NO812418L - BUILDING GROUP FORMING AN EDGE IN AN ANGLET HOLE BODY, EXAMPLE A SHIP LOAD CONTAINER - Google Patents

Description

The invention relates to a construction group which forms

one edge in an angular hollow body, for example a shipping container and which is formed by a steel angle iron arranged in the corner and a building element running parallel to it,

which components hold the edges of lightweight building boards using flanges parallel to the edges.

In a well-known building group of this type, the light, plywood-made walls are placed with their outer surfaces directly against the flanges of the steel angle iron and fixed by means of screw bolts. The angle iron can be braced, as the flanges are provided with indentations running in the longitudinal direction or the angle iron has a hollow cross-sectional profile.

This bracing of the angle iron increases its weight

to a considerable extent.

With regard to the state of the art, reference should also be made here to the German patent documents 200 772 and 586 832, from which it is known for a corner connection for containers in addition to an angle iron arranged in the corner and at a parallel distance to arrange a rail-shaped building element which is connected to the angle iron by means of screws and, together with the angle iron, clamps the container's wall edges between flanges.

US patent document 3 261 49 3 shows a device in which U-shaped profiled and 4 5° intake profiles are arranged at the edges of the container wall. Two such recording profiles can thus be put together to form an angle of 90°, and they are held together by means of a strip arranged in the corner.

All of the construction groups belonging to the state of the art for the edges of angular hollow bodies have so far had a very large weight for achieving high strength, especially taking into account that the stresses are quite significant during transport by ship and similar conditions.

The purpose of the invention is to design the building group so that it can be made significantly lighter while retaining its strength, or that a higher strength can be achieved with reduced weight. The aim is also to reduce the corner construction group weight's share of the total weight of an angular hollow body, especially a ship's cargo container, so that one can thereby increase the usable cargo weight and make full use of the hollow body's or the container's volume.

According to the characteristics of claim 1, this is achieved by

that a building group that forms an edge in an angular hollow body, for example a shipping container, where a steel angle iron arranged in the corner and a building element running parallel to it holds the edges to light building plates using

of flanges with parallel edges, is characterized by the fact that a plastic stiffening element reinforced with tensile fibers rests against and is rigidly connected to the angle iron.

The rigid connection between the angle iron and

the plastic stiffening element attached to this internally and reinforced with tensile fibers leads to an unexpectedly high combined strength at a relatively low weight,

which is superior to the firmness of the known corner connections. The reinforcement of the plastic stiffening element with tensile fibers and the rigid connection with the angle iron are given particular importance here. For this reason, in particular, the angle iron can also be made significantly weaker and lighter than has been possible up until now.

The bracing element can be constructed as a uniform light construction profile beam, but it can also be composed of several parts (with an intermediate piece between the angle iron and the light construction profile beam).

Within the framework of the basic idea of the invention, a large number of designs are possible, all of which utilize the combined firmness effect of the angle iron and the plastic stiffening element reinforced with tensile fibers.

Parts of the building group can be formed from U-shaped profiled and also from fiber-reinforced plastic strips that are built together with the edges of the light walls. Various execution options are highlighted in the sub-requirements.

The drawings show various design examples of building groups that form an edge in an angular hollow body, e.g.

for example a shipping container. The drawings show:

fig. 1 a well-known building group,

fig. 2 shows a building group according to the invention, where the light walls are laid with their outer surfaces against the flange inner surfaces of the angle iron and with their inner surfaces abut against the flanges of the light building profile beam,

fig. 3 shows a construction group where each of the light plates rests against the flanges of the light construction profile carrier with both outer and inner surfaces,

fig. 4 shows a building group which differs se"g from the one shown in Fig. 3 in that the light building profile beam has a hollow cross-sectional profile,

fig. 5 shows a construction group that differs from that in fig. 4 with regard to the bevel of the corner of the angle iron,

fig. 6 shows a construction group that differs from that in fig. 4 in that the corner is rounded,

fig. 7 shows a construction group that differs from that in fig. 2 by using an intermediate piece against the angle iron that holds the light building profile beam at a distance from the angle iron,

fig. 8 shows a construction group that differs from that in fig. 6 with regard to the cross-sectional profile of the lightweight building profile beam,

fig. 9 shows a construction group similar to that in fig. 7, with hollow building profile beam,

fig. 10 shows a construction group as in fig. 2, but with a hollow construction profile beam,

fig. 11 shows a construction group similar to that in fig. 10, but where the angle iron has longitudinal indentations,

fig. 12 shows an embodiment with a hollow angle iron, with two flanges for each wall,

fig. 12a shows a cross-section through a construction group with U-shaped profiled strips and an angular profiled rod arranged at the edges of the walls as parts of the bracing element,

fig. 13 shows a cross-section through, a construction group where the angular profiled rod is provided with additional flanges,

fig. 14 shows a cross-section of a construction group

which contains a cavity lined with the walls of a second rod, and

fig. 15 shows a cross-section of a construction group

where the flanges of the angular profiled rod are stiffened with thickenings.

In the case of known shipboard containers, the corners are used, for example, in fig. 1 showed a building group consisting of an angle iron 10 made of steel and of light walls 12 and 14,

as the walls are attached to the flanges 16 and 17 of the angle iron

using screw bolts. The flanges are stiffened using longitudinal indentations to thereby increase the bending strength. The walls 12 and 14 can be plywood sheets that are coated on both sides with plastic or a sheet material. With such a design, the necessary bending strength for the construction group can only be achieved by using a relatively large wall thickness and a correspondingly heavy angle iron.

The plywood walls 12, 14 also contribute strongly

degree to the container weight. This means that a container with a room content of 40 m 3 weighs approx. 2 tons. As the permitted weight for loaded containers is limited, the container volume cannot be fully utilized when it comes to heavy bulk goods.

Fig. 2 shows a design of the building group, where the weight of the angle iron 10 can be reduced to a considerable extent. Namely, the light walls 20 and 22 lie with their inner surfaces against the flanges 24, 26 on a light building profile beam 28 which extends internally along the angle iron 10 and is rigidly connected thereto. This light building profile beam 28 rests on the inside against the angle iron 10. The angle iron is provided with surfaces 30 and 32 which extend parallel to the bisector plane 34 of the angle iron 10. The light building profile beam has the form of a strip provided with flanges 24 and 26 which has a sliding guide between the surfaces 30 and 32 across the angle iron and construction

the longitudinal direction of the profile beam.

In the plane 34, screw bolts pass through the angle iron 10 and through the construction profile beam 28, which screw bolts serve to rigidly attach the elements 10 and 28. In relation to the known construction group in fig. 1, the light walls 20 and 22 rest against the flanges 16 and 17 of the angle iron 10 under the influence of the force exerted by the screw bolts. Furthermore, each building plate 20 and 22 respectively can be penetrated by screw bolts which connect the two flanges 16 and 24 respectively 17 and 26 to each other. Thanks to this rigid fastening of the building plates 20 and 22 as well as the angle iron 10

as with the light building profile beam 28, the two walls will contribute significantly to the building group's bending strength.

By the one in fig. 3, the light construction profile beam 328 has, in addition to the two flanges 124 and 326, parallel to these continuous flanges 336 and 338 which abut against the flanges 316 and 317 of the angle iron 310. The construction group in fig. 3 differs from that in fig. 2 in that the two light walls 320 and 322 do not abut against the angle iron with their outer surfaces, but against the light building profile beam's 328 flanges. The individual parts are rigidly connected to each other by means of screw bolts, in the same way as described above in connection with fig. 2.

The one in fig. 4 shown construction group differs from that in fig. 3 mainly in that the lightweight building profile beam 428 is hollow. In addition, the outer edges of the two flanges 424 and 426 are connected to each other by means of a step 440. Otherwise, the parts that correspond to parts in the building group in fig. 3 provided with corresponding reference numbers, increased by 100, so that these parts do not require any special description. In addition to the screw bolts, located in plane 434,

further screw bolts are arranged in a transversely extending plane 442. The light walls are omitted in fig. 4.

One wall goes in between flanges 424 and 436 and the other goes in between flanges 4 36 and 4 38.

The one in fig. 5 shown construction group essentially corresponds to the construction group in fig. 2, but the light building profile beam 528 is hollow and the angle iron 310 lacks the guide rafts 30 and 32. The same reference number as in fig. 2, increased in a 100 series. Under the nuts on the screw bolts arranged in the plane 534, there is placed a base plate 544 which is adapted to the outer profile of the building profile beam 528.

The one in fig. 6 shown construction group differs from that in fig. 5 mainly in that the corner of the angle iron and the opposite side of the building profile beam are rounded. Here, too, the same reference number is used, in an ascending 100 series.

By the one in fig. 7 shown embodiment of a building group, the light construction profile beam 728 is held at a distance from the angle iron 710 by means of an intermediate piece 74 6 which is located internally against the angle iron 710 and is rigidly connected to the angle iron and the intermediate piece 746 by means of screw bolts arranged in the plane 734. The light walls, not shown, lie with their outer surfaces against the flanges of the intermediate piece 746, which intermediate piece is designed as a hollow profile. The light construction profile beam 728 is in this design example designed as an angle piece whose top point lies in a recess in the intermediate piece 746.

That in fig. 8, the design example of a construction group corresponds in the main to what is shown in fig. 6. While, however, the opposite walls in the hollow building profile beam 628 run parallel to the angle bisector plane 634, they run in fig. 8 at right angles to the flanges 816, 824 and 817, 826 respectively, so that they can lie flat against the edge surfaces of the walls.

That in fig. 9 shown embodiment of a construction group corresponds to a large extent to the embodiment in fig. 7, but the construction profile beam 928 is hollow and its corner is rounded.

That in fig. 10, the design example of a construction group corresponds in the main to the design in fig. 2, but the light construction profile beam 1028 is hollow and the corner of the angle iron 1010 is rounded. The flanges 1016 and 1017 also abut against the inner edges of the guide rafts 10 30 and 10 32. That in fig. 11 shown embodiment of a construction group differs from that in fig. 10 mainly in that the angle iron 1110 has a different profile. The flanges are provided with recesses 1118, so that the angle iron in this way has contact surfaces 1148 for the edge surfaces of the wall plates, which contact surfaces are at right angles to the flanges.

By the one in fig. In the embodiment shown in 12, a double-walled angle iron 1210 is used, the walls of which are connected to each other by means of transverse intermediate walls 1250

which confines a cavity. A hollow and light building profile beam 1228 is placed in this cavity. This can be connected to the angle iron 1210 by means of screw bolts that pass through the angle iron in planes 1234 and 1252.

In all of the described embodiments, the lightweight building profile beam consists of plastic and is reinforced with tensile fibers, for example carbon fibers, glass fibers or the like. The light walls consist of two outer skins, a body arranged between them of solid foam material and of tensile fibres, such as carbon fibres, glass fibers or the like for strengthening the light wall. These walls have a wall thickness that is sufficient for the desired thermal insulation, especially when low temperatures are to be maintained inside the body enclosed by the walls.

The hollow profile beam, and in the embodiment in fig. 7 and

9 the intermediate piece, preferably consists of a polyester or epoxy material with high strength, reinforced with tensile fibers, such as carbon fiber, glass fibers or fibers marketed under the trademark "Kevlar". Thanks to the bracing of the angle iron with the help of the building profile beam or intermediate piece, the wall thickness of the angle iron does not usually need to exceed three millimeters, at a length for the building group of a few metres. This gives a very low weight. At those in fig. 4-12 shown embodiments of the invention, the cavities in the building profile beam and the intermediate piece can be filled with a solid foam.

The building group, whose cross-section is shown in fig. 12a, forms a corner in a shipping container. The construction group consists of

a) of an angle iron provided with flanges 1210a which extends over the entire corner length of the container and is chamfered

in the corner, at 1212a

b) of light walls 1214a which are attached, for example glued to the flanges 1210a, and c) of an angle iron 1210a, 1212a reinforcing light building profile beam in the form of an angular profiled rod 1216a

of fibre-reinforced plastic, which rod internally extends along the angle iron 1210a, 1212a, parallel to this,

and with its flanges is attached, for example by means of adhesive, to the inner side of the light walls 1214a.

Such a construction group is shown, for example, in fig. 7. The further design of this building group consists here in that the walls 1214a are provided at their edges with U-shaped profiled strips 1218a which internally extend along the flanges 1210a of the angle iron, are rigidly connected to these and form parts of the light building profile beam, and thus likewise consists of fibre-reinforced plastic. By the one in fig. 12a shows the embodiment of the invention, the legs 1220a of the U-shaped profiled strips 1218a are directed away from the corner 1212a of the hollow beam.

In another embodiment of the invention,

which likewise proceeds from fig. 12a, the legs 1222a of a U-shaped profiled strip 1224a are directed towards the corner 1212a of the hole. The two flanges 1222a are connected in the same way as the flanges 1220a to the flanges 1210a on the angle iron and to the legs of the angular profiled rod 1216a, for example by means of a suitable adhesive. While in the one in fig. 12a, the two U-shaped profiled strips 1218a and 1224a are arranged between the angle iron's flange 1210a and the rod 1216a, either the strip 1218a or the strip 1224a can be omitted.

As shown in fig. 12a surrounds the angular profiled rod 1216a, the angle iron 1210a, 1212a arranged at a distance from the rod and the edge surfaces of the walls, which edge surfaces are provided with the U-shaped profiled strips 1218a or 1224a or both, a cavity 1226a. This cavity is lined with the walls of the two strips 1224a, which may optionally be produced as one part. This cladding therefore forms part of the light building profile beam, which consists of the elements 1216a, 1218a, 1224a and significantly reinforces the angle iron 1212a, so that the building group has a high bending and buckling strength.

The light walls 1214a may consist of two parallel light metal plates, the spaces of which are filled with a foam material and which may be connected to each other by means of holders which are distributed over the wall surfaces and extend through the foam filling.

The one in fig. 13, the design of the building group is very similar to the design in fig. 12a. This applies to the walls 1334 and to the U-shaped profiled strips 1338 arranged along the wall edges, which correspond to the strips 1318. The U-shaped profiled strips 1224a in fig. 12 has been replaced with angular profiled strips 1344. These have only one flange 1342 each, in contact with the angle iron flange 1330.

The second flange is attached to the angular profiled rod 1336 in that this additionally has two ribs 1345 and 1347 which surround the strip 1344 and are attached to this.

Also in this embodiment, a cavity 1346 appears. In the same way as the cavity 1226a, this can be filled with foam material. The corner of the angular profiled rod 1336 is in this case chamfered.

The one in fig. 14 shown embodiment of a construction group differs from that in fig. 13 in the main in that the two strips 1454 consisting of fiber-reinforced plastic and arranged at the edges of the walls, which correspond to the strips 1344, are connected to each other by means of a profile section 1455 which is attached adhesively to the beveled edge of the rod 1456. In this case too, the cavity 1466 can be filled with foam material.

The one in fig. 15 shown building group separates

from the one in fig. 12a mainly in that the legs of the angular profiled rod 1576 are stiffened by means of thickenings 1577. For the sake of simplicity, in fig. 15 the light walls and the angle iron not shown.

A particular advantage of those in fig. The construction groups shown in 12a-15 consist in the fact that they can be put together in a very simple and fast way.

From the preceding description, it is clear that the basic idea of the invention can be realized in various ways with a corner construction group of the type in question here, including a steel angle iron in the corner, with a plastic stiffening element reinforced with tensile fibers which interacts with the angle iron . Above all, the stiffening element can have different shapes and also be made up of different parts. The stiffening element can in particular also take the form of the described light building profile beams (for example 28, 72 8), the intermediate piece (for example 746), Unshaped profiled strips (for example 1218a). etc.

Claims (15)

1. An edge in an angular hollow body, for example a shipping container, forming a building group, where a steel angle iron arranged in the corner and a building element running parallel to it hold the edges to light building boards by means of flanges parallel to the edges, characterized in that a with tensile fibers reinforced stiffening element (28; 328; 428; 746; 946; 1216; 1218, 1224 etc.) made of plastic rests against and is rigidly connected to the angle iron (10; 310; 410; 1110; 1212 etc.). 2. Construction group according to claim 1, characterized in that the stiffening element is formed by a light construction profile beam (28 etc.) which in a manner known per se has flanges (24, 26, etc.) which are parallel to the flanges of the angle iron (16, 17, etc), against which beam flanges the light walls (20; 22; 320; 322, etc.) rest with their inner surfaces. 3. Building group according to claim 2, characterized in that the light walls with their outer surfaces abut additional flanges (336; 436; 1220, 1222) on the light building profile beam. 4. Building group according to claim 1, characterized in that the stiffening element includes an intermediate piece arranged between the angle iron and the light building profile beam (746; 946, etc). 5. Building group according to claim 4, characterized in that the light walls abut against flanges (754) on the intermediate piece. 6. Building group according to one of claims 1-5, characterized in that the connection of the stiffening element and the light building profile beam with the angle iron takes place by means of screw bolts which are arranged in the bisect plane of the angle iron (34; 434; 636, etc). 7. Building group according to one of claims 1-6, characterized in that the light building profile beam (928) or the intermediate post (946) or both are hollow. 8. Building group according to one of the claims 1-7, characterized in that the angle iron and the light building profile beam are provided with mutually sliding guiding surfaces (30, 32, 1030, 1032), which surfaces run parallel to the angle iron's bisector plane ( 34), as the sliding guide extends across the longitudinal direction of the angle iron and the building profile beam. 9. Building group according to one of claims 1-8, characterized in that the light walls consist of an outer layer, of a reinforcement of these layers with the help of tensile fibers and of a space between the layers filling in fixed foam. 10. Building group according to claim 7, characterized in that the cavity is filled with a solid foam. 11. Building group according to one of the preceding claims, characterized in that the light walls (1214a, 1234a) attached to the building group are provided at their edges with U-shaped profiled and fiber-reinforced plastic strips (1218a, 1224a, 1244a), which strips extends internally along the angle iron (1210a, 1212a), is rigidly connected to this and forms part of the bracing element. 12. Building group according to claim 11, characterized in that the legs (1220a) of the U-shaped profiled strips (1218a) are directed away from the corner of the hollow body. 13. Building group according to claim 11, characterized in that the legs (1222a) of the U-shaped profiled strip (1220a) face the corner of the hollow body. 14. Building group according to one of the claims 11-13, characterized in that the light building profile carrier includes an angularly profiled rod (1216a, 1336a, 1456a) made of fiber-reinforced plastic, which rod is held at a distance from the angle iron (1210a, 1212a) by means of the lists (1218a, 1222a). 15. Building group according to claim 14, characterized in that the angular profiled rod (1456), the angle iron (1210a, 1330a) arranged at a distance from this and the edge surfaces of the light walls (1214a) surround a cavity (1226a, 1466a) which is lined with the walls to a second angular profiled rod (1454) which likewise consists of fibre-reinforced plastic.