google Patents

Abstract

1. Roof, particularly as an assembly-set, with at least one moveable roof-part (4), consisting of two parallel metallic longitudinal girders (2, 3) having a rectangular cross-section, of at least one metallic inner frame (6) with inserted plates (7) covering at maximum approximately half the roof-area and being moveable between the longitudinal girders (2, 3) via rollers (15) on opposite guide-rails (12, 19), as well as of a supporting structure comprising the remaining roof-area having also inserted plates (10), wherein the one guide-rail (12) is L-shaped and attached to the vertical inner wall-surface (2a) of one of the longitudinal girders (2, 3), wherein the at least one inner frame (6) is mounted upon carriage-brackets (14, 18) having rollers (15), and wherein a U-shaped drainage channel (33) is attached to one of the longitudinal girders (3), comprising the features : a) the longitudinal girders (2, 3) are mounted on different levels, b) the one, L-shaped guide rail (12) is attached to the upper longitudinal girder (2), c) the U-shaped drainage channel (33, 49) is attached in a parallel manner to the lower longitudinal girder (3), d) supporting bridges (23, 53) are inserted into the drainage channel (33, 49) in a linked manner and with distances in between, e) at least one guide-rail (19) for the at least one moveable roof-part (4) and a supporting structure (63) for the remaining roof-structure are attached to the supporting bridges (23, 53) and optionally to the drainage channel (33, 49).

Description

The invention relates to a roof, preferably as a kit, with at least one movable roof part, consisting of two parallel metal longitudinal beams with a rectangular cross-section and at least one between the longitudinal beams by means of rollers on opposite running. rails that can be slid, a maximum of about half the roof area, comprising a metallic inner frame with inserted panels, as well as a supporting structure that forms the rest of the roof area with panels that are also inserted, the one running rail being L-shaped and fastened to the vertical inner wall surface of one side member and the at least one an inner frame is placed on the carriage holder, to which the rollers are attached, and wherein a U-shaped drainage channel is attached to one of the side members.

Such roofs are known in conservatories, courtyards, restaurants, etc. (DE-OS 33 08 285). The two longitudinal members are parts of a circumferential outer frame, which has a rectangular upright cross section and rests in a horizontal position on a substructure. Inside this outer frame, at least one inner frame that can be moved on rollers is arranged, the longitudinal axes of the frame profiles also lying in a horizontal plane. The slabs with a slope are inserted into this inner frame, and the purpose of the frame construction is to make the slope not visible from the outside. Despite the limited profile height, this is quite possible with conventional sunroofs because the gradient is a maximum of about 5%. Nevertheless, the frame construction shields a considerable part of the incident light, which was previously perceived as pleasant.

So-called solar add-ons for residential buildings have recently been propagated, which have the task of capturing as much of the solar energy as possible and passing it on to the interior of the immediately adjacent residential building. The effect of such a "passive system" is very remarkable despite the absence of technical devices such as solar collectors and heat pumps: the heating period in winter is shortened, and on many days in spring and autumn there is no need for artificial heating of the house.

An effective solar extension, however, requires a larger roof slope, which can be 30% and more, whereby shadowing effects due to the supporting structure, which usually consists of light metal profiles, must be largely avoided. This in turn leads to hot Sommerta ^g s to an undesirably high temperature load, so that cultivation solar care must be taken for proper ventilation possibility of. Just think of the strong heating of motor vehicles, which leads to unbearable temperature loads, particularly due to the extremely inclined windshield and rear windows. While the wind of the vehicle quickly provides cooling, this is naturally not possible with solar attachments.

Another problem is the need for roof drainage. While on the one hand the large sloping roof keeps the static load from snow within limits, the comparatively large slope creates high flow velocities, so that the rainwater sprays easily over insufficiently dimensioned drainage channels. A running down of the rain water on the vertical glass surfaces of the solar attachments is highly undesirable, so that a so-called "controlled drainage" must be provided by adequately dimensioned drainage channels to avoid this disadvantage.

Solar add-ons with controlled drainage and ventilation through pop-out skylights are known. However, these only open openings of relatively small cross-section, so that their effect is limited in strong sunlight.

It is also known to provide the roofs of solar attachments with a sliding element, which, however, can be moved in the direction of the slope. This has the disadvantage that d _'ie operation is significantly affected by gravity, which becomes particularly disturbing because of the great pitch of the roof.

The invention is therefore based on the object of specifying a design instruction for solar add-ons, in which, despite the large roof pitch and controlled drainage, it is possible to move roof parts transversely to the direction of the slope without requiring high profiles which hinder the solar radiation.

• a) die Längsträger auf unterschiedlichen Höhen angebracht sind,
• b) die e-ine, L-förmige Laufschiene an dem oberen Längsträger angebracht ist, und
• c) an dem unteren Längsträger parallel zu diesem die U-förmige Entwässerungsrinne befestigt ist, in die
• d) formschlüssig und in Abständen Tragbrücken eingesetzt sind, und daß
• e) an den Tragbrücken und gegebenenfalls an der Entwässerungsrinne mindestens eine Laufschiene für das mindestens eine verschiebbare Dachteil und eine Stützkonstruktion für die restliche Dachkonstruktion festigt sind.

The solution of the task is carried out according to the invention in the roofing described above in that

• a) the side members are attached at different heights,
• b) the e-in, L-shaped running rail is attached to the upper side member, and
• c) is attached to the lower longitudinal member parallel to this, the U-shaped drainage channel, in the
• d) form-fitting and spaced support bridges are used, and that
• e) at least one running rail for the at least one displaceable roof part and a supporting structure for the rest of the roof structure are fixed to the supporting bridges and, if appropriate, to the drainage channel.

The panels described above are glass panels, for example wire glass, transparent or translucent building panels or the like. A preferred type of plate is the so-called plastic web glass, in which two plane-parallel plates are connected to one another by a large number of parallel webs. These plates are transparent to solar radiation but prevent a considerable extent, the heat emission to the outside that might arise d _J rch convection and conduction. Such panels are even accessible, so that they are an ideal material for solar crops.

In the solution according to the invention, it is possible to arrange one, two or even more movable inner frames with the inserted panels despite the large sloping roof and to move them one above the other or in the horizontal direction, ie parallel to the longitudinal members. It is then only necessary to subdivide the entire roof area into a corresponding number of fields of the same size, with one of these fields generally being arranged in a fixed manner, while the other fields are movable and with the fixed field for Cover can be brought. In this way, a very large opening for ventilation purposes can be formed in the roof of the solar extension. It is also possible to make all fields movable, so that the package of fields pushed over one another can then be brought into any position so that the uncovered opening can also be located at any position, or else, for example, in the Fields in the middle, one above the other, each formed an opening.

The large roof slope described is made possible by attaching the longitudinal beams at different heights without the incidence of light being excessively obstructed. It will still have to be shown that some of the profiles of the inner frames lie to a certain extent in the shadow of the outer side member, so that these profile parts at least do not cast any additional shadows on the translucent plates.

By attaching the running rails parallel to the horizontal longitudinal beams, the moving roof parts are unaffected by gravity, so that the same speeds in both directions of movement are possible without special braking measures. The displacement is also possible without assistance from motor power, it being necessary to bear in mind that the dimensions of an inner frame transversely to the direction of displacement easily between Can be 3 and 4 m, so that the inner frame with the plates used have a considerable weight.

Finally, due to the structural union of the U-shaped drainage channels and the support bridges used at intervals, good controlled drainage is possible without rainwater running down the panes of the substructure.

The drainage channel with the supporting bridges is an essential, load-bearing element for the entire roof structure, without the dimensions having to go beyond the usual dimensions of the drainage channel. Running and mounting rails can be accommodated in a space-saving manner in the shadow of the outermost side member and / or in the shadow of the drainage channel, so that an additional shadow is very largely avoided. The structurally coordinated parts also enable easy assembly at the point of installation, whereby additional adaptation measures are also possible if necessary.

• I. Entweder sind auf die Tragbrücken die mindestens eine Laufschiene und eine Tragschiene für die restliche Dachkonstruktion aufgesetzt, wie dies Figur 1 zeigt, oder
• II. auf die Tragbrücken ist die Stützkonstruktion für die restliche Dachfläche aufgesetzt, während die Laufschiene seitlich innen an die Entwässerungsrinne aufgesetzt ist, wie dies die Figuren 10 und 11 zeigen.

Two main variants are possible: (

• I. Either the at least one running rail and one supporting rail for the rest of the roof structure are placed on the supporting bridges, as shown in FIG. 1, or
• II. The supporting structure for the remaining roof area is placed on the support bridges, while the running rail is placed laterally on the inside of the drainage channel, as shown in FIGS. 10 and 11.

It is particularly advantageous if the support bridges (based on their installation position) have two support feet reaching to the bottom of the drainage channel and a web connecting the support feet which extends over the clear interior of the drainage channel.

In connection with the measure of providing the drainage channel on the upper edges of its side walls with a rib overlapping the web and providing the ribs and the support bridge with mutually complementary projections and recesses, the drainage channel, the support bridges and the runner or mounting rails a compact but dimensionally stable composite is formed, which can be easily attached to or on the associated side member and in use a flawless, ie controlled drainage. Details are explained in more detail in the detailed description.

It is furthermore advantageous if joints made of extruded profiles with mutually complementary cylindrical surfaces are arranged between roof parts which are at an angle deviating from 90 degrees or 180 degrees to another roof part are designed so that on the one (first) extruded profile two mutually facing, coaxial cylindrical surfaces, on the other (second) extruded profile two mutually facing cylindrical surfaces are arranged and that the radii of the cylindrical surfaces are matched to one another such that the two extruded profiles can be inserted into one another in the axial direction with the formation of joint connections in pairs. This has the advantage that the inner frame can be installed with different slopes without this requiring special profiles for the rails in question.

Further advantageous embodiments of the subject matter of the invention emerge from the remaining subclaims; their advantageous effects are explained in more detail in the detailed description.

Two exemplary embodiments of the subject matter of the invention and their details are explained in more detail below with reference to FIGS. 1 to 18.

• Figur 1 einen Querschnitt senkrecht zu den Längsachsen der Längsträger durch eine vollständige Dachkonstruktion, bei der die Entwässerungsrinne zusammen mit den Tragbrücken und den Lauf- und Tragschienen innen und seitlich an den unteren Längsträger angesetzt ist,
• Figur 2 einen Querschnitt durch ein Profil für die Tragbrücken,
• Figuren 3 Querschnitte durch die Profile für die Lauf-und 4 und Tragschienen,
• Figur 5 einen Querschnitt durch ein Profil für die Entwässerungsrinne,
• Figur 6 einen Querschnitt durch ein Profil für die Laufwagenhalter, .
• Figur 7 einen Querschnitt durch ein Profil für eine L-förmige Lauf- oder Tragschiene,
• Figuren 8 Querschnitte durch Profile für Tragwinkel für und 9 die Abstützung der ortsfesten Innenrahmen,
• Figuren 10 zwei hintereinander liegende Querschnitte analog und ¹¹ dem linken Teil von Figur 1, jedoch mit dem Unterschied, daß die Entwässerungsrinne auf den unteren Längsträger aufgesetzt ist und daß die Laufschiene seitlich und innen an die Entwässerungsrinne angesetzt ist,
• Figuren 12 zwei hintereinander liegende Querschnitte analog und 13 dem rechten Teil von Figur 1, jedoch mit dem Unterschied, daß zwischen den schrägen Dachteilen und dem oberen Längsträger speziell ausgebildete Gelenke angeordnet sind,
• Figur 14 einen Querschnitt durch ein weiteres Profil für die Tragbrücken,
• Figur 15 einen Querschnitt durch ein weiteres Profil für die Entwässerungsrinne,
• Figuren 16 Querschnitte durch zwei zu einem Gelenk zusammen-und 17 setzbare Strangprofile, und
• Figur 18 eine perspektivische Darstellung eines Solar-Anbaus mit einer erfindungsgemäßen Oberdachung.

Show it:

• 1 shows a cross section perpendicular to the longitudinal axes of the side members through a complete roof construction, in which the drainage channel together with the support bridges and the running and support rails is attached to the inside and side of the lower side member,
• FIG. 2 shows a cross section through a profile for the support bridges,
• 3 cross sections through the profiles for the running and 4 and mounting rails,
• FIG. 5 shows a cross section through a profile for the drainage channel,
• 6 shows a cross section through a profile for the carriage holder,.
• FIG. 7 shows a cross section through a profile for an L-shaped running or mounting rail,
• 8 cross sections through profiles for support angles for and 9 the support of the stationary inner frame,
• 10 shows two cross sections lying one behind the other and ¹¹ the left part of FIG. 1, but with the difference that the drainage channel is placed on the lower longitudinal member and that the running rail is attached laterally and internally to the drainage channel,
• 12 shows two cross sections lying one behind the other and 13 the right part of FIG. 1, but with the difference that specially designed joints are arranged between the sloping roof parts and the upper longitudinal member,
• FIG. 14 shows a cross section through a further profile for the support bridges,
• FIG. 15 shows a cross section through a further profile for the drainage channel,
• 16 shows cross sections through two extruded profiles that can be put together and 17, and
• Figure 18 is a perspective view of a solar extension with a roof according to the invention.

In Figure 1, an upper roof 1 for a solar cultivation is shown, which consists of an upper box-shaped longitudinal member 2 and a parallel parallel lower longitudinal member 3, between which there is a sliding roof part 4 and a stationary roof part 5. The direction of displacement is perpendicular to the plane of the drawing and parallel to the longitudinal axes of the beams 2 and 3, of which the longitudinal beam 3 is also formed by a box-shaped profile. It goes without saying that in the case of roofs which have a greater length in the direction of displacement, the arrangement can also be made several times in succession.

The displaceable roof part 4 consists of a metallic inner frame 6 which extends on three peripheral sides of a plate 7 made of web glass. At the lowest point, the inner frame 6 is closed by a flatter profile, not shown, for the purpose of water drainage. The plate 7 is held in the inner frame 6 by so-called glass strips 8, which are designed as a hollow profile and are inserted in a positive manner in the inner frame 6.

The roof part 5 forms a stationary supporting structure, which consists of a further inner frame 9 with an identical profile cross section, in which a plate 10 is inserted by means of identical glazing beads 8. Also the inner frame 9 is for drainage purposes at the lowest point by a not shown Profile ^g e-closed, that does not extend beyond the run-off surface 10a of the plate 10 degrees.

The upper side member 2 is fastened to a wall 11 of a building and has a vertical inner wall surface 2a, to which an L-shaped running rail 12 and a mounting rail 13 with an identical profile cross section are fastened in such a way that the longer legs of the profiles point upwards. Details of the profile cross section are explained in more detail below with reference to FIG. 7 ′.

At the upper end of the inner frame 6, more precisely, on its profile parallel to the direction of displacement, there are several carriage holders 14, of which only the first one is visible in FIG. Details of the profile are shown in Figure 6. There are two rollers 15 in each carriage holder, which are connected to one another by a rocker to form a carriage. This carriage is articulated in the middle to the carriage holder, which in turn is screwed to the inner frame 6. At its apex, the carriage holder has an anti-lift device 14a, which prevents the rollers 15 from being removed from the rail 12 in an unacceptable manner.

In an analogous manner, the stationary inner frame 9 has a support bracket 16, the details of which are shown in FIG. This support bracket has a cantilever 16a, which by means of a cutout from a cylindrical Contact surface rests on the mounting rail 13, so that a flat support is guaranteed regardless of the slope or the sloping roof.

It can be seen that only a relatively small height of the side member 2 is required due to the selected arrangement, and that the fastening means described above are nevertheless within the projection surface of this side member. The upward gap between the roof parts 4 and 5 and the side member 2 is from a weatherboard profile; 17 covers, which has at its free end an insertion groove 17a for a sealing profile, not shown. The weatherboard profile is also attached to the side member 2.

At the other end, the movable inner frame 6 has a corresponding number of carriage holders 18, into which pairs of rollers 15 are also inserted. These rollers can be moved on a running rail 19, the details of which are explained in more detail in FIG. The other end of the stationary roof part 5 is provided with a plurality of support brackets 20, of which only the first one is visible here. Each of these support brackets has a cantilever 20a which is laterally bent in such a way that it overlaps the head of a support rail 21 with a partial cylindrical surface, the profile cross section of which is discussed in more detail in connection with FIG. In any case, it can be seen from FIG. 1 that the different heights of Track 19 and support rail 21 in connection with the attachment of the rollers 15 on the roof part 4 or the support bracket 20 on the stationary roof part 5, a height gradation or an overlap of the roof parts 4 and 5 is possible in a confined space, while at the same time opposite the lower side member 3 Gap 22 of sufficient width is maintained, which allows entry of the running rainwater.

It goes without saying that the position of the displaceable to the stationary roof part can also be interchanged, adaptation measures having to be carried out at the support points of the roof parts.

The running rail 19 and the mounting rail 21 are suspended on the lower side member 3 as follows: With the side member 3, several support bridges 23 are screwed at intervals, which consist of short sections of a profile, which will be explained in more detail with reference to FIG. 2. This carriage bridges on both sides have a vertical supporting ^fu ß 24 and a web connecting these 25 and 26, three grooves 27, 29 are 28.und in the top thereof, which have a width-increased groove bottom, so that the insertion of a component with a complementary dovetail 30 or 31 is possible (Figures 3 and 4 '). The support foot 24, which points outward with respect to the roof covering, has an extension 24a which projects upwards beyond the grooves in the web 26 and with which the support bridge 23 can be fastened to the lower longitudinal member 3, for example by screwing. Ver Stiffness of the longitudinal beam 3, a U-shaped stiffening profile 32 is arranged in this.

According to FIG. 1, the support bridges are at the same time the holders for a U-shaped drainage channel 33, the details of which are explained in more detail with reference to the profile cross section in FIG. Thus, the drainage channel 33 has a rib 36 and 37 on the upper edges of its side walls 34 and 35, which overlaps the respectively associated end of the web 26 of the support bridge 23. The representations in FIGS. 2 and 5 can be seen in direct association, ie the rib 36 engages in a recess 24b in the extension 24a, and the rib 37 engages over the complementarily bevelled upper edge 25a of the support foot 25. The heights are H ₁ and H ₂ and the distance D of the outer surface 24c and 25c of the support feet so designed that they correspond to the corresponding internal dimensions of the drainage channel 33 (Figure 1). Furthermore, the drainage channel 33 according to FIG. 5 has on its inner side wall 35 on its upper edge a receiving groove 38 for the insertion of a sealing strip, not shown.

From Figures 3 and 4 it can be seen that the running or support rails 19 and 21 have a rail head 39 and 40, which represents the largest part of a circumference in cross section. At the bottom, a rail 41 or 42, which widens in a trapezoidal shape, adjoins the rail head and finally in a swallow tail 30 or 31 ends. By means of these dovetails, the rails can optionally be inserted into the grooves 27 to 29 in the support bridge 23. The majority of the grooves in the support bridge 23 offer great flexibility with regard to structural adjustments.

Figure 1 can be seen that the overall arrangement of support bridges 23, drainage channel 33 and running or support rails 19 and 21 for the roof parts is a floating storage, which is extremely compact, but still mechanically stable due to the selected arrangement. The support bracket 20 and the support rail 21 form a support structure 63 for the stationary roof part 5.

FIG. 6 shows a carriage holder 14 which consists of a profile section. The cross section essentially consists of an approximately U-shaped basic profile, one leg 14c of which has an extension 14e. In the apex there is an anti-lift device 14a which is formed by a projection which runs parallel to the extension 14e as well as to the yoke 14f of the "U". In the space between the "U" a carriage 47 is housed and screwed, which is shown in Figure 7. The parts according to Figures 6 and 7 are shown in an explosion-like representation.

FIG. 7 shows an L-shaped running rail 12 which has a long leg 12a and a short leg 12b. On the top of the short leg, a rail head 12c is arranged, which on most of its circumference also formed as a cylindrical surface _. is. The carriage 47 can be moved on this rail head by means of its rollers 15. The rollers are mounted in pairs in a rocker 48, which can be pivoted relative to a fastening body 49, so that both rollers 15 always come to rest with the same contact pressure.

It is understood that the circumferential groove of the rollers 15 is complementary to the rail head 12c.

In Figure 8, a support bracket 16 is shown, which is also formed by an essentially rectangular angle profile with the legs 16c and 16d. In the area of the apex there is also an anti-lift device 16b which runs parallel to the leg 16c. A bracket 16a is attached to the leg 16d and has a bearing surface 16e which is circular in cross section. The rail head 12c of the L-shaped mounting rail 13 engages between the anti-lift device 16b and the boom 16a. This carrier rail is identical in cross section to the running rail 12 according to FIG. 7. The interaction is shown in FIG. 1.

FIG. 9 shows a support bracket 20 which is also formed in its essential part by a right-angled profile with the legs 20b and 20c. In the apex of this profile is the already described bracket 20a, which also has a bearing surface 20d with a circular cross section.

The longitudinal axis of the arm 20a extends approximately in the direction of the bisector, so that the bearing surface 20d is offset to both legs 20b and 20c.

With reference to FIG. 1, it follows that with respect to the rail heads which are circular in cross section on the one hand and with regard to the design of the rollers 15 and the bearing surfaces in the support angles on the other hand, a sloping position of the roof covering which is variable within wide limits is possible.

In FIG. 10 too, the top roof consists of a displaceable roof part 4 and a stationary roof part 5, which, however, have a larger roof slope than in FIG. Here, too, the plates 7 and 10 consist of web glass, and the drop traces 48 indicate the outflow of the rainwater into the drainage channel 49, which in this case has a somewhat modified cross section, which is explained in more detail with reference to FIG. 15. The drainage channel here has an intermediate wall 50, through which a hollow chamber 51 which is closed on all sides is formed within the profile and does not serve to guide water, but rather to accommodate fasteners. For example, a stiffening angle 52 can be inserted into the hollow chamber 51, which can be drilled through together with the drainage channel for attaching fastening screws, without thereby jeopardizing the tightness of the drainage channel.

In the drainage channel 49, support bridges 53 are inserted in a form-fitting manner at intervals, the details of which will be explained in more detail below with reference to FIG. 14. These support bridges have a web 54 and two support feet 55 and 56 reaching to the bottom of the drainage channel 49, of which the right one is arranged approximately in the middle and abuts directly against the vertical part of the intermediate wall 50.

In this case, the drainage channel 49 is screwed onto the horizontal upper side of the lower longitudinal beam 3, specifically by means of a screw connection, not shown, with the stiffening angle 52. It can be seen that the support bridge 53 is positively enveloped by the drainage channel 49 in all directions lying in the plane of the drawing is, and in particular that the 'side walls 57 and 58 (Figure 15) can not be bent outwards. By means of the support foot 56 arranged in the middle, vertical forces which act on the web 54 are transmitted directly to the lower longitudinal member 3.

Here, too, an L-shaped running rail 19 (FIG. 7) is screwed onto the right side wall 58 and penetrate the fastening screws (not shown) through the vertical leg of the stiffening angle 52. A so-called running carriage 59 can be moved on the running rail 19, which is shown in FIG a carriage profile 60 housed is, as shown in a similar form in Figure 6. The cross section of the carriage also consists here of an approximately U-shaped basic profile, the longest leg 60a of which has an extension 60b perpendicular thereto.

A joint 61 with a joint axis 62 is placed on the carriage profile 60, the details of which are explained in more detail with reference to FIGS. 16 and 17.

This joint 61 creates an adjustable and form-fitting connection with the displaceable roof part 4. From the lever arm of the running rail 19 in connection with any roof loads that may occur (wet snow), it follows that the running rail 19 has a tendency to pull the side wall 58 outwards. However, such positive bending is effectively prevented by the form-fitting clamping of the upper end of the side wall 58 with the support bridges 53 arranged at intervals at ^g e, in particular if the drainage channel is additionally screwed to the support bridges 53, which will be discussed in more detail below .

A support structure 63 for the rest of the roof structure, to which the stationary roof part 5 belongs, rests on the support bridge 53. This support structure includes a purlin 64, which consists of a short, vertically standing box section, which is cut off at its upper end along a miter joint 65 (FIG. 11). Between the purlins 10 so-called guide profiles 43 and 66, which prevent the overflow of rainwater or effect the roof sealing when the roof is closed. A seals attached at the upper end of the guide profiles 66 in sealing grooves are not shown. Shown in FIG. 10 is only a sealing rail 67 attached to the movable roof part 4, into which a sealing profile 68 is inserted. This sealing profile is located in the immediate vicinity of a rib, which is located on the upper edge of the side wall 58 of the drainage channel 49.

FIG. 11 shows a section along a plane offset in the depth direction with respect to FIG. 10, which extends through the purlin 64. This purlin consists of a hollow profile with a vertical axis, the attachment being carried out by a piofil portion 69 which is screwed to the support bridge 63 with its lower horizontal leg 70. The purlin 64 also tends to strain the overall construction by bending the left side wall 57 of the drainage channel. This bending is also effectively prevented by the positive locking. A further joint 72 is fastened on the upper horizontal leg 71 of the profile section 69, the joint axis A of which lies in the miter joint 65. Another profile section 73 is flanged to the other side of the joint and is accommodated in the cavity of a support 74 which merges into the purlin 64 at the miter joint 65.

The attachment of the profile sections 69 and 73 in the associated hollow profiles is state of the art and is therefore not explained in detail. This type of fastening also applies to the fixing of the profile section 75 in each carrier 76 of the displaceable roof part 4.

It can be seen from FIGS. 10 and 11 that obliquely incident sunlight, which is to be expected, for example in the direction of arrow S (FIG. 10), is only very insignificantly due to the entire supporting structure in the area of the drainage channel and the parts directly attached to it Incidence is prevented in the cultivation to which the roofing belongs. This results in a largely closed appearance towards the outside, which leads to a uniform overall impression of the complete roof in connection with the associated substructure, to which the lower longitudinal member 3 belongs.

In Figures 12 and 13, the connection of the roof 1 is shown in an analogous manner as in the right half of Figure 1. On the upper longitudinal beam 2, the running rail 12 is fastened, in the manner already described, on which the carriage holder 14 rolls with the running rollers 15. In contrast to Figure 1, the axis of the rollers 15 is aligned horizontally, however, because the carriage holder 14 is connected via a joint 77 to the displaceable roof part 4, of which only one of the here Carrier 76 with an inserted profile section 75 is shown. The conditions are essentially the same as at the other end of the carrier 76 shown in FIG. 11. The horizontal adjustment of the axes of the rollers 15 made possible by the joints 61 and 77 enables better load absorption by the carrier profiles 12 and 19, respectively.

The stationary roof part 5, of which only the other end of one of the beams 74 from FIG. 11 is shown in FIG. 12, is connected to the upper longitudinal beam 2 via joints 78. Each joint 78 is also fastened here via profile sections 73 and 79, respectively, which are accommodated in the support 74 or in a further support 80. The beams 74 and 80 have the same profile cross section and meet in a miter joint 81. The joint 78 is firmly connected to the upper longitudinal beam 2 by means of the profile section 79. The fastening screws are omitted for the sake of simplicity.

FIG. 13 shows the upper end of the roofing in a representation similar to that in FIG. 10. The inner frames 6 and 9 for holding the plates 7 and 10 (multi-wall glass) and the glass strips 8 for the sealed fixing of the plates can be seen here. In Figure 13, two sectional planes are drawn one above the other, which are offset in a direction perpendicular to the plane of the drawing compared to Figure 12. This representation was chosen to show the position of two weatherboard profiles 17 to show which the two roof parts 4 and 5 overlap, including the joints 77 and 78. At the front ends of the weatherboard profiles 17 there are sealing profiles 82, which ensure extensive sealing against the roof parts in question.

FIG. 14 shows a profile cross section for the support bridges 53, from which the support bridges can be produced by cutting to length (the length is a few centimeters). Each of the support bridges consists of a horizontal web 54, the length of which corresponds to the internal dimensions of the drainage channel according to FIG. 15. At both ends of the web 54 there are recesses 83 and 84 which are open at the top and which are complementary to corresponding prismatic projections 85 and 86 of the drainage channel 59 (FIG. 15). The recesses continue downward in so-called screw channels 87, the cross section of which corresponds to the longitudinal section of a corresponding metal screw. The recesses 83 and 84 are accommodated in transverse ribs 88 and 89 which protrude above the web 54 and have lugs 90 on their inwardly directed sides which are used for the form-fitting fixing of connecting parts (FIG. 11).

The already described support foot 55 is arranged at one end of the web 54 and is supported on the bottom of the drainage channel with a flange 91 parallel to the web 54. The support foot 55 is in mirror Symmetrical arrangement approximately in the middle of the web 54 opposite the support foot 56, which is also supported on the bottom of the drainage channel with a further flange 92.

FIG. 15 shows the cross section through the drainage channel 49 shown in FIGS. 10 and 11, which is used for the actual water flow. It has a base 93 from which the two vertical side walls 57 and 58 extend, which in the region of their upper edges have inwardly directed ribs 94 and 95 in a mirror-symmetrical arrangement and which have the prismatic projections 85 and 86 already described on their underside. On the upper edges of the side walls 57 and 58 there are inwardly directed lugs 96 and 97 which, together with the ribs 94 and 95, form insertion grooves 98 and 99 for sealing strips, not shown here. Furthermore, the respective groove base is designed as a hollow prism, with an opening angle that corresponds to the head of a normal countersunk screw.

16 and 17 show parts of the joints 61, 72, 77 and 78, as shown in FIGS. 10 to 13.

A first extruded profile 101 is shown in FIG. which consists of a flange plate 102 and a wing-shaped projection 103 which carries a first cylinder surface 104 on its inside and a second cylinder surface 105 on its outside. The The outer surface of the flange plate 102 is the actual mounting surface 102a. The hinge axis A. is at a distance D ₁ from this mounting surface, and the cylinder surfaces have the radii R ₁ and R ₂ with respect to the hinge axis A. The major part of the circumference of the coaxial cylinder surfaces 104 and 105 lies on one side of a plane E ₁ , which runs through the axis A and is perpendicular to the flange plate 102. A recess 106 in the wing-shaped projection 103 can also be omitted, in particular in the case of smaller designs.

FIG. 17 shows a second extruded profile 111 which has a flange plate 112 with a mounting surface 112a. The flange plate has on its one longitudinal edge an approximately L-shaped web 117, the free leg 118 of which supports the third cylinder surface 114 with the hinge axis A. Furthermore, a projection 113 is arranged on the side facing the articulation axis A, which carries the fourth cylinder surface 115 on its side facing the articulation axis A. The hinge axis A is at a distance D ₂ from the mounting surface 112a, from which the radii R ₃ and R _{4 start} for the cylinder surfaces in question. The radii R ₃ and R ₄ are only slightly smaller or larger than the radii ^R ₁ and R _{2 of} the paired cylindrical surfaces 114 and 115 of the first extruded profile, taking normal tolerances into account. (Figure 16)

In FIG. 17 as well, a plane E2 perpendicular to the flange plate 112 is defined by the hinge axis A, and it can be seen that the major part of the circumference of the cylinder surfaces 114 and 115 lies on one side of the plane E2. The profiles according to FIGS. 16 and 17 can be plugged together axially in the position shown, which leads to the joints as shown in FIGS. 10 to 13.

Figure 18 shows a very schematic representation of a portion of a solar extension with the roof 1 according to the invention. The longitudinal beams 2 and 3 extending in the longitudinal direction of the extension and their course at different heights can be clearly seen. The considerable sloping roof is also clearly recognizable. The direction of movement of the sliding roof part 4 is indicated by a double arrow. The lower side member 3 rests on a substructure 100 (not explained in more detail), which likewise consists of metal profiles with inserted plates P.

The profiles described above are, without exception, extruded profiles made of a light metal alloy, as is often used in metal construction. The profiles are usually anodized. A drain pipe, not shown, is connected to the drainage channel 33.

Claims (13)

1.Top roofing, preferably as a kit, with at least one sliding roof part, consisting of two parallel metallic longitudinal members with a rectangular cross-section and with at least one metallic inner frame with inserted panels, which can be moved between the longitudinal members by means of rollers on opposite running rails and comprises a maximum of approximately half the roof area from a supporting structure forming the rest of the roof surface with likewise inserted plates, the one running rail being L-shaped and fastened to the vertical inner wall surface of the one longitudinal member and the at least one inner frame being placed on the carriage holder to which the rollers are fastened, and wherein one of the side members is attached to a U-shaped drainage channel, characterized in that a) the side members (2, 3) are attached at different heights, b) the one, L-shaped running rail (12) is attached to the upper side member (2), and c) on the lower longitudinal member (3) parallel to this the U-shaped drainage channel (33, 49) is attached, in the d) positively and at intervals support bridges (23, 53) are used, and that e) at least one guide rail (19) for the at least one displaceable roof part (4) and a support structure (63) for the remaining roof structure are fastened to the support bridges (23, 53) and, if appropriate, to the drainage channel (33, 49). 2. Roofing according to claim 1, characterized in that on the support bridges (23) the at least one running rail (19) and a support rail (21) for the rest of the roof structure are placed (= Figure 1). 3. Roofing according to claim 1, characterized in that on the support bridges (23), the support structure (63) for the rest of the roof area is placed and that the running rail (19) to the drainage channel (49) is attached laterally (= Figures 10 and 11 ). 4. Roofing according to claim 1, characterized in that the supporting bridges (23, 53) two to the bottom (93) of the drainage channel (33, 49) reaching support feet (24, 25; 55, 56) and a horizontal connecting the support feet Have web (26, 54) which extends over the clear interior of the drainage channel (33, 49). 5. Canopy according to claim 4, characterized in that the outward-pointing support foot (24) of the support bridge (23) has an upwardly projecting over the web (26) extension (24a) for attachment to the lower side member (3). 6. Roofing according to claim 4, characterized in that the one support foot (56) is arranged approximately in the central region of the web (54). 7. Roofing according to claim 4, characterized in that the drainage channel (33, 49) on the upper edges of its side walls (34, 35; 57, 58) each have a rib (36, 37; 94, 95) which the web ( 26, 54) of the support bridge (53). 8. Roofing according to claim 7, characterized in that the ribs (94, 95) and the support bridges (53) are provided at their contact points with mutually complementary projections (85, 86) and recesses (83, 84). 9. Canopy according to claim 8, characterized in that the ribs (94, 95) and the supporting bridges (53) are positively fixed at their contact points by continuous fastening elements in the longitudinal direction of the drainage channel (49). 10. Roofing according to claim 8, characterized in that the drainage channel (49) on the underside of the ribs (94, 95) has prismatic projections (85, 86). 11. Canopy according to claim 10, characterized in that between the floor (93) and a side wall (58) of the drainage channel (49) an intermediate wall (50) through which an all-round closed hollow chamber (51) is limited within the drainage channel. 12. θ roofing according to claim 1, characterized in that the carriage holder (14, 60) consists in cross section of an approximately U-shaped base profile, the legs (14c, 60a) has an extension (14d, 60b). 13. Roofing according to claim 1, characterized in that between roof parts, which are at a different angle from 90 degrees or 180 degrees to another roof part, from extruded profiles (101, 111) existing joints (61, 72, 77, 78) with mutually complementary cylindrical surfaces are arranged, which are designed such that on the one (first) extruded profile (101) two mutually facing, coaxial cylindrical surfaces (104, 105), that on the other (second) extruded profile (111) two mutually facing, mutually coaxial cylinder surfaces (114, 115) are arranged and that the radii of the cylinder surfaces (104, 114; 105, 115) are matched to one another in such a way that the two extruded profiles (101, 111) can be pushed into one another in the axial direction with the formation of articulated connections in pairs .

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