NO320548B1 - Method for manufacturing a grid structure as well as grid structure prepared by the method - Google Patents

Description

The invention relates to a method for producing a net construction as stated in the introduction to independent patent claim 1, as well as a net construction as stated in the introduction to patent claim 5.'

The net structure is specially intended for use as a safety net to prevent falling, flying or swinging objects from accidentally hitting and damaging a structural part, installation or facility. In addition, a small mesh width is often desired so that the net can stop smaller objects such as hand tools from injuring personnel. Such nets are used tensioned or attached instead of protective walls or cover structures made of solid materials, for example steel walls or the like, on offshore platform forms or other installations. This is because, for example, they provide far greater accessibility to the construction part or the plant/installation they are to protect than a conventional retaining wall, ceiling or floor, as they can be easily removed, put back out and tightened.

Extreme demands are placed on the strength of such nets and consequently rope is used in the manufacture which has the required breaking strength as well as an acceptable coefficient of expansion before breaking. Conventionally, the net is provided by tying the ropes together so that meshes are formed in a way that can, for example, be compared to ordinary fishing nets or trawl line. Under bmk, the net is strung up like a wall, ceiling or floor. It is often a requirement that the safety net has minimal deflection when the net is hit by an object to prevent damage to the object the safety net is supposed to protect.

As mentioned, the conventional nets use knots to provide the meshes. These knots have the highest strength when the meshes stand as an upright equilateral parallelogram and the load goes in the direction of the parallelogram's longest extent. In this direction, however, the net meshes will easily stretch a lot under the influence of a shock load with large and often unacceptable deflection of the net.

It is possible to tension the net so that the meshes are in a square, but then the direction of the force is such that the knots have a further significantly reduced strength. In addition, the threads of which the net is made up will not be continuous in the direction of force, i.e. vertically or horizontally, but run in a stair-shaped pattern where each mesh represents a step and, under heavy load, the net will constrict and not retain its net structure. This applies in particular to ropes made of modern synthetic fibers where the strength in terms of weight can be 15 times higher than steel and where conventional net knots do not hold.

However, the knots also mean that the net's deflection resistance is adversely affected as they will constitute extension centers for the ropes which are joined together, with the result that the net wall exhibits greater compliance than it would have done without the knots. Moreover, the knots will represent a significant weakening of the wall construction's breaking strength, and they will cause an unfavorable increase in dimensions when the net is folded together. Since we are talking about nets with relatively large dimensions, the increase in weight due to the knots will also be noticeable. It can also be mentioned that the rope materials used are very expensive and just the increase in the amount of rope as a result of the knots represents a not insignificant increase in costs.

As a concrete example of the closest prior art, reference can be made to US-Al 4 000 344 where a net made of standard braided rope as raw material is described and the meshes are made by sawing. Compared to the invention, however, there is a significant difference in that the rope is threaded through and is threaded through each corner of the mesh so that the continuous rope runs in a stair shape (horizontally or vertically) if the net is stretched out in a square pattern. This in turn leads to much more slack in the mesh when it is tensioned regardless of whether it is tensioned in diamond mesh where the side walls themselves, due to the geometric shape of the mesh, will give slack, or in a square shape where it will not be continuous threads that prevent stretching. In the publication's column 1, lines 24 to 35, a solution is given where a crossing is formed between two parts of the length of the mesh wire by threading such a length part through a hole formed in the other of the parts, but this solution is determined to exhibit the disadvantage , in certain areas of use, that the crossing could slip if special measures are not taken to prevent this sliding. However, any solution proposed by the present invention is neither shown nor implied.

As related prior art, reference can also be made to GB - A 303 111 and A 489 200 as well as US-A1 2 402 709, 3 252 676, 5 869 162, 6 408 732, 6 559 077, 3 129 632 and 6 076 448 , but the technique described in these publications is further from the invention than the aforementioned US patent and does not solve the problems underlying the invention either.

There is thus an obvious potential for improvement in the known methods for producing nets of this type, as well as nets produced by the method.

The invention addresses the shortcomings as indicated above and aims to provide a method for producing a net construction as well as a net construction produced by the method, where the strength of the net construction is optimized in relation to weight and volume.

This is achieved according to the invention with a method and network construction of the type mentioned at the outset, which is characterized by what is stated in the characteristics of the respective patent claims 1 and 5.

Advantageous embodiments of the invention appear from the independent patent claims.

The invention will now be described with reference to the drawing therein; Fig.l shows in section, schematically, a principle design of the net construction according to the invention and;

Fig. 2 shows, in section, a special embodiment of the invention.

In fig. 1, the reference number 1 denotes a net construction according to the invention with mainly square net meshes. The reference numerals 2 and 3 denote ropes or ropes used for the net construction, for the sake of simplicity or clarity referred to as so-called first rope 2 and second rope 3, while the reference numeral 4 denotes a thread through or through. The penetration/penetration 4 is shown as a black rectangle. The longitudinal extent of the rectangle indicates the rope that is threaded through and consequently the shortest part indicates the direction of execution.

When the net construction 1 is to be produced, two mainly parallel first rope groups and two mainly parallel second rope groups are provided, which rope groups are arranged mainly perpendicular to each other, and consist of respective first rope 2 and second rope 3. The rope groups are provided as a net structure as can be seen from fig. 1 with vertical and horizontal reps in the drawing plane. Threading 4 is provided by the rope 2, 3 which is to be threaded being pressed together in the longitudinal direction or influenced in another appropriate way so that a bulge or the like is formed as the cords forming the rope are forced somewhat apart where an insertion and penetration can be made. This can, for example, be provided with the help of a conventional splicing tool which is used to thread one rope through a second perpendicular rope.

Seen from the left in fig. 1 the following operations are carried out:

A first vertical first rope 2 is threaded through 4 a first horizontal second rope 3, a second vertical first rope 2 is threaded through 4 of the first second rope 3, a third vertical first rope 2 is threaded through 4 the first horizontal second rope 3, a fourth vertical first rope 2 is threaded through 4 of the first horizontal second rope 3, etc and the second horizontal second rope 3 is threaded through 4 of the first vertical first rope 2, the second horizontal second rope 3 is threaded through 4 of the second vertical first rope 2, the second horizontal second rope 3 is threaded through 4 of the third vertical first rope 2, the second horizontal the second rope 3 is threaded through 4 of the fourth vertical first rope 2, etc. until the entire net is provided.

The process can of course be carried out in reverse order, i.e. starting with the respective horizontal second ropes 3 which are threaded through 4, or threaded through 4 of, the vertical first ropes 2. The process can also be thought of as a combination of different threading and threading sequences.

Briefly summarized, the method according to the invention thus consists in the ropes 2, 3 which are to form a net construction 1 consisting of net meshes being joined in such a way that the respective corners of each net mesh are provided by each net mesh being formed by respective perpendicular ropes 2 and 3 of which one rope 2 or 3 is threaded through the other rope 3 or 2 and the second rope is threaded through the first rope, as the order between the threading of the rope and the threaded rope is alternated so that a rope is first threaded through a perpendicular rope, and at a suitable distance from the thread through, depending on the mesh size, another perpendicular rope is threaded through which is parallel to the first rope, so that in each stitch space a joining of the ropes is provided when parallel ropes are brought together so that a threaded rope lies against against a perpendicular, pierced rep.

In this way, a net construction is provided where the respective corners of each net mesh consist of respective perpendicular ropes 2 and 3, of which one rope 2 or 3 is threaded through the second rope 3 or 2 and the other rope is threaded through the first rope, the order between Threading of rope and threaded rope are provided alternately so that a rope is first threaded through a perpendicular rope, and at a suitable distance from the threading, depending on the mesh size, threaded through another perpendicular rope that is parallel to the first rope, so that in each stitch space, a joining of the ropes is provided when parallel ropes are brought together so that a threaded rope rests against a perpendicular, threaded rope.

Often, a loop at the end of a piece of rope or rope for direct connection to supporting structures will be beneficial with regard to minimal tension in the net. This is done by splicing a loop at the end of the ropes and then using the described net-making method with the only difference being that the ropes where the splice is, are thicker than the rest of the rope.

Fig. 2 shows an example of a preferred net construction. In this case, each mesh is formed by two parallel pairs of first rope 2 and two parallel second rope 3, which are provided perpendicular to each other. The respective two pairs of first rope 2 are provided close to each other. Treeings and the through-tree 4 are provided in the same way as in the net construction in fig. 1, but since each of the parallel pairs is provided so close to each other, an immediate interlocking of the ropes 2 and 3 in the corners of the mesh will be achieved and the maximum opening or size of the mesh will be smaller and can thus stop a small object more effectively.. This appears evident from fig. 2 that due to the threading directions, the ropes in all the respective mesh hems will be joined together. This solution provides a further reinforced mesh construction in the direction of the adjacent parallel ropes, which will be particularly beneficial where the forces caused by the object to be stopped must be taken up in one direction, for example if the mesh wall is only tensioned at the top and bottom.

With the net construction according to the invention, not only is a stronger net achieved with less deflection under loads than the conventional knotted nets, but the net is also far less bulky when there are layers together and the weight saving is significant since the knots are omitted.

Instead of two parallel pairs of ropes or ropes, it is also conceivable that the horizontal ropes in fig. 2 is replaced by two adjacent horizontal ropes (not shown).

Instead of parallel pairs consisting of two ropes, it is also conceivable that several ropes can be included in each pair, but due to the costs, such a solution will probably only be interesting under certain circumstances.

The rope that is used preferably consists of a braided cord structure, but other suitable structures that will retain a threaded rope laterally can of course also be used. The rope material is preferably selected from the group comprising "High-Tech" artificial fibers or similar, such as Aramid, Kevlar, Dyneema, Spectron or similar materials. The diameter of the rope or rope used is chosen according to the load the net must withstand, the maximum acceptable mesh width and in which direction the forces are mainly to be taken up. Different diameters of the ropes can of course be used vertically or horizontally so that, for example, horizontally the ropes have a diameter of 5 mm and vertically 12 mm. The latter will be beneficial in cases where, for example, the net is only tensioned at the top and bottom.

Claims (10)

1. Method for producing a net construction (1) comprising net meshes provided by first and second ropes (2, 3) of braided cord structure, each net mesh being formed by the respective ropes (2, 3) of which the first rope (2,3) is threaded through the the second rope (3,2) and the second rope is threaded through the first rope, characterized by the order between threading through the rope and threaded rope is arranged alternately so that a rope is first threaded through a perpendicular rope, and at a suitable distance from the threading, depending of the mesh size, another perpendicular rope is threaded through which is parallel to the first rope, so that in each stitch space a joining of the ropes is provided when parallel ropes are brought together so that a threaded rope abuts a perpendicular, threaded rope. 2. Method according to claim 1, characterized in that two mainly parallel first rope groups and two mainly parallel second rope groups are provided, which rope groups are arranged mainly perpendicular to each other, and consist of respective first ropes (2) and second ropes (3), with the rope groups being provided as a net structure with in the horizontal plane vertical and horizontal ropes and threading (4) is provided by the rope (2, 3) to be threaded being pressed together in the longitudinal direction or influenced in another appropriate way so that a bulge or the like is formed as the cords that form the rope are forced somewhat apart where the an insertion and passage can be made using a suitable tool that is used to thread one rope through a second perpendicular rope. 3. Method according to claim 2, characterized in that a first vertical first rope (2) is threaded through (4) a first horizontal second rope (3), a second vertical first rope (2) is threaded through (4) of the first second rope (3), a third vertical first rope (2) thread through (4) the first horizontal second string (3), a fourth vertical thread string (2) thread through (4) the first horizontal second string (3), etc. and the second horizontal second string (3) thread through (4) the first vertical first rope (2), the second horizontal second rope (3) is crossed (4) by the second vertical first rope (2), the second horizontal second rope (3) is threaded through (4) by the third vertical first rope (2), the second horizontal the second rope (3) is threaded (4) through the fourth vertical first rope (2), etc., until the entire net is provided. 4. Method according to claim 3, characterized in that threading is carried out in reverse order, starting with the respective horizontal second ropes (3) which are threaded through (4), or threaded through (4) of the vertical first ropes (2), possibly done as a combination of different treeing and treeing sequences. 5. Net construction (1) comprising net meshes provided by ropes of braided cord structure, each net mesh being formed by the respective ropes (2, 3) of which one rope (2,3) is penetrated by the other rope (3,2) and the other rope (2,3) is threaded through the first rope, characterized in that the order between ropes that are threaded through another rope and threaded rope is arranged alternately so that a first rope is threaded through a second perpendicular rope, and at a suitable distance from the threading , depending on the mesh size, threaded through a second perpendicular rope which is parallel to the first rope, so that in each stitch space a joining of the ropes is provided when parallel ropes are brought together so that a threaded rope rests against a perpendicular, threaded rope. 6. Net construction according to claim 5, characterized in that each net mesh is formed by two parallel pairs of ropes (2) provided close to each other, each pair forming respective opposite mesh walls, and two parallel ropes (3) arranged perpendicular to the rope pairs, and at a distance corresponding to the distance between two opposite mesh walls, so that an immediate interlocking of the ropes (2) and (3) is achieved in the corners of the mesh. 7. Net construction according to claim 6, characterized in that the parallel ropes (3) are replaced by parallel, closely adjacent pairs of ropes or ropes. 8. Net construction according to claim 6 or 7, characterized in that the closely adjacent rope pairs comprise at least two ropes (2). 9. Net construction according to any one of claims 1-8, characterized in that the ropes or ropes (2,3) have a diameter of approximately 5 mm. 10. Net construction according to any one of claims 1-8, characterized in that the vertical and horizontal, or perpendicular ropes/ropes in the net construction have different diameters.