EP2447434B1 - Metallic ceiling substructure - Google Patents

Description

The invention relates to a metallic ceiling substructure for ceiling elements, which consists of intersecting, spaced from the ceiling metal beams. The metal supports form a grid and are in the form of main and transverse beams. The connection of the metal support to each other is realized by specially designed connectors, which engage in openings which are arranged in the web region of the metal support, and engage the individual metal support with each other.

Metallic ceiling sub-constructions for ceiling elements consisting of intersecting, ceiling-spaced metal beams forming a grid are known in the art.

In the US 6,199,343 B1 Such a metallic ceiling substructure is described. At this off The prior art prior art substructure is also a grid formed by locking of main and cross members. The main and transverse beams described therein are designed in the form of a T-profile. The latching takes place here already by connectors, which are arranged on the front sides of the metal carrier and by an opening which is arranged in the web region of the metal carrier, engage. The opening in the T-beams is formed in a special rectangular shape. However, it has now been shown that the locking of the connectors by the in the US 6,199,343 B1 described opening is time consuming. Also, it is difficult to release the locking, then, if desired, again.

Another comparable system is in the US 4,779,394 disclosed. It is also proposed according to this US patent to form a metallic ceiling substructure in that the main and transverse beams are latched via connectors. By doing U.S. Patent US 4,779,394 Although a special design of the opening in the web area of the metal support is provided, but also the mutual locking of the two cross members with the main carrier is cumbersome and time consuming. Also, a release of the latched connection is not readily possible.

Furthermore, in the WO 2009/087378 A1 a T-beam of a web and a flange described, which can also be used for metallic ceiling substructures. In the aforementioned WO document, it is proposed to introduce reinforcing ribs in the web region for reinforcing the material.

Also from the US 3,501,185 A a similar ceiling substructure for ceiling elements is known.

Based on this, it is the object of the present invention to provide a metallic ceiling substructure for ceiling elements, in which the individual metal support, i. the main and cross beams are easily and safely latched together. Also should be possible by the solution to be found easy separation of the latched connection. A further object of the present invention is also to propose a connector which is as simple as possible in construction, which nevertheless ensures reliable latching of the individual metal carriers to one another.

This object is achieved by the features specified in claim 1. The dependent claims show advantageous developments.

According to the invention, a metallic ceiling substructure is proposed for ceiling elements, which consists of intersecting, spaced from the ceiling metal beams, which form a grid. In the ceiling substructure according to the invention, the metal beams are formed as a main and transverse beams and consist of an inverse T-profile, the flange is aligned in the direction of the interior of the room. The crossing points of the grid are formed by connectors which are arranged at the front ends of the cross members and which are latched to one another via openings in the web region of the metal carriers.

It is essential in the case of the ceiling substructure according to the invention that the metal supports have an opening with a rectangular basic shape, with projections in the direction of the interior of the opening being formed centrally on the short sides of the rectangle and on the longitudinal sides of the rectangle at the same height are. These specially designed openings then act together with the connectors as they are proposed according to the invention, namely with connectors which have respective bends on their longitudinal sides.

By such a construction is now achieved that a secure and easy locking of the metal support is ensured with each other. It has also been shown that the specific design of the opening and the connectors also enables easy and problem-free separation of the carriers from one another. It has also been found that by the specific design of the connectors with the bends forming an omega shape, when the metal beams are locked together, a significantly better stability and strength is achieved. It has also been shown that the torsional stiffness is significantly improved with such "omega connectors".

It is also advantageous in the inventive solution that the projections, i. the protrusions on both the short side of the rectangle and those disposed on the longitudinal sides are machined out of the material of the metallic supports themselves. As a result, in a simple production process, the protrusions can be formed simultaneously with the manufacture of the metallic supports.

According to the invention, the projections are formed on the longitudinal side in the upper region remote from the flange side, the projections being arranged on the longitudinal sides in the upper third, preferably in the upper quarter, particularly preferably in the upper fifth are. The projections and the opening itself are then dimensioned so that they are suitable for guiding the connectors passing through the opening. According to the invention, the size ratios of the rectangle are thus matched directly to the connector. Furthermore, embodiments with three projections on the long sides are excluded.

The connectors themselves are, as known per se, attached to the front ends of the cross member via at least one connecting device, preferably a compression and / or rivets. The connectors, which are attached to the front ends of the cross member, then protrude beyond the front end of the cross member, of course. The connectors are matched in their dimensioning and design so that they work together in combination with the openings in the web area of the metal support. It is essential that each connector has a fold on both sides of the long sides, which cooperates with the projections.

In principle, the specific form of the connector is not limited in the sense of the invention. According to the present invention, the connectors, if they have the above-described folds in omega form, can be designed both as hook connectors and as click connectors.

The click connectors, which can be used according to the invention, are constructed so that the connector itself has two openings, both in the front end of the web area superior part are formed. The two openings can either be flat, or, which is preferred, be formed so that the first opening, namely the one which faces the front end of the web, has approximately rectangular shape and is arched outwardly. The second opening is designed so that in each case the bulged opening of the other connector of the cross member can engage in the second opening. As a result, a further stabilization of the Verrastverbindung is accomplished.

The hook connector as described above is further characterized in that it has an arcuate recess and an additional nose in the folded portion, on the side facing away from the flange side. This specific design of the arcuate recess with the nose ensures that then in the locked state easy release of the locking connection is possible. Namely, when one of the rails, preferably the main carrier is pushed aside, the nose releases from its support point and the cross member can then be pulled out through its opening. The inventively proposed hook connector, which has a hook at its free end, thus characterized by the fact that he also has omega shape and that he next to the nose has an arcuate recess in the folded portion.

However, as already explained above, the invention also encompasses other embodiments, namely by means of an opening in the connector or else two, which can each also be planar. Also, the invention includes embodiments that are formed without opening in the connector.

According to the invention but not only the hook connectors described above can be used for latching cross members to the main carrier or the cross members with each other, but the locking can also be done by means of so-called. Click connectors. Such click connectors are known in the art in principle. However, according to the present invention, it is now proposed to use a click connector, which in turn also has the omega shape already described above for the hook connector. The click connector according to the invention is therefore also characterized in that it has the above-described folds, so that an omega shape of the click connector is formed and in which case a spring is arranged in the area between the two folds. The design of the spring is in and of itself known in the art. However, unlike the prior art, as already described above, the click connector also has an omega shape due to the folds.

By now proposed according to the invention specific design of the connector in omega shape in cooperation with the projections of the opening can now be achieved that not only identical connectors with each other, ie click connectors or hook connectors, are used for locking, but it is Also, a latching possible, in such a way that on a cross member in the front end of a click connector and at the other end face of the second cross member, for example, a hook connector is arranged. The omega shape also ensures locking of these two different connector types.

As described above, in the case of the metallic ceiling substructure according to the invention, latching takes place by means of the above-described connectors between two transverse beams and the main beam. In the case of the metallic ceiling substructure according to the invention, it is then also provided, as is already known from the prior art, that the transverse beams may in turn be latched to one another. In this case, then also have the cross member in the web area on the opening described above. A latching then takes place with two other cross members with the connectors described above. By such a system can then be built a grid, as it has already prevailed as known in the prior art. In such grids is essential that the ceiling panels manufactured by the industry, which have a standard size, can be hung in the appropriate grid. For this purpose, according to the invention, the main carrier 3 to 4 m long, preferably 3.6 m and 3.75 m, and the cross member has a length of 0.5 m to 2.0 m, preferably 0.6 m to 0.625 m and 1.2 m and 1.25 m, respectively.

The metallic ceiling substructure according to the invention is further distinguished by the fact that the connection of the cross members to the main carrier or the connection of two cross members with another cross member through the arranged in the web portion opening can be formed so that metal carriers are connected to each other via impact at the intersection points , In this case, thus abuts the front end of the flange of the cross member to the longitudinal edge of the flange. This achieves a flush transition towards the room side.

However, the ceiling substructure according to the invention can also be designed so that the front ends of the cross member have a crank, so that this offset then engage over the flange of the main carrier or the cross member, so that then a secure grip is ensured.

Another particularly preferred embodiment now proposes that for safe connection of the cross member with the main carrier or the cross member with each other at the front ends of the cross member a herausgearbeiteter from the material of the cross member projection is present. This projection then engages in the locked state on the flange of the main carrier or the cross member and provides additional stabilization.

The advantage of this solution consists in the fact that this projection can be worked out in the manufacture of the cross member with the material of the cross member in one operation. The projection, which protrudes from the web of the cross member is thus an integral part of the cross member itself. The length and dimensioning of the projection of the cross member is adjusted so that a secure overlap of the projection on the top of the flange of the main carrier or another cross member achieved becomes. It has been found that especially this variant is preferred because it is inexpensive to manufacture on the one hand and also allows a secure and stable locking. Also, this solution has the advantage that there is no jamming when releasing the locking connection, so that the locking connection in a simple manner dissolves again.

In the construction according to the invention, the T-beam is preferably formed from a double sheet. The production of such a T-beam thus takes place from a flat sheet, which is formed by certain forming operations so that a T with a web length preferably in the range of 20 to 80 mm and a flange width of 10 to 70 mm is formed. As already known in the prior art, it is also preferred in the ceiling substructure according to the invention that the web-side end of the T-beam has a hollow profile, preferably in a rectangular shape. It can also be provided in the ceiling substructure according to the invention that the double sheet is connected to the flange-side end of the T-beam via an additional metallic end plate. This metallic end plate, which then visually comes into effect on the room side, can be designed according to the desired design. In addition to the optical effects, this metallic end plate also has the advantage that it provides additional stabilization of the flange end of the T-profile.

The T-beam used according to the invention for the main beams and the cross beams can be further formed in the web area by providing at least one line-shaped reinforcing profile over the entire length of the web area. This reinforcing profile may for example be embossed in the form of a rectangle in the metal. The invention also encompasses embodiments in which more than one reinforcing profile, for example two or three reinforcing profiles, are incorporated in the web area in parallel form.

To further improve the rigidity of the carrier system, reinforcing ribs may additionally be incorporated in the web region of the main carrier and cross member in the region of the flange-side end. These reinforcing ribs can be incorporated selectively or in the form of short lines in the web area in the region of the flange-side end. These reinforcing ribs are usually also formed in a line shape and parallel to the flange. Preferably, the reinforcing ribs are introduced by a two-stage process in the web. In the first process step, a tab is cut free from the material. In the second process step is then carried out by a stamp pressing, so that a flow of the material of the tab takes place. By this pressing is then ensured that the tab can not be pushed back into the recess. According to the invention, such a configuration of the reinforcing ribs according to the present invention is preferred, since a high improvement of the torsional stiffness can be achieved, in particular, with such a configuration of the reinforcing ribs.

Of course, the invention also includes embodiments in which e.g. two reinforcing ribs are arranged in line parallel to the flange and in addition then also the reinforcing profiles in line form as described above are present.

To connect the main carrier with each other, it is provided in the invention, as already known in the prior art, that this is done via so-called. Bayonet closures. The connection of the main carriers with each other thus takes place differently in those at the aforementioned crossing points, ie at the points where the grid is formed by the main carrier and two cross members or from a cross member and two main carriers. These crossing points are realized exclusively as described above by means of the special connectors.

The material of the metallic carrier is a steel sheet of cold rolled strip. The steel grades include integrated C-steels with carbon mass fractions up to 1%, a preferred steel sheet is DX 51 Z 100.

The material for the connectors is a stainless steel, e.g. Chromium-nickel alloyed steels, such as e.g. X10CrNi18-8 (AISI 301).

In the invention, it should be emphasized that the choice of material stainless steel in combination with the omega shape outstanding mechanical stability is achieved.

• Figur 1 zeigt in der Draufsicht die Formgebung der Öffnung im Stegbereich der metallischen Träger.
• Figur 2 zeigt im Schnitt den Aufbau der metallischen Träger, d.h. sowohl der Hauptträger als auch der Querträger.
• Figur 3 zeigt einen Haken-Konnektor und dessen Befestigung am stirnseitigen Bereich der Querträger.
• Figur 4 zeigt einen Klick-Konnektor und dessen Befestigung am stirnseitigen Bereich der Querträger.
• Figur 5 zeigt in Figur 5a und in Figur 5b in zwei verschiedenen Ansichten die Ausbildung des Kreuzungspunktes der Verrastung zwischen den Haupt- und Querträgern mit den Konnektoren.
• Figur 6 zeigt in einem weiteren Schnitt, wie die Konnektoren in der Öffnung zusammenwirken.
• Figur 7 zeigt in einer weiteren Darstellung einen Bajonett-Verschluss zur Verbindung der Hauptträger untereinander.
• Figur 8 zeigt die Omega-Form eines Haken-Konnektors.
• Figur 9 zeigt die Omega-Form eines Klick-Konnektors.

The invention will be described below with reference to FIGS. 1 to 9 described in more detail, without limiting the scope of protection to these specific embodiments.

• FIG. 1 shows in plan view the shape of the opening in the web region of the metallic carrier.
• FIG. 2 shows in section the structure of the metallic carrier, ie both the main carrier and the cross member.
• FIG. 3 shows a hook connector and its attachment to the frontal region of the cross member.
• FIG. 4 shows a click connector and its attachment to the frontal region of the cross member.
• FIG. 5 shows in Figure 5a and in Figure 5b in two different views the formation of the crossing point of the catch between the main and cross members with the connectors.
• FIG. 6 shows in a further section how the connectors interact in the opening.
• FIG. 7 shows in a further illustration a bayonet closure for connecting the main carrier with each other.
• FIG. 8 shows the omega shape of a hook connector.
• FIG. 9 shows the omega shape of a click connector.

FIG. 1 shows in plan view the formation of the opening 1, as provided according to the invention in the metal supports, ie both in the main carrier and in the cross member. The opening 1 is formed in a rectangular shape and has two projections 2, 3 on the two short sides and two projections 4 and 5 on the longitudinal sides. The projections are worked out of the material of the metallic support itself and thus an integral part of the metal support. This allows a simple and cost-effective production, since the projections 2, 3, 4, 5 made of the same material as the metal support itself and thus can be produced in one operation. Essential in the solution according to the invention is the specific design of the opening 1 in the metal carriers. The positioning of the longitudinal projections 4 and 5 becomes chosen so that they are arranged in the upper third, preferably in the upper quarter of the opening 1 and that they are shaped so that the connector is supported with its specific shape by the projections.

In FIG. 2 is now on average the formation of the metal carrier, ie both the main carrier and the cross member shown. The metal support according to the invention consists of a double sheet, which is formed by forming accordingly. At its flange 31 opposite end of the web 32 is formed in the form of a rectangular hollow section 9. The in the embodiment according to FIG. 2 Example shown additionally has in the web 32 a reinforcing profile 7. This reinforcing profile 7 is also formed during the molding of the double sheet with and provides an additional stiffening of the T-beam in the web 32. This reinforcing profile 7 is preferably formed over the entire length of the web 32. The invention also includes embodiments in which two or three parallel line-shaped reinforcing profiles 7 are introduced in the web 32. The metal carrier according to the invention may additionally have reinforcing ribs 8. These reinforcing ribs 8 can either also be machined out of the material of the double sheet metal carrier or they can be applied separately in one operation. These reinforcing ribs, which are likewise likewise arranged linearly in the vicinity of the flange 32 close to the flange, again increase the rigidity, in order then to produce sufficient stability for the ceiling substructure when the corresponding ceiling elements are suspended. The invention includes, of course, embodiments in which only reinforcing ribs are arranged in line form or that only reinforcing profiles are provided in line form.

As in the embodiment according to FIG. 2 shows, the metal support shown there additionally has a metallic end plate 10 which is folded over the ends of the flange 31 of the metal support. By means of this end plate, a desired optical effect can be produced on the room side. Furthermore, the end plate also ensures a flush conclusion room side.

FIG. 3 shows a detail of the formation of a hook connector 11 according to the invention and its attachment to a cross member 12. The connector 11, as shown FIG. 3 can be seen, is attached via two pressings 13, 14 at the front end of the cross member 12. The connector 11 is characterized in that it has a hook 15 at its free end. As below in the FIG. 4 explained in more detail, this hook 15 is used for locking with the main beam or cross member. The embodiment of the connector, as he FIG. 3 is shown, also has two openings 16 and 17. As is apparent from the figure, while the first opening 17, ie that which faces the front end of the web, formed in a rectangular shape and has outwardly bulging longitudinal sides. The second opening 16 is now flat and designed so that when interlocking the connectors 11 at the crossing points, the bulge of the other connector 17 can engage in the opening 16. As a result, a secure and immovable stabilization of the two cross members is achieved to each other. The connector 11, as in FIG. 3 is shown is still characterized by the fact that it has two folds 18, 19, so that an omega shape is formed. These bends 18, 19 are formed in their shape, that they with the projections 4 and 5, as in FIG. 1 shown, work together.

Another essential element of the hook connector according to the invention is that this has an arcuate recess 41 with a nose 40 in the folded portion, on the side facing away from the flange side. By this training in curved shape 41 with a nose 40 ensures that the hook connector abuts in the locked state in the opening on the side facing away from the flange upper short side of the rectangular opening to be solved by turning the Verrastverbindung this stop and the cross member can be pulled out over the arcuate recess again.

In the FIG. 3 illustrated embodiment is still characterized by the fact that the cross member 12 is provided with a projection 20. This projection 20, which is an integral part of the cross member 12 is machined out of the same material as the cross member 12 and serves to stabilize the operative connection of the two to be connected cross member 12 with a main carrier or with another cross member. The design and shape of the projection 20 is chosen so that it engages in the locked state via the flange 31 of the main carrier or the cross member and thus contributes to a stabilization (see, inter alia FIG. 4 ).

The embodiment according to FIG. 3 also shows the introduced in the cross member 12 reinforcing ribs 8 in line form.

FIG. 4 now shows the inventive design of a click connector. The click-connector according to the invention also has, what is considered essential to the invention, two folds 18, 19, so that in turn here an omega-shape is formed. The click connector according to the invention then has, as is well known in the art, a resilient element 50. The formation of this resilient element 50 is in and of itself known in comparable click connectors in the prior art.

In FIG. 5 is now shown in two different sections a) and b), as the two cross members 12 are latched on the hook connectors 11 and the main carrier 21.

On average in the FIG. 5a is partially shown in the left part of the cross member 12 with a hook connector 11, as described above in the FIG. 3 has been described in detail. An identical cross member 12 with an identical connector 11 is in the right part of FIG. 5a shown. The main carrier 21, which can only be seen here in section, is analogous to that in FIG FIG. 2 constructed and consists of a web 32 with a rectangular reinforcement 9 and a flange 31. The opening is designated 1. Like now from the cut in FIG. 5a shows, the hook 15 engages through the opening 1 therethrough. The two connectors 11 are then locked together via the openings 16 and 17 with each other. Characterized in that the opening 17 has a bulge to the outside, this bulge of the opening 17 of the one connector 11 in the plane opening 16 of the other connector 11 engage so as to accomplish a secure locking.

In FIG. 5b the latch is shown in plan view. The main carrier 21 is, as in the above FIG. 5a described, with the two cross beams 12 and the identical connectors 11 locked. The locking is achieved via the connectors 11 of the respective cross members 12, which are fastened by means of rivets 13, 14 at the front end of the cross member (crossing point).

In FIG. 6 Now the locking of the two hook connectors 11 in the opening 1 is shown in a third section in an enlarged view. FIG. 6 shows the interaction of the opening 1 with the specially designed connectors 11. In FIG. 6 is the omega shape (dashed) of the connectors 11 to see.

As in FIG. 6 is illustrated, the projections 2, 3, 4 and 5 serve to guide the connector 11. The connector 11 has folds 18, 19 which are formed so that they engage around the projections 2, 3, 4 and 5. For this purpose, the connector 11 is provided with folds 18, 19 which extend through said longitudinal sides, formed, wherein these folds 18, 19 are formed so that they interact exactly with the projections 2, 3, 4 and 5 and so a secure fit Ensure locking connection.

Ultimately shows FIG. 7 the main carrier 21 with the opening 1 and a bayonet closure 30. Thus, according to the invention, not a connector as described above is proposed for connecting the main carriers, but this connection is ensured with in and of itself known from the prior art bayonet locks.

FIG. 8 shows now in three different views already at FIG. 3 closer described hook connector 11. In the FIG. 8a the hook connector 11 is shown in plan view and fully corresponds to the hook connector as shown in FIG FIG. 3 has already been described in detail. In FIG. 8b is now shown in section the hook connector 11. As is apparent from the cross section b), the hook connector 11 has an omega shape with two folds 18 and 19. Ultimately shows FIG. 8 then the hook connector 11 in the side view.

FIG. 9 shows in an analogous way in three views in Figures 9a, 9b and 9c the training of already at FIG. 4 described click connector. The click connector 60 in the illustration a), ie in plan view, is already in FIG. 4 has been described in detail. Like now off FIG. 9b shows, the click connector 60 in cross-section an omega shape with folds 18 and 19.

The key advantage of the connectors according to the invention is that both the hook connector 11, as at FIG. 8 described as well as the click connector 60 in cross-section an omega-shaped, which is designed similar, so that this omega shape with the projections in the opening 1 cooperates. The depth of the fold is matched exactly to the projections.

Ultimately, it's also in FIG. 9 the click connector 60 shown in side view.

Claims (24)

1. Metallic ceiling substructure for ceiling elements which consist of intersecting metal beams which are at a spacing from the ceiling and form a grid, the metal beams being configured as main- and cross-beams and having an inverse T-profile, the flange (31) of which points in the direction of the room interior and the intersection points of the grid being formed respectively by connectors (11, 60) which are disposed on the end-side ends of the cross-beams (12) and are locked to each other via openings (1) in the web region of the metal beams, wherein the metal beams have an opening (1) with a rectangular basic shape, projections (2, 3, 4, 5) at the same height in the direction of the interior of the opening (1) being configured respectively centrally on the short sides of the rectangle and respectively on the longitudinal sides of the rectangle and in that the connectors (11, 60) have bent portions (18, 19) respectively on their longitudinal sides which cooperate with the projections (2, 3, 4, 5) characterized in that the projections (4, 5) are configured on the longitudinal sides in the upper region orientated away from the flange side (31), wherein embodiments with 3 projections on the longitudinal sides are excluded.
2. Metallic ceiling substructure according to claim 1, characterised in that the projections (2, 3, 4, 5) of the openings (1) are produced from the material of the metallic beams.
3. Metallic ceiling substructure according to claim 1 or 2, characterised in that the projections (2, 3, 4, 5) of the rectangular openings (1) are dimensioned such that they serve for guidance of the connectors (11, 60) led through the opening (1).
4. Metallic ceiling substructure according to one of the claims 1 to 3, characterised in that the connectors (11, 60) have an omega shape due to the bent portions (18, 19).
5. Metallic ceiling substructure according to at least one of the claims 1 to 5, characterised in that the connectors (11, 60) are secured on the end-side ends of the cross-beams (12) via at least one pressing (13, 14).
6. Metallic ceiling substructure according to at least one of the claims 1 to 5, characterised in that the connectors (11) have two openings (16, 17), the first opening (17) which is orientated towards the end-side end of the web having a rectangular shape with outwardly curved longitudinal sides, and in that the second opening (16) is configured such that respectively the curved opening (17) of the connector (11) of the other cross-beam (12) can engage in the second opening (16) of the connector (11) and in that a hook (15) is disposed on the free ends of the connectors (11) (hook connector).
7. Metallic ceiling substructure according to claim 6, characterised in that the connectors (11), on the side orientated away from the flange side, have a lug (40) in the bent region and an arcuate recess (41).
8. Metallic ceiling substructure according to one of the claims 1 to 7, characterised in that the connectors (60) have a resilient element (50) between the two bent portions (18, 19) (clip connector).
9. Metallic ceiling substructure according to at least one of the claims 1 to 8, characterised in that the metal beams are connected to each other edge to edge at the intersection points.
10. Metallic ceiling substructure according to at least one of the claims 1 to 8, characterised in that the metal beams are connected to each other via a right-angle bend on the end-side ends of the cross-beams (12).
11. Metallic ceiling substructure according to at least one of the claims 1 to 8, characterised in that the metal beams respectively have, on the end-side ends of the web (32), a projection (20) which is produced from the material of the metal beam and engages, in the locked state, over the inside of the flange (31) of the other metal beam.
12. Metallic ceiling substructure according to at least one of the claims 1 to 11, characterised in that the T-beams are formed from a double metal sheet.
13. Metallic ceiling substructure according to one of the claims 1 to 12, characterised in that the web-side end of the T-beams has a hollow profile (9), preferably in rectangular shape.
14. Metallic ceiling substructure according to claim 13, characterised in that the double metal sheet on the flange-side end of the T-beam is connected via an additional metallic closing sheet (10).
15. Metallic ceiling substructure according to at least one of the claims 1 to 14, characterised in that at least one linear reinforcing profile (7) is present in the web (32) of the metal beams, preferably over the entire length of the web (32).
16. Metallic ceiling substructure according to claim 15, characterised in that two or three parallel linear reinforcing profiles (7) are present in the web (32).
17. Metallic ceiling substructure according to at least one of the claims 1 to 16, characterised in that reinforcing ribs (8) are present in the web (32) of the metal beams in the region of the flange-side end.
18. Metallic ceiling substructure according to claim 17, characterised in that the reinforcing ribs (8) are configured parallel to the flange (31) in linear form.
19. Metallic ceiling substructure according to at least one of the claims 1 to 18, characterised in that the main beams (21) amongst each other are connected to each other via connectors which are disposed on the end-side ends and form a bayonet socket (30).
20. Metallic ceiling substructure according to at least one of the claims 1 to 19, characterised in that the grid consists of cross- and main beams (12, 21) which are locked to each other and/or of cross-beams (12) which are locked to each other.
21. Metallic ceiling substructure according to at least one of the claims 1 to 20, characterised in that the main beams (21) have a length of 3 m to 4 m and the cross-beams (12) a length of 0.5 m or 2 m.
22. Metallic ceiling substructure according to at least one of the claims 1 to 21, characterised in that the T-profile of the metal beams has a web length of 20 to 80 mm and a flange width of 10 to 70 mm.
23. Metallic ceiling substructure according to at least one of the claims 1 to 22, characterised in that the metallic material of the beams is a thin steel sheet.
24. Metallic ceiling substructure according to at least one of the claims 1 to 23, characterised in that the metallic material of the connectors is a stainless steel.

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