The present invention relates to bridging connectors for a suspended ceiling system and suspended ceiling systems comprising such bridging connectors.

Bridging connectors known in the art comprise a beam connector for connecting to a beam of a grid system, and a wall engagement element arranged at an angle of essentially 90 degrees to the beam connector for connecting to a wall, thereby connecting the beam to the wall. Other bridging connectors comprise a beam connector for connecting to a first beam of a grid system and a beam engagement element arranged at an angle of essentially 90° to the beam connector for connecting to a second beam in the grid system, thereby connecting the two beams to each other.

Examples of such connectors can be found in US9255403, in which Figures 1 to 8 show a connector in various forms for connecting a beam to a wall angle. Figures 9 to 1 1 show a different connector which is for connecting two beams to each other. This document does not disclose the use of a single type of connector for fulfilling both functions.

US2014/0000205 and WO 2017/062944 disclose other bridging connectors for connection of a beam to a wall angle.

Another example of a connector can be found in US patent application no. 2006/0096219, which discloses a seismic perimeter clip for suspended ceiling grid. The perimeter clip comprises first and second legs bent at 90 degrees with respect to each other. The first leg is for engaging the vertical leg of a wall angle. The second leg is adapted to receive a bead of a beam. The perimeter clip is not suitable for connecting two beams of a suspended ceiling at right angles. Although the second leg is adapted to receive a beam, the first leg is not. The first leg includes a lower portion and a tongue which are designed to fit over a wall angle, but are not able to receive the bead of a beam. For a suspended ceiling system it is important that beams are not tilting in relation to each other, and this is not possible to safeguard with this prior art connector.

Summary of the invention

The known connectors are quite specific to the purpose, which means that an installer of suspended ceiling systems must have several different connectors for different purposes, which makes the installation process more complex and time-consuming.

It is hence an object of the present invention to provide a bridging connector, which is versatile and can be used in different configurations.

According to a first aspect of the invention there is provided a bridging connector for a suspended ceiling system, comprising:

a beam connector joined to

a wall engagement element arranged at an angle of essentially 90 degrees to the beam connector,

the beam connector being a saddle type connector of mainly U-shape, and the wall engagement element further comprising a depressed beam engagement portion.

According to a second aspect of the invention there is provided a bridging connector for a suspended ceiling system, comprising:

a beam connector joined to

a wall engagement element arranged at an angle of essentially 90 degrees to the beam connector,

the wall engagement element further comprising a depressed beam engagement portion,

wherein the wall engagement element further comprises a wall angle engagement portion, wherein the wall angle engagement portion comprises a first stop element and a second stop element. According to a third aspect of the invention there is provided a suspended ceiling system comprising a bridging connector according to the invention, further comprising:

a first beam connected to the beam connector of the bridging connector, the first beam comprising a flange,

a second beam connected to the beam engagement element of the bridging connector, the second beam comprising a flange,

a ceiling tile positioned on flanges of the first and second beams.

According to a fourth aspect of the invention there is provided a suspended ceiling system comprising a bridging connector according to the invention, further comprising

a beam connected to the beam connector of the bridging connector, the first beam comprising a flange,

a wall angle adapted for connection to a wall and engaging the wall angle engagement portion of the bridging connector, the wall angle further comprising a flange,

a ceiling tile positioned on flanges of the beam and the wall angle.

According to a fifth aspect of the invention there is provided a suspended ceiling system comprising at least two bridging connectors, the bridging connectors having the same structure and each bridging connector comprising:

a beam connector joined to

a wall engagement element arranged at an angle of essentially 90 degrees to the beam connector,

the wall engagement element further comprising a depressed beam engagement portion,

the suspended ceiling system comprising

a first beam connected to the beam connector of a first bridging connector, the first beam comprising a flange,

a second beam connected to the beam engagement element of the first bridging connector, the second beam comprising a flange,

a ceiling tile positioned on flanges of the first and second beams, a third beam connected to the beam connector of a second bridging connector, the third beam comprising a flange,

a wall angle adapted for connection to a wall and engaging the wall angle engagement portion of the second bridging connector, the wall angle further comprising a flange,

a ceiling tile positioned on flanges of the third beam and the wall angle

The object of providing a bridging connector, which is versatile and can be used in different configurations is firstly achieved by the wall engagement element further comprising a depressed beam engagement portion. The depressed beam engagement portion is tailored for accommodating part of a beam. Hereby the same bridging connector can be used both as a connector connecting a beam to a wall, and function as a connector between two beams for connecting these at an angle. This means that the installer does not need different connectors for connecting two beams and for connecting a beam and a wall angle, respectively, as the same connector can be used for both purposes.

Use of a saddle type connector has the advantage that it enables a quick connection between the bridging connector and the beam.

Preferred bridging connectors meet the requirements of both the first and second aspects of the invention.

The wall engagement element may further comprise a wall angle engagement portion. Such an embodiment enables positive and well-defined engagement between the bridging connector and a potential wall angle. Wall angles are often used to provide an aesthetically pleasing transition from a suspended ceiling to a wall. Further wall angles are often used for supporting ceiling tiles along the wall.

According to a second aspect the wall angle engagement portion comprises a first stop element and a second stop element. Hereby it is possible to position the bridging connector in different positions relatively to the wall angle. This eliminates the need for different types of bridging connectors for different types of wall angles or for different positions of the connector relative to the same wall angle.

The wall angle engagement portion will normally be positioned below the depressed beam engagement portion (“below” being in relation to their positions when the bridging connector is in use).

The first and second stop elements may be steps formed in the wall angle engagement portion. This provides for simple manufacturing by bending of the wall angle engagement portion.

In an alternative embodiment the first and second stop elements are indentations formed in the wall angle engagement portion. This may be cheaper in production and potentially save material.

The beam engagement portion is depressed in relation to the plane of the wall engagement element. Namely, its surface is displaced by a distance in relation to the plane of the wall engagement element. It forms a recess in the surface of the wall engagement element. This means that it can accommodate the bead of a beam. The lower and upper bounds of the recess are generally formed by first and second abutments.

In an embodiment of the bridging connector the beam engagement portion comprises a first abutment and a second abutment. Hereby an even more versatile bridging connector is provided in that the bridging connector can be connected to a beam at two different, well-defined positions at the respective abutments connecting in first and second vertical positions. This means that the same bridging connector can be used in different configurations, and the need for a variety of different connectors is eliminated or at least reduced.

The depressed beam engagement portion will have a height which is greater than the height of the bead of the beam which is to be accommodated within the recess. The height of the beam engagement portion is therefore defined by the distance between the first and second abutments and this distance is generally greater than the height of the bead of the beam to be accommodated.

In an embodiment of the bridging connector the wall angle engagement portion supplementarily or alternatively comprises a tongue off-set from a plane of the wall engagement element. Hereby the wall engagement element is adapted to straddle the wall angle and provide at least a certain degree of fixation of the bridging connector to a wall angle. This can be advantageous for installers to have a non-permanent connection before making more permanent fixation of the wall engagement element to a wall, e.g. by means of a screw.

According to an embodiment the wall engagement element further comprises fracture assistance weakenings. The fracture assistance weakenings may be one or more cut-outs or stitches in the wall engagement element to weaken the wall engagement element at the wall angle engagement portion to provide a well-defined line of fracture. Hereby it is possible to break away the wall angle engagement portion by hand without the use of tools. In some situations, it is advantageous to remove the wall angle engagement portion when this is not to be used, e.g. if it would be in the way connecting two beams at different levels.

The bridging connector may be made up of different parts, which are assembled to form the bridging connector, but according to a particularly simple embodiment the bridging connector is a unitary piece.

The bridging connector may be made of any suitable material, such as plastics or reinforced plastics which may be suitable for 3D printing. According to an embodiment, however, the bridging connector is made of sheet metal, which is relatively light and strong, and can be bent in various forms and shapes with common tools, and further metal has good fire stability.

According to an embodiment the wall engagement element of the bridging connector comprises an aperture adapted for receiving a fastener making it easier for the installer to mount a fastener. The aperture may be an elongated hole to facilitate some adjustment. The fastener may for example be a screw.

An aspect of the invention relates to a suspended ceiling system comprising the bridging connector. The suspended ceiling system further comprises a first beam connected to the beam connector of the bridging connector, the first beam comprising a flange, a second beam connected to the beam engagement portion of the bridging connector, the second beam comprising a flange, and a ceiling tile positioned on flanges of the first and second beams.

Another aspect of the invention relates to a suspended ceiling system comprising a bridging connector comprising a wall angle engagement portion as outlined above, further comprising a beam connected to the beam connector of the bridging connector, the first beam comprising a flange, a wall angle adapted for connection to a wall and engaging the wall angle engagement portion of the bridging connector, the wall angle further comprising a flange, a ceiling tile positioned on flanges of the beam and the wall angle.

The versatility of the bridging connectors of the invention means that it is possible to provide a suspended ceiling system which uses connectors which are all of the same configuration, for connecting beams to each other and for connecting beams to the wall.

The beam may be of the type denoted tee runners. Such tee runners are beams of T-shaped cross section with a stem or web and flanges to each side of the stem at one end thereof. The other end of the stem may comprise a bulb or bead at the other end of the stem part. Such tee runners are commonly used in suspended ceiling systems.

The ceiling tiles may be made of mineral wool, such as stone wool or glass wool, which provides favourable acoustic properties by providing sound absorption thereby optimizing room acoustics. The thickness of such tiles is generally between 15 and 50 mm, and other dimensions generally 600 x 600 mm, 1200 x 600 mm or 1800 x 600 mm. The area weight is generally below 10 kg/m ² , and often in the range of 2 to 8 kg/m ² , such as 3-5 kg/m ² .

Alternatively, the ceiling tiles may be metal panels, wet felt ceiling tiles or gypsum boards.

In the following, embodiments of the invention will be described in more detail with reference to the drawings in which:

Figure 1 shows a bridging connector according to a first embodiment,

Figure 2a is an illustration of part of a suspended ceiling system using the bridging connector of Figure 1 in a first position,

Figure 2b is an illustration of part of a suspended ceiling system using the bridging connector of Figure 1 in a second position,

Figure 2c is an enlarged detail of Figure 2a,

Figure 3a is an illustration of part of a suspended ceiling system using the bridging connector of Figure 1 in a second way - first position,

Figure 3b is an illustration of part of a suspended ceiling system using the bridging connector of Figure 1 in a second way - second position,

Figure 4 is an illustration of part of a suspended ceiling system using the bridging connector of Figure 1 in a third way,

Figure 5 shows a bridging connector according to a second embodiment,

Figure 6 shows the bridging connector of Fig. 5 connecting a wall angle and a beam, and

Figure 7 shows the bridging connector of Fig. 5 connecting two beams at an angle.

The bridging connector 1 illustrated in Figure 1 comprises a beam connector 2 and a wall engagement element 3. The beam connector 2 is joined to the wall engagement element 3 via a web part 6. The beam connector 2 and the wall engagement element 3 are connected at an angle of 90 degrees as illustrated. The beam connector 2 is a saddle type connector of mainly U-shape. The beam connector 2 comprises a cut-out 20 for receiving a fastener. The wall engagement element 3 is fitted with apertures 30 to receive a fastener for connection to a wall. Fracture assistance weakenings 40, here in the form of V- shaped cut-outs, are arranged at the lower part of the bridging connector to facilitate breaking away of a lower part of the connector, should this be in the way in certain installations. The fracture assistance weakenings 40 makes it possible to break away this lower part by hand, i.e. without using tools. The wall engagement element 3 further comprises a beam engagement portion 4. The beam engagement portion 4 is provided with a first abutment 4a and a second abutment 4b. The beam engagement portion 4 is provided with holes 7 for receiving a fastener. The beam engagement portion 4 is depressed by a distance X in relation to the plane of the wall engagement element 3. The bridging connector is further provided with a wall angle engagement portion 5. The wall angle engagement portion 5 is provided with a first stop element 5a and a second stop element 5b. The first and second stop elements are provided as bent portions of the wall angle engagement portion 5 thereby providing steps in the wall angle engagement portion.

Part of a suspended ceiling system incorporating the bridging connector 1 is shown in Figure 2a. The beam connector 2 is connected to a bead 27 of a beam 24. Arranged at right angles to this beam 24 is another beam 24. The bead 27 of this beam 24 is arranged in the depressed beam engagement portion 4. A lower edge of the bead 27 is positioned abutting the first abutment 4a of the depressed beam engagement portion 4. A screw 21 introduced through the hole 7 into the bead 27 and thereby firmly connects the beam 24 to the bridging connector 1. The two beams are at the same level in this position, so the lower face of the connected beams are flush.

Similarly, part of a suspended ceiling system incorporating the bridging connector 1 is shown in Figure 2b, but here the two beams are arranged at different levels off-set by a distance Y, such as 15 mm. The beam connector 2 is connected to a bead 27 of a beam 24. Arranged at right angles to this beam 24 is another beam 24. The bead 27 of this beam 24 is arranged in the depressed beam engagement portion 4. An upper edge of the bead 27 is positioned abutting the second abutment 4b of the depressed beam engagement portion 4. A screw 21 introduced through the hole 7 into the bead 27 and thereby firmly connects the beam 24 to the bridging connector 1.

An enlarged detail of Figure 2a is seen in Figure 2c. In this illustration, it is more clearly seen that the beam engagement portion 4 is depressed by a distance X to accommodate the bead 27 of the beam. The distance X is adapted for the width of the bead 27. As an example, a common width of the bead of the beam 24 for suspended ceilings is 6.5 mm, and the distance X of the depression slightly less than half of this, e.g. 2 to 3.2 mm, taking into account the thickness of the material of the beam and potential embossing or stitching of the beam. Often such beams are made of folded sheet metal where the central web portion is double layer.

Part of a suspended ceiling system incorporating the bridging connector 1 is seen in Figure 3a. The wall engagement element 3 of the bridging connector 1 is connected to a wall via a screw 21. The beam connector 2 is connected to a bead 27 of a beam 24. A wall angle 22 is fixed to the wall via means not shown in the drawing. An upper part of the wall angle is abutting the second stop element 5b of the bridging connector 1. In this configuration there is a well- defined first distance between the top of the wall angle 22 and the top of the beam connector 2. A tile 23 (having so-called E-edge) is arranged to rest on flanges of the wall angle 22 and the beam 24.

Part of a suspended ceiling system incorporating the bridging connector in another configuration is seen in Figure 3b. The wall engagement element 3 of the bridging connector 1 is connected to a wall (not shown) via a screw 21. The beam connector 2 is connected to the bead 27 of the beam 24. The wall angle 22 fixed to the wall via means not shown in the drawing. An upper part of the wall angle is abutting the first stop element 5a of the bridging connector 1. In this configuration there is a well-defined second distance between the top of the wall angle 22 and the top of the beam connector 2. This means it is possible to fit a ceiling tile 23 with another edge configuration (here illustrated with a tile having the so-called X-edge). The flanges of the beam are arranged in a groove at the edge of the ceiling tile, thereby concealing the beam.

Part of a suspended ceiling system incorporating the bridging connector in another configuration is seen in Figure 4. Ceiling tiles 23 are often made of materials that are not strong enough to support the weight of lamps or other equipment, so the weight of such equipment must be distributed to the beams of the suspended ceiling grid. For this purpose beams 24 are arranged on top of the tile 23 to hold a lamp 30. The beam 24 holding the lamp 30 is connected to another beam of the suspended ceiling grid at right angles via the bridging connector 1. The top of the beam is abutting the second abutment 4b of the beam engagement element 4, and the beam 24 is fixed to the beam engagement element 4 using a screw. In this position the flange 25 is above the top of the tile 23, so the beam 24 is out of the way of the ceiling tile.

A bridging connector T according to another embodiment is seen in Figure 5. The beam connector 2 has a slightly different design, but the same function. The wall angle engagement portion also has a slightly different design with a tongue 50 and prongs 53. The tongue 50 and prongs 53 are adapted to engage a wall angle by straddling the top of the wall angle. The tongue 50 comprises indentations 51 functioning as first stop.

Figure 6 illustrates part of a suspended ceiling system incorporating the bridging connector 1 of Figure 5. The wall engagement element 3 of the bridging connector 1 is connected to a wall 54 via a screw 21. The beam connector 2 is connected to a beam 24. The wall angle 22 is fixed to the wall via means not shown in the drawing. The wall angle 22 in the illustrated embodiment is stepped to provide a recess near the wall and further is provided with a wall angle flange 29. An upper part of the wall angle is straddled by the tongue 50 and prongs to a second stop element of the bridging connector 1. In this configuration there is a well-defined first distance between the top of the wall angle 22 and the top of the beam connector 2. Figure 7 illustrates part of a suspended ceiling system incorporating the bridging connector 1 of Figure 5 in another configuration. The beam connector 2 is connected to a bead 27 of a beam. The beam has a general inverted T-shape with a web 26 and flanges 25. Another beam is connected to the beam engagement element of the bridging connector using a screw 28.

In the embodiment shown the beam connector is a saddle type connector of mainly U-shape to straddle the top of the beam. Saddle type connectors enables a quick connection between the bridging connector and the beam. The saddle type connector may be configured for snap fit with the top of the beam. Further the saddle type connector may be configured to receiving an end of the beam in sliding engagement. Alternatively, the beam connector may be any suitable type of connector. In the simplest form the beam connector may be a plate portion with holes for screw connection to the beam.