EP2718203A1 - Freight floor, freight container, use of a multi-layer panel to produce a freight floor, and method for producing a freight floor - Google Patents

Abstract

For economic and ecological reasons, the aircraft industry continuously strives to reduce the weight of freight containers and/or freight pallets. However, it is necessary for the functionality and the robust design of the freight container or freight pallet to remain unaffected. In this regard, the invention provides a solution approach, wherein a freight floor has a multi-layer construction and is designed as a composite material, comprising a core layer (42, 43, 44) made of carbon-fiber-reinforced and/or glass-fiber-reinforced plastic and an overlay layer (21) made of a metal alloy, in particular made of an aluminum alloy.

Description

 Cargo floor, cargo container, use of a multi-layer panel for the production of a cargo floor, method of manufacturing a cargo floor

description

The present invention relates to a cargo floor, a freight container, the use of a multi-layer panel for the production of a cargo floor and a method for the production of a cargo floor.

Freight containers and cargo pallets are indispensable for the effective transport of cargo in aircraft, as they allow a fast loading and unloading of the aircraft. The vast majority of commercial aircraft can accommodate a variety of freight containers or cargo pallets. Most containers or pallets are standardized so that they can be used independently of the aircraft used for transport. Until 10 years ago, freight containers were made exclusively of aluminum, with the weight of the container was about 100 kg. The currently used containers are partly based on lighter materials, so that freight containers weighing around 60 kg are now being used. It should be obvious that reducing the dead weight of the containers or pallets used has a significant financial and environmental impact. Freight containers are for example from the

DE 69 702 821 T2, US 5,941,405, DE 20 64 241 and

DE 102 008 005 010 AI known. Also, the use of textiles or

Fabric (see US 4,538,663) or non-metallic materials (cf.

JP 07257683 A, DE 69616182 T2 and DE 3409683 AI) in this area was considered.

In the construction of a freight container or cargo pallet, it is essential how the cargo floor is configured. On this rests the entire load of the loaded cargo. Furthermore, the freight containers or

Cargo pallets often parked improperly, so that in some cases large punctual loads act on the cargo floors. Freight containers and freight pallets are parked and locked fully automatically or partially automatically on the cargo deck of the aircraft at a predetermined position. To drive the freight containers and freight pallets, roller drive units (PDUs: Power Drive Units) or cargo drive units are embedded in the cargo deck. These cargo propulsion units have rollers that are coated with an elastomer (eg rubber) and attach to the cargo floor to apply appropriate forces. In the construction of freight containers, it is therefore necessary to design the cargo container floors or cargo floors so that sufficient force can be transmitted by means of the rollers. Again, high forces act on parts of the cargo floors, which can lead to rapid wear.

Based on the cited prior art, it is the task of

present invention, a freight container with an improved

Provide cargo floor and a corresponding cargo floor alone.

In particular, the new cargo floors and cargo containers should be lighter, functionally applicable and robust.

This object is achieved by a cargo floor according to claim 1.

In particular, this object is achieved by a cargo floor with at least one core layer of carbon-reinforced and / or glass-fiber-reinforced and / or aramid-fiber-reinforced plastic and a support layer of a

Metal alloy, in particular of an aluminum alloy, dissolved, which is a composite material.

An essential idea of the present invention is to reduce the weight of the cargo floor by making it of several layers, in particular in a sandwich construction, wherein for the

Layers of metal and plastic materials are used. Here are given requirements, eg. As good friction and wear conditions, considered, with a total of very stable composite material or

Composite material is provided.

Preferably, a connection of the layers by material and / or positive connection, wherein a material connection leads to particularly good results. The cargo floor may comprise a plurality of core layers. These

Core layers can form a nucleus. The core layers can

fiber reinforced, wherein a first core layer may have a first fiber orientation extending from a second fiber orientation of a second fiber orientation

Core layer is different. For example, two core layers may be arranged such that the first fiber orientation of the second

Fiber orientation differs by an absolute angle of at least 20 or 30 or 40 or 45 degrees or 90 degrees. The absolute angle may be defined such that it is the smallest absolute angle value between two

Fiber alignments is.

At least one core layer may comprise a fiber network of carbon fiber and / or glass fibers and / or aramid fibers. The fibers within one

Fiber network can be substantially perpendicular to each other, so that there is a grid. A corresponding core layer is particularly durable. The core layers with fiber nets can also be arranged such that the fiber orientations of two core layers differ by 20 or 30 or 40 or 45 degrees or 90 degrees. This angle can also be used as

Absolute angle to be understood.

The cargo floor may comprise at least one core layer with a foam layer. Here a foam with cellular structure and low density can be used. The foam may be at least partially impregnated with synthetic resin. The foam causes the inventive

Cargo compartment floor has a low weight, wherein the synthetic resin

Construction stiffened.

The foam layer may comprise a support structure. Preferably, this support structure extends vertically to the cargo compartment floor, so that this adhering to the foam layer layers firmly together. The support structure may be formed of a synthetic resin. The support structure may have a rectangular or honeycomb or round shape to accommodate vertical forces.

The foam layer may be between a first core layer

carbon fiber reinforced and / or glass fiber reinforced and / or

aramid fiber reinforced plastic and a second core layer carbon fiber reinforced and / or glass fiber reinforced and / or

embedded aramid fiber reinforced plastic. Preferably, the individual layers are interconnected by material bond. For example, a compound of the layers can be made by synthetic resin.

Preferably, the foam layer has the support structure already described, which is substantially perpendicular to the fiber direction or the

Fiber directions of the first and second core layers extend.

At least one core layer may have a connection layer on a side facing the support layer. This connection layer can for

Connecting the corresponding core layer or the core with the

Pad layer serve. This is preferably the core layer, which is arranged directly adjacent to the support layer. The

Bonding layer can be made of an elastomer. Preferably, this connection layer serves firstly to connect the support layer to the core or the core layers. Furthermore, the tie layer compensates for a differential thermal expansion between the core having the at least one core layer and the overlay layer. This can be advantageous if the cargo space floor according to the invention is produced, or if it is exposed to strong temperature fluctuations during its use.

Alternatively or additionally, an adhesive, in particular a polyurethane adhesive, can be used to bond the support layer to the core layer.

The bonding layer can be bonded to the core layer and / or the overlay by adhesion, in particular by vulcanization. Preferably, the overlay layer of the metal alloy serves as the outer layer against which the cargo drive units engage. Furthermore, this layer absorbs punctual loads and distributes them over a wide area. An aluminum alloy is particularly suitable here, since a good coefficient of friction results in connection with conventional rollers of cargo drive units. The core layers stiffen the entire construction and lead to significant

Weight savings.

The support layer may have a thickness of 0.5 mm to 2.5 mm, in particular from 0.7 mm to 1.5 mm, in particular from 0.9 mm to 1.5 mm. Preferably, the overlay layer has only a small thickness in relation to the thickness of the entire cargo floor, e.g. B. less than 40%, in particular less than 30%, in particular less than 20% of the total thickness. In this respect, significantly lighter cargo floors can be produced.

The support layer may have a strength of more than 400 N / mm ² , in particular more than 500 N / mm ² . In this respect, the overlay layer can protect the core layer from high punctual loads. The cargo floor according to the invention is subject to the usual rough treatment only a slow wear and is very robust.

It is possible to design the cargo floor in a multilayer structure only in two layers. Preferably, however, at least one further layer, namely a wear layer or cover layer can be provided, which is arranged on the side facing away from the support layer of the core layer.

The wear layer may be formed from a metal alloy, in particular from an aluminum alloy, and / or a glass fiber reinforced plastic and / or a material from the group of aromatic polyamides (eg aramid). The wear layer can protect the core layer from wear and stiffen the sandwich construction as a whole.

The aluminum alloys mentioned for the support layer and / or

Wear layer may be aluminum wrought alloys. The main alloying element used may be zinc, with zinc occupying a constituent of 0.7 to 13%, in particular 0.8 to 12%. Such aluminum alloys are very hard. For example, 7075 T6 or 7075 T7 may be used as the material.

On the other hand, an aluminum wrought alloy with the main alloying element copper may be used, whereby copper may occupy a constituent of 0.5 to 9%, in particular 0.7 to 8%. In addition to the materials 7075 T6, 7075 T7 already mentioned, materials such as 2024 T3 / T4, 2026 T3511, 2056 T3, 2524 T3, 5052, 6061 T4, 7075 T761 or 7475 T61 are conceivable, for example. Particularly good properties are 2024 T3 / T4, 2056 T3 or 2524 T3, since these materials sufficiently stiffen the cargo hold floor and have a long service life under load. Preferably, the wear layer is connected by form and / or material bond with the core layer.

The aluminum alloys mentioned can be aluminum alloys with a solution-annealed and / or heat-aging and / or overhardened

Be heat treatment so that a sufficient strength is achieved.

The core layer may have a thickness of at least 1 mm, in particular at least 1.5 mm, in particular at least 2 mm, in particular at least 4 mm, in particular at least 6 mm.

In one embodiment, the core layer comprises a solid core.

According to the application, a core may be understood to mean a core that is essentially solid. That is, the core layer is at least 50%, in particular at least 70%, in particular at least 90%

built carbon fiber reinforced and / or glass fiber reinforced plastic. Larger contiguous cavities, in particular honeycomb or the like, are not provided.

The wear layer may have a thickness of 0, 1 to 1 mm, in particular from 0.2 to 0.6 mm, in particular from 0.25 to 0.5 mm.

The stated object is further achieved by a freight container which comprises a cargo floor, as has already been explained, as well as side walls arranged on the cargo floor. The freight container has similar advantages as those already explained in connection with the cargo floor.

The cargo floor may comprise an at least partially circumferential edge profile, in particular in the form of a bead, for connecting the side walls to the cargo compartment floor. Ultimately, the cargo hold floor can do so

be formed so that it has a peripheral edge, which can then be inserted into the circumferential container corner profiles so that no rivets for the connection of the bottom with the side walls are necessary.

The side walls may be at least partially made of glass fiber reinforced and / or carbon fiber reinforced plastic. The above object is further achieved by using a

Multilayer panel comprising a core layer of carbon fiber reinforced and / or glass fiber reinforced and / or aramid fiber reinforced plastic and a release layer of a metal alloy, in particular one

Aluminum alloy, for the production of a cargo floor and solved by a corresponding manufacturing process.

The manufacturing process may include the following steps:

- Producing a core with at least one core layer

 carbon fiber reinforced and / or glass fiber reinforced and / or aramid fiber reinforced plastic;

- Producing a support layer of a metal alloy, in particular of an aluminum alloy;

- Connect the support layer with the at least one core layer by material bond and / or material connection.

Preferably, the method is suitable for producing a cargo hold floor, as has already been described.

The bonding of the support layer to the core layer can be achieved by applying and / or vulcanizing a bonding layer from the group of

Elastomers take place.

The core can be made from a variety of core layers.

Preferably, the core layers have at least two core layers of carbon fiber reinforced and / or glass fiber reinforced and / or

aramid fiber reinforced plastic, wherein the fiber orientation of the individual core layers differs.

To reduce the weight, a core layer of the core can have a

Foam, in particular with a support structure include.

The core layers can be bonded together by applying a synthetic resin. Preferably, a curing of the plastic takes place at Temperatures between 100 and 200 degrees, in particular between 150 and 180 degrees. The curing of the core layer (s) may occur simultaneously with the bonding of the overlay layer to the core. For example, the applied thermal energy for curing the core may be used to bond an at least partially unvulcanized rubber to the overlay layer and the core. Alternatively, an adhesive may be used to make the bond between the overlay layer and the core layer.

For example, a polyurethane adhesive may be used to bond the layers together.

Further advantageous embodiments will be apparent from the

Dependent claims.

The invention will now be described by means of several embodiments

described in more detail with reference to figures.

Hereby show:

Fig. 1 is a schematic representation of a freight container with a

 Base plate and side walls;

2 shows a cross section through the bottom plate of Fig. 1.

Fig. 3 is a three-layer embodiment of the bottom plate of Fig. 1;

4 shows a section of an edge region of the freight container

 Fig. 1;

5 shows a cross section through an alternative embodiment of a

 Base plate (single layer core with tie layer); and

Fig. 6 shows a cross section through an alternative embodiment of a

 Base plate (multilayer core with bonding layer).

In the following description, the same reference numerals are used for the same and like parts. 1 shows a cuboid-shaped freight container 10 which has a freight container height h, freight container width b and a freight container length I.

The freight container 10 has a bottom plate 20, which is arranged opposite a cover plate 13 and as an embodiment of the invention

Cargo floor can be viewed. The lateral surface of the cuboid freight container 10 is formed by the side walls 12a to 12d, in particular a first side wall 12a, a second side wall 12b, a third side wall 12c and a fourth side wall 12d. The side walls 12a to 12d are arranged in pairs opposite each other.

2 shows a cross section through the bottom plate 20 of the freight container 10. In the embodiment shown in FIG. 2, the bottom plate 20 is constructed in a multi-layer structure comprising a support layer 21 and a core 40. The support layer 21 forms the lower layer and is connected in a planar manner to the core 40 by material connection, the core resting on the support layer 21. The base plate 20 is thus constructed as a composite material, wherein the core 40 consists of a core layer, namely of a CFRP layer 42 (carbon-reinforced plastic), and the support layer 21 of an aluminum alloy (eg a material with the designation 7075 T6 or 2024 T3 / T4). The support layer 21 has a support layer thickness h1 of 1 mm and the CFRP layer 42 has a core layer thickness h2 of at least 2 mm. Preferably, the

Aluminum alloy has a strength of at least 500 N / mm ² . With this structure, it is possible to achieve a weight reduction of the bottom plate 20 of about 35% to 50%, satisfying existing requirements (eg good traction with rollers of freight conveyors, high stability). Since the main weight of a conventional freight container 10 is still in the bottom plate 20, thus the total weight is significantly reduced. This results in the transport of the freight container 10 with an aircraft to a significant fuel savings, which in turn results in a lower C0 ₂ emission.

Fig. 3 shows another embodiment of a bottom plate 20, wherein this is constructed in three layers. In a top-down order, this bottom plate 20 has a wear layer 23, a core 40 consisting of a CFK layer 42 as a core layer and a support layer 21. The wear layer 23 may be made of glass fiber reinforced plastic or aramid. The overlay layer 21 is made of a metal alloy, preferably one

Aluminum alloy, made. A wear layer thickness h3 amounts to approx. 0.25 to 0.5 mm, while the core layer thickness h2 approx. 3 mm and the

Layer thickness hl is approx. 1 mm.

This embodiment of the bottom plate 20 as sandwich panels has the advantage that the at least one core layer (eg CFK layer 42) is protected by the wear layer 23. Furthermore, the multilayer structure leads to an increase in the stability of the entire base plate 20. In another

Embodiment, the wear layer 23 also from a

Aluminum alloy, z. 7075 T7 or 7075 T6. Theoretically, a steel sheet could also be used, but an electrically non-conductive layer should be preferred, as this has no influence on RFID tags 14 (see FIG. 1) possibly provided on or in the freight container 10.

The floor panel 20 according to the invention preferably has a revolving floor panel profile 25 (Figure 4) which can be inserted into a container corner profile to secure the floor panel 20 to the side walls 12a-12d. It can therefore on additional fastening means, for. Legs

Welded connection or rivets are dispensed with.

The freight containers 10 according to the invention preferably have a bottom plate 20, which are equipped at the bottom with a support layer 21, which is made of a metal alloy, in particular an aluminum alloy. This results in having existing cargo decks of aircraft with

corresponding cargo conveyors for transporting the freight container 10 can be used without problems occur with respect to the coefficients of friction during engagement of the rollers provided thereon. The freight container 10 according to the invention are therefore universally applicable.

Preferably, the bottom plate 20 is thus at least two layers, in particular constructed in three layers and designed as a composite material or composite material. A compound of the individual layers, in particular the

Pad layer 21 and / or core layer and / or wear layer 23, carried by material or form fit, with a fabric bond is preferable. A Connection between the individual layers can be made directly or indirectly.

In the described embodiments, the cuboid configuration of a freight container 10 has been discussed in detail. For the person skilled in the art it should be obvious that the shape of the freight container 10 is purely exemplary and can be arbitrary. Frequently used freight containers 10 have a bevel in the upper region in order to optimally fit them to the

Adapt cargo hold of an aircraft.

Further exemplary embodiments of the cargo compartment floor 20 will be apparent from FIGS. 5 and 6.

Fig. 5 shows a cargo hold floor 20 having a core 40 and a

Pad layer 21 has an aluminum alloy. The core 40 is made of a CFK layer 42 and a rubber layer 47 with the

Pad layer 21 connected. The rubber layer 47 may be bonded to the CFK layer 42 and / or the overlay layer 21. It is conceivable to use a PU adhesive. Alternatively, the rubber layer 47 may be vulcanized onto the support layer 21 and / or the CFK layer 42.

Another embodiment is shown in FIG. 6 forth. The core 40 is multilayered in this example and connected via a rubber layer 47 as a connecting layer with the support layer 21. The core 40 comprises a foam layer 43, wherein alternately the foam layer 43, a first CFK layer 42 and a second CFK layer 44 are arranged. The foam layer 43, the first CFRP layer 42 and the second CFRP layer 44 are glued together via a synthetic resin. Preferably, the

Foam layer 43 honeycomb-shaped recesses, which allow the cured resin makes a direct material connection between the first CFRP layer 42 and the second CFRP layer 44. In this respect, the foam layer 43 sheathed by the CFK layers 42, 44 is particularly well suited for picking up vertical loads without causing compression of the core 40. The cured resin in the recesses of the foam layer 43 thus forms a Stürz structure. On the side facing away from the support layer 21 of the first CFRP layer 42, a GRP layer 41 is arranged. This GRP layer 41 may be a wear layer 43, which is the protects first CFK layer 42 from wear. It is possible to bond the GRP layer in the course of the production of the core 40 with this.

The CFRP layer 42 may comprise a first network of glass fibers and the first CFRP layer 42 a second network of plastic fibers with the fibers of the first network disposed at a 45 degree angle to the fibers of the second network. Overall, therefore, the following structure could result: + 45 / -45 degree GFRP layer, 0/90 degree CFRP layer, foam core (eg Rohacell), 0/90 degree CFRP layer.

The first CFRP layer 42 may, for example, have a thickness of 0.2 mm to 0.6 mm, in particular 0.4 mm. The foam layer 43 may have a thickness of 1.0 to 8.0 mm, in particular from 1.8 to 6.0 mm. The second CFRP layer 44 may have similar or identical thickness ratios as the first CFRP layer 42. The overlay layer 21 in the embodiment shown has a thickness of 1.0 to 1.5 mm and consists of 2024 T3.

In one embodiment, on both sides of a core, e.g. B. a core 40, as described above, a metal layer, for. B. aluminum, arranged. The connection between the layers can be done by gluing and / or vulcanization. This sandwich arrangement has the advantage that the base plate 20 deforms only slightly with temperature fluctuations. Also, the manufacturing process is easy as the

Pad layer 21 and the wear layer 23 of metal or from a

Metal alloy in a manufacturing step connected to the core 40, z. B. glued, can be. In one embodiment, the bonding of the layers may be carried out under temperature (eg greater than 20 °, greater than 30 °, greater than 40 °).

The design of the freight container and the base plate 20 used therein has been described above. According to the application, a method for producing a corresponding base plate 20 or a cargo container floor as well as a production method for producing a freight container 10 should also be recorded. For example, a method of manufacturing a cargo container floor may include the following steps: - Producing the core layer 22 of carbon-reinforced and / or glass-fiber reinforced plastic;

- Producing a support layer 21 of a metal alloy, in particular of the already described aluminum alloy;

- Connect the support layer 21 with the core layer 22 by material bond and / or material connection.

The production steps mentioned can be carried out before joining the layers. Theoretically, however, it is also conceivable to produce one of the layers first and then to build up the further layer on this base layer. For example, the aluminum alloy may form the base layer on which the core layer 22 with the carbon reinforcement and / or glass fiber reinforcement and / or aramid fiber reinforcement is produced successively.

Furthermore, in the method according to the invention, a wear layer 23 can be applied. Again, it is possible to first make the support layer 21, the core layer 22 and the wear layer 23 and then produce a material connection between the individual layers.

Alternatively, the overlay layer 21 and the wear layer 23 may be formed, and the core layer 22 successively formed on the overlay layer 21 and / or the

Wear layer 23 are constructed. The composite may then be made by joining the overlay layer 21 with or without the core layer 22 and the wear layer 23 with or without the core layer 22.

It should be apparent to those skilled in the art that there are numerous alternative embodiments to the manufacturing process. Likewise, it should be readily apparent to the person skilled in the art how to get involved

inventive freight container 10 can be produced. Furthermore, one skilled in the art should know how to make the cargo floor of the invention as part of a cargo pallet.

Hereinafter, a variety of embodiments for realizing the invention will be described.

Embodiment 1.1: Cargo floor comprising:

 a core layer 42, 43, 44 of carbon fiber reinforced and / or glass fiber reinforced and / or aramid fiber reinforced plastic and

 - A support layer 21 made of a metal alloy, in particular of an aluminum alloy, wherein the core layer 42, 43, 44 and the support layer 21 are connected to each other by material connection and / or positive engagement.

Embodiment 1.2:

 Cargo floor according to embodiment 1.1,

d a d u r c h g e ke n ze i c h n e t that

the support layer 21 has a thickness hl of 0.5 mm to 2.5 mm, in particular from 0.7 mm to 1.5 mm, in particular from 0.9 mm to 1.5 mm.

Embodiment 1.3:

 Cargo floor according to one of the preceding embodiments,

d a d u r c h e n c i n e c e n s that

the support layer 21 has a strength of more than 400 N / mm ² , in particular more than 500 N / mm ² .

Embodiment 1.4:

 Cargo floor according to one of the preceding embodiments,

marked by

a wear layer 23 or cover layer, which is arranged on the side facing away from the support layer 21 of the core layer 42, 43, 44, wherein the

Wear layer 23 and the core layer 42, 43, 44 preferably by

Material connection and / or positive connection are connected.

Embodiment 1.5:

 Cargo floor according to one of the preceding embodiments, in particular according to embodiment 4,

d a d u r c h g e k e n c i n c e n s that

the wear layer 23 is formed of a metal alloy, in particular of an aluminum alloy, and / or a glass fiber reinforced plastic and / or a material from the group of aromatic polyamides.

Embodiment 1.6: Cargo floor according to one of the preceding embodiments, dadurchge ke nnzeichnet that

at least one of the aluminum alloys is an aluminum wrought alloy with the main alloying element zinc, in particular with 0.7 to 13.0% zinc,

especially 0.8 to 12.0% zinc.

Embodiment 1.7:

 Cargo floor according to one of the preceding embodiments,

d a d u r c h e n c i n e s that

at least one of the aluminum alloys an aluminum alloy with a solution-annealed and / or warm-outs and / or over-hardened

Heat treatment is.

Embodiment 1.8:

 Cargo floor according to one of the preceding embodiments,

d a d u r c h e n c i n e s that

the core layer 42, 43, 44 has a thickness h2 of at least 1 mm, in particular at least 1.5 mm, in particular at least 2 mm.

Embodiment 1.9:

 Cargo floor according to one of the preceding embodiments,

d a d u r c h e n c i n e s that

the core layer 42, 43, 44 comprises a solid core.

Embodiment 1.10:

 Cargo floor according to one of the preceding embodiments,

d a d u r c h e n c i n e s that

the wear layer 23 has a thickness of 0.1 to 1 mm, in particular from 0.2 to 0.6 mm, in particular from 0.25 to 0.5 mm.

Embodiment 2.1:

 Cargo container comprising a cargo floor according to one of the preceding embodiments as well as arranged on the cargo floor 20 side walls 12a - 12d.

Embodiment 2.2: Freight container according to embodiment 2.1,

d a d u r c h g e ke n ze i c h n e t that

the cargo floor 20 comprises an edge profile 25 running around at least in sections, in particular in the form of a bead, for connecting the side walls 12a-12d to the cargo floor (20).

Embodiment 2.3:

 Freight container according to embodiment 2.1 or 2.2,

d a d u r c h e n c i n e s that

the side walls 12a-12d are at least partially made of glass fiber reinforced and / or carbon fiber reinforced plastic.

Embodiment 3:

 Use of a multilayer panel comprising:

 a core layer 42, 43, 44 of carbon fiber reinforced and / or glass fiber reinforced plastic and

 - A support layer 21 made of a metal alloy, in particular

Aluminum alloy, for the production of a cargo floor 20, in particular according to one of the embodiments 1.1 to 1.10.

Embodiment 4:

 Method for producing a cargo floor, in particular a cargo floor 20 according to one of the embodiments 1.1 to 1.10, comprising the steps:

 - Producing a core layer 42, 43, 44 of carbon-reinforced and / or glass fiber reinforced plastic;

 Preparing a metal alloy overlay layer 21,

 in particular of aluminum alloy;

 - Connecting the support layer 21 with the core layer 42, 43, 44 by

Material connection and / or material connection.

LIST OF REFERENCE NUMBERS

10 freight containers

 12a to 12d sidewall

13 cover plate 14 RFID tag

 20 base plate

 21 contact layer

23 wear layer

25 base plate profile

40 core

 41 GRP layer

 42 CFRP layer

 43 foam layer

44 CFRP layer

 47 Rubber layer h Cargo container height b Cargo container width

1 freight container length hl bearing layer thickness h2 core layer thickness h3 wear layer thickness

Claims

claims

1. Cargo floor comprising:

 - At least one core layer (42, 43, 44) made of carbon fiber reinforced and / or glass fiber reinforced and / or aramid fiber reinforced plastic and

 - A support layer (21) made of a metal alloy, in particular of an aluminum alloy, wherein the core layer (42, 43, 44) and the support layer (21) are interconnected by material bond and / or positive engagement.

2. Cargo floor according to claim 1,

 marked by

 a core (40) comprising at least one first core layer (42, 43, 44) having at least one first fiber orientation and at least one second core layers (42, 43, 44) having at least one second fiber orientation, wherein the first fiber orientation is preferably about

 at least 20 degrees, or at least 30 degrees, or at least 40 degrees, or at least 45 degrees, or at least 90 degrees different from the second fiber orientation.

3. Cargo floor according to one of the preceding claims,

 d a d u r c h e c e n c i n e s that

 the at least one core layer (42, 43, 44) comprises a fiber network

 Carbon fibers and / or glass fibers and / or aramid fibers, preferably a first plurality of

 Carbon fibers / glass fibers / aramid fibers substantially perpendicular to a second plurality of carbon fibers / glass fibers / aramid fibers.

4. Cargo floor according to one of the preceding claims,

 d a d u r c h e n c i n e s that

 at least one core layer (42, 43, 44) comprises a foam layer (43), in particular a resin-impregnated foam layer.

5. Cargo floor according to one of the preceding claims,

in particular according to claim 4, dadu rc hge ke nn ze ichn et that

 the foam layer (43) has a support structure, in particular a

 honeycomb support structure.

6. Cargo floor according to one of the preceding claims,

 in particular according to claim 4 or 5,

 d a d u rc h e ke n ze i c h n et that

 the foam layer (43) is interposed between a first core layer (42) of carbon fiber reinforced and / or glass fiber reinforced and / or aramidfaserverstärktem plastic and a second core layer (44) made of carbon fiber reinforced and / or glass fiber reinforced and / or aramidfaserverstärktem plastic, wherein the layers preferably connected by material connection.

7. Cargo floor according to one of the preceding claims,

 d a d u rc h e ke n ze i c h n et that

 at least one core layer (42, 43, 44) on a side facing the support layer (21) comprises a connecting layer (47), in particular a connecting layer (47) from the group of elastomers, for connection to the support layer (21).

8. Cargo floor according to one of the preceding claims,

 in particular according to claim 7,

 d a d u rc h e ke n ze i c h n et that

 the bonding layer (47) is joined to the core layer (42, 43, 44) and / or the overlay layer (21) by adhesion, in particular by vulcanization.

9. Cargo floor according to one of the preceding claims,

 d a d u rc h e ke n ze ze ch n et that

 the support layer (21) has a thickness (hl) of 0.5 mm to 2.5 mm,

 in particular from 0.7 mm to 2 mm, in particular from 0.9 mm to 1.5 mm.

10. Cargo floor according to one of the preceding claims,

 d a d u rc h e ke n ze ze ch n et that

the support layer (21) has a strength of more than 300 N / mm ² , in particular more than 400 N / mm ² , in particular more than 500 N / mm ² .

11. Cargo floor according to one of the preceding claims,

 marked by

 a wear layer (23) or cover layer, which on the

 Pad layer (21) facing away from at least one core layer (42, 43, 44) is arranged, wherein the wear layer (23) and the

 Core layer (42, 43, 44) are preferably connected by material bond and / or positive connection.

12. Cargo floor according to one of the preceding claims, in particular according to claim 11,

 d a d u r c h g e k e n c i n c e n s that

 the wear layer (23) is formed from a metal alloy, in particular from an aluminum alloy, and / or a glass fiber reinforced plastic and / or a material from the group of aromatic polyamides.

13. Cargo floor according to one of the preceding claims,

 d a d u r c h e n c i n e c e n s that

 at least one of the aluminum alloys is an aluminum wrought alloy with the main alloying element copper, in particular with 0.5 to 9% copper, in particular 0.7 to 8.0% copper.

14. Cargo floor according to one of the preceding claims,

 d a d u r c h e n c i n e s that

 at least one of the aluminum alloys is an aluminum alloy with a solution-annealed and / or warm-outsided and / or

 overheated heat treatment is.

15. Cargo container comprising a cargo floor according to one of

 preceding claims as well as on the cargo floor (20) arranged side walls (12a - 12d).

16. Freight container according to claim 15,

characterized in that the cargo floor (20) at least partially circulating

 Edge profile (25), in particular in the form of a bead, for connecting the side walls (12a - 12d) with the cargo floor (20).

17. Freight container according to claim 15 or 16,

 d a d u r c h e n c i n e s that

 the side walls (12a - 12d) at least in sections

 are made of glass fiber reinforced and / or carbon fiber reinforced plastic.

18. Use of a multilayer panel comprising:

 - At least one core layer (42, 43, 44) made of carbon fiber reinforced and / or glass fiber reinforced plastic and

 - A support layer (21) made of a metal alloy, in particular

 Aluminum alloy, for the production of a cargo floor (20),

 in particular according to one of claims 1 to 14.

19. A method for producing a cargo floor, in particular a

 A cargo floor (20) according to any one of claims 1 to 14, comprising the steps of:

 - Producing a core (40) having at least one core layer (42, 43, 44) made of carbon-reinforced and / or glass-fiber reinforced plastic;

Producing a metal alloy coating layer (21),

 in particular of aluminum alloy;

 - Connecting the support layer (21) with the core layer (42, 43, 44) by material adhesion and / or material closure.

20. A method for producing a cargo floor, in particular a

 Cargo floor (20) according to claim 19,

 d a d u r c h e n c i n e s that

 the connection by applying and / or vulcanizing a

Connecting layer of the group of elastomers takes place.