阅读说明：本技术 链，尤其是重载链 (Chain, in particular heavy-duty chain ) 是由 T·多勒奇 于 2019-10-02 设计创作，主要内容包括：本发明涉及一种链,该链具有多个相互连接的链节(6),所述链节分别由塑料丝(3、4)制成,其特征在于,每个链节(6)构成为至少一个由基于塑料丝(3、4)的扭绞的绳结构制成的无端部地放置的环、尤其是索环。(The invention relates to a chain having a plurality of interconnected chain links (6) each made of plastic wires (3, 4), characterized in that each chain link (6) is designed as at least one endless loop, in particular a grommet, made of a twisted rope structure based on the plastic wires (3, 4).)

1. Chain with a plurality of interconnected chain links (6), each of which is made of a plastic wire (3, 4), characterized in that each chain link (6) is designed as at least one endlessly placed ring, in particular as a grommet, which is made of a twisted rope construction based on the plastic wires (3, 4).

2. Chain according to claim 1, characterized in that the twisted rope structure essentially consists of at least one rope (1) made of plastic filaments (3, 4) placed continuously helically around the core.

3. Chain according to claim 2, characterized in that the rope (1) is designed as a woven rope made of plastic filaments (3, 4).

4. Chain according to claim 3, characterized in that the rope (1) is configured as a round-woven rope (1).

5. Chain according to any of claims 1 to 4, characterized in that the plastic filaments (3, 4) are constituted as multifilaments made of plastic fibers (2).

6. The chain according to any one of claims 1 to 5, characterized in that the plastic filaments (3, 4) are configured as high-tensile filaments having a maximum tensile force with respect to fineness of at least 5cN/dtex, typically 8cN/dtex and higher, in particular at least 10cN/dtex, preferably 20cN/dtex and higher, and particularly preferably at least 30 cN/dtex.

7. Chain according to any one of claims 1 to 6, characterized in that the plastic filaments (3, 4) are composed of, in particular, thermoplastic fibers as plastic fibers (2), for example based on PE, PA, PET, PP or the like.

8. The chain of claim 7, wherein the thermoplastic fibers are plastic fibers made of polyolefins having an ultra-high molecular weight.

9. Chain according to any of claims 1 to 8, characterized in that the fineness of the plastic filaments (3, 4) is at least 20 dtex.

10. A chain according to any of claims 1-9, characterized in that the respective ends (1a, 1b) of one or more of said ropes (1) are guided in the twisting direction under the outer rope (1) of the outer layer of ropes.

11. Chain according to any of claims 1 to 10, characterized in that the links (6) have a breaking strength or breaking force of at least 1 kN.

12. Chain according to any of claims 1 to 11, characterized in that the chain links (6) are directly engaged into each other or coupled to each other by means of a connecting piece (7).

13. Use of a chain according to any one of claims 1 to 12 for storing, securing, lifting and manipulating goods, loads and vehicles.

Technical Field

The invention relates to a chain, in particular a heavy-duty chain, having a plurality of interconnected chain links, each made of plastic wires.

Background

In practice, heavy duty chains are often used in which the chain links are made of steel. Furthermore, there are nowadays increasingly chains consisting of plastic wires and in particular heavy-duty chains, which are described, for example, in patent document EP 2122194B 1 as a whole. Herein, it relates to chains suitable for use in securing or anchoring ships, lashing loads for road, rail, water and space transportation, and for transportation, lifting, suspension and lifting applications. For this purpose, the chain links are constituted by multifilament yarns, which are themselves polyolefin multifilament yarns.

Furthermore, there are different chains in which the links consist of short fibers, which are adhesively connected to one another. Such chains as described in patent document EP 1063449 a1 are complex in their manufacture.

Finally, patent document EP 2858936B 1 describes a woven chain in which the individual chain links are made of a strip, which itself is designed as a woven belt made of plastic filaments. This results in a strip which is rotated by a plurality of 180 ° about its respective longitudinal axis. A closed loop is thus formed, which overall defines the chain links.

However, the result of this manufacturing scheme is an overall reduced breaking strength. That is, the forces that can be transmitted by means of such a chain and thus the breaking forces are reduced with respect to the non-wound loop, which can ultimately be attributed to the so-called "shrinkage losses". In fact, when the rings are connected to one another, a contraction of the plastic band occurs at the coupling point, which reduces the maximum breaking force that can occur. In this case, a shrinkage loss of up to 50% relative to the non-wound ring is actually observed. The invention herein provides benefits in its entirety.

Disclosure of Invention

The invention is based on the technical problem of further developing a chain of this type in such a way that the breaking strength is improved and the shrinkage losses are minimized as far as possible.

In order to solve this problem, a chain of this type within the scope of the invention is characterized in that each chain link is designed as at least one endless loop made of a twisted rope structure based on plastic wires. In particular, each chain link is a so-called grommet or rope ring, i.e. at least one endlessly operating ring made of twisted rope construction. The rope arrangement itself is here made of at least one or two ropes helically twisted around each other. In this way, the core required additionally in the center can be largely dispensed with. In the usual case, this is done by at least 4 and in particular 6 or more cords, which are each continuously twisted helically around one another and in this way form a cord structure, which itself defines an endlessly placed loop and thus a chain link.

In this case, provision is made in terms of the rope structure for the respective ends of the ropes to be guided in the twisting direction under the outer ropes of the outer rope layer. In this way, the grommet that defines the respective link forms an integral uniform loop consisting of a twisted rope structure that can be suspended, for example, into a round hook for lifting a load. Furthermore, individual links or grommets can thereby be joined into a chain by direct engagement into one another. In principle, however, it is also possible that the links are not joined into one another, but rather are coupled to one another by additional connecting elements.

The connector may be a metal circular hook, a ring made of plastic tape, or a similar loop-shaped connector. In addition, the chain according to the invention can be shortened particularly simply in order to achieve adaptation to the respective application purpose. Here, for example, it is possible to work with so-called shortening hooks or likewise correspondingly designed ratchets or chain tensioners, which, by means of the individual chain links, define an unloaded loop, effect a corresponding shortening of the chain.

In this case, according to the invention, the respective cord is designed as a woven and in particular round-woven cord made of plastic fibers. The plastic fibers themselves form an integral part of the plastic filaments, which are processed and regularly twisted into a rope. In this woven and in particular round-woven cord, it is provided that the cord, as in any other woven product, is composed of warp and weft threads, respectively. In this case, the entire design is concerned with the fact that the warp threads extend predominantly in the circumferential direction of the ring. In contrast, the weft filaments extend perpendicular to the warp filaments, primarily radially with respect to the loops. The round or mainly round cross section of the individual threads is realized and implemented in such a way that the warp threads define the different layers of the fabric. The circular or almost circular cross section of the woven and in particular circular-woven rope is now achieved, for example, by arranging warp threads having different numbers of the same diameter in the layers involved, so that the desired circular or circular cross section of the rope is obtained.

But it is also possible to make the warp filaments with different diameters. In this connection, it can be provided, for example, that the respective outer layer of the warp threads has a larger diameter than the inner layer of the circular cross section of the cord formed in this way. In contrast, it is common for the weft threads that interconnect the layers to work with weft threads of the same diameter. In order to connect the weft threads involved here not only to the warp threads of one layer but also to at least two or more layers of a round fabric, the principle of which is generally described in patent document EP 0089483 a1, working with devices for round weaving. Reference is made explicitly herein to the embodiments and explanations thereof.

Particularly preferably, a circularly woven rope made in a single-layer or double-layer cylindrical fabric weaving method is used. That is, a round-woven rope has an outer cylindrical fabric made of warp and weft. The cylindrical fabric itself can be designed in a single-layer or multi-layer fashion. Furthermore, a liner surrounded by a cylindrical fabric as a jacket can be realized. The inner liner may be a fabric (Gelege) composed of plastic filaments. Other liners are also contemplated.

In any case, the invention advantageously uses a woven and in particular a round-woven rope made of plastic fibers, wherein the round cross-sectional shape of the rope is obtained in such a way that a cylindrical round fabric and, if necessary, a lining are used in this case. In principle, the tubular fabric can also be designed in multiple layers.

Now, by twisting the warp filaments (including the weft filaments connecting the warp filaments) extending in the longitudinal direction with each other, i.e. spirally wound around a central rotational symmetry axis, it is possible to manufacture the woven or round-woven rope itself made in this way. Thus, at the end of the process, a single rope or a round-woven rope made of the plastic fiber concerned is provided.

The individual threads of the cord or the plastic threads, i.e. both the warp threads and the weft threads, are each formed as multifilament threads made of plastic fibers. The multifilaments are filaments each made of a plastic fiber having a practically unlimited length. Now, in order to realize multifilaments for producing corresponding warp and weft threads from plastic fibers of unlimited length, the individual plastic fibers are, for example, twisted with respect to one another. However, it is also possible for the plastic fibers to have the required consistency for the filament by means of eddy current deformation. Since multifilament yarns are used here, these consist of a plurality of plastic fibers, typically more than 10 plastic fibers, wherein up to 40 or 50 or even more plastic fibers can be used for each yarn.

The use of high tensile strength threads, in particular plastic threads, with a maximum tensile force of at least 5cN/dtex, with regard to fineness, has proved to be particularly preferred. Generally, the maximum tension with respect to fineness is 8cN/dtex or more. Particularly preferred is a maximum tensile force with respect to fineness of at least 10 cN/dtex. The maximum tensile force or fineness strength with respect to fineness indicates the maximum tensile force in N (newton) of the filament concerned with respect to its fineness in dtex. If it is considered that the steel wire or steel strand has a maximum tension with respect to fineness of typically 2cN/dtex, the tensile strength of the wire used according to the invention is at least 5 times greater (10cN/dtex and more) compared to steel.

In practice, in the usual case even high tensile strength filaments are used which have a maximum tension with respect to fineness of especially 20cN/dtex and higher and preferably a maximum tension of at least 30 cN/dtex. Thereby providing even a tensile strength of the wire with 15 times that of steel (30cN/dtex vs 2 cN/dtex).

As a result, a grommet made of the relevant wire is formed with a significantly higher breaking force than a grommet made of a wire rope (as described in the prior art according to patent document DE 7930165U 1). The plastic fibers used here for producing the threads or plastic threads and thus the strands are also in particular designed as thermoplastic fibers. The use of plastics, such as Polyethylene (PE), Polyamide (PA), polyethylene terephthalate (PET), polypropylene (PP), alone or in combination, has proven particularly suitable here. The list is obviously not limiting.

Typically, this type of thermoplastic fiber has a density or specific weight slightly less than that of water, so that the grommet made therefrom can float as a whole. For example,for Polyethylene (PE), 0.92 to 0.95g/cm are obtained³The density of (c). If the density is compared with the density of steel (between 7.85 and 7.87 g/cm)³) In contrast, it is evident that the density of the steel or steel cord is configured to be almost 8 times that of the plastic cord used. At the same time, the breaking force with respect to fineness of the plastic rope used according to the invention is almost 15 times that of the known steel rope, so that overall the ratio of the material weight/breaking force in the grommet realized according to the invention is only 0.5 compared to a grommet made of steel rope.

That is, compared to a grommet made of a steel cord with the same breaking force, the grommet according to the invention has only half as much mass or weight. As a result, the handling of the grommet according to the invention is also made simpler, and, depending on the design, additional lifting devices can usually be dispensed with. Further, the user can mostly operate the grommet with his own force and e.g. hang it into a hook, which is no longer possible in a steel cord with a relatively double weight with the same breaking force. Of course, the same applies to a chain according to the invention equipped with chain links configured as grommets.

The result is therefore a grommet made of plastic rope which has a significantly smaller weight (only about 50%) than a grommet made of steel rope at the same breaking force and which is accordingly significantly simpler to handle than hitherto. Furthermore, due to the use of one or more plastic cords for manufacturing the grommet according to the present invention, damage to the surface of a load, for example, moved thereby, is practically avoided. Furthermore, the grommet according to the invention is in principle floatable, so that the grommet according to the invention is not lost when used in, for example, a harbour area. The same applies to the case where the grommet is used in offshore applications. Furthermore, the grommet according to the invention and the chain produced therefrom are able to withstand environmental changes and naturally do not corrode.

According to a further advantageous embodiment, for producing the thread, plastic fibers made of polyolefins having an ultrahigh molecular weight are used. In fact, the polyolefins used in the scope of the present invention have a molecular weight of at least 400,000 g/mol. Furthermore, the fineness of the filaments or plastic filaments achieved in this way is at least 20 dtex. Plastic fibers of this type made of polyolefins having an ultrahigh molecular weight and their production have been known for a long time. For this purpose, reference is made, for example, to patent document EP 0205960 a 2. On the market, for example, the nameThe corresponding product of (1).

As a further advantage, it is conceivable to determine the breaking force of the loop of the grommet or of the corresponding chain link according to the invention by subtracting only one placement force loss from the sum of the individual rope breaking forces. In fact, according to the invention, the placing force loss is less than 20% and in particular less than 15% and preferably about 10% of the sum of the individual rope breaking forces. As a result, unlike the circular loops already described above, the breaking force achieved by means of such a grommet can be predicted and adjusted relatively accurately. For this purpose, only the sum of the individual rope breaking forces is determined. If, for example, six rope strands are wound around one another here, the breaking force of an endlessly placed loop produced in this way is 6 times the rope breaking force of a single rope. Then, only the placing force loss given above is subtracted from the sum. In this way, the grommet can be produced in a defined manner with regard to the breaking force that it can achieve and adapted to the actual requirements. Of course, this also applies to the links made of grommets.

In this way, it is possible to define links as a whole having a breaking strength or breaking force of at least 1 kN. Typically even a breaking force of 5kN, especially 10kN and preferably even at least 20kN is observed. The chain thus realized can be advantageously used for storing, fixing, lifting and manipulating goods, loads, but also vehicles as a whole. By using plastic wires, possible surface damage is avoided. The chains thus produced are also particularly weather-resistant. Thereby obtaining important advantages.

Drawings

The invention is explained in detail below on the basis of the drawings which show only exemplary embodiments. Wherein:

figure 1 shows the different stages in the manufacture of a grommet from endlessly placed rings made of twisted rope structures and thus the manufacture of the chain links,

figures 2A and 2B show in cross-section two different variants of the rope used,

fig. 2C shows a particularly preferred variant of the rope used, and

fig. 3 and 4 show two principle variants of a chain according to the invention.

Detailed Description

In fig. 1 and 2A to 2C, a grommet is shown in each case, which is equipped with at least one endless loop made of a twisted rope structure and is shown in fig. 1. In principle, a plurality of rings can also be implemented. According to this embodiment and according to fig. 3 and 4, the grommet shown in detail in fig. 1 and 2A to 2C and described in more detail below is used to realize a chain consisting of a plurality of interconnected links 6. In the chain shown in fig. 3, the individual chain links 6 are connected to one another in such a way that the chain links 6, to be precise the grommets arranged at this point, engage directly into one another. In contrast, the variant according to fig. 4 provides that the individual links 6 do not engage into one another, but are instead coupled to one another by means of a respective interconnecting connecting piece 7. The connector 7 may be a steel ring, an endless plastic band or similar connector. The chain shown in fig. 3 and 4 can in principle be used for storing, securing, lifting and manipulating goods, loads, but also for vehicles, which is generally known and described in detail in the prior art cited above.

As already explained, the respective chain link 6 is designed as at least one endlessly placed ring made of a twisted rope structure based on plastic wires and in particular as a grommet, which is shown in detail in fig. 1 and 2A to 2C, for example. The rope structure itself and essentially consists of at least one rope 1 placed helically continuously around the core.

As can be seen from the exemplary embodiment in fig. 1, a single rope 1 is used here, which is laid helically continuously around itself as a core. The two rope ends 1a and 1b which remain in the right-hand part of fig. 1 in the end are each guided in the twisting direction under the outer rope or outer rope layer at the end of the placing process.

That is, it is also possible in principle for the two rope ends 1a, 1b to project into the interior of the grommet as if under the outer rope layer and not to project outwards. According to the embodiment in fig. 1, working with a clockwise twist direction. However, the illustrated grommet could also be made with a counterclockwise twist orientation. If a plurality of ropes twisted helically about one another is used, different twist directions counter-clockwise and clockwise can in principle also be achieved and are included in the invention.

The cord 1 itself consists of plastic fibers 2, as can be seen, for example, from the sectional views through the cord 1 in fig. 2A to 2C. In practice, the rope 1 is substantially a plastic rope, i.e. the rope 1 consists of a plurality of individual plastic fibers 2. The plastic fibers 2 themselves define filaments or plastic filaments 3, 4. Here, the threads 3 are warp threads, while the threads 4 are weft threads.

The warp threads 4 extend mainly in the longitudinal direction, here in the circumferential direction of the ring shown in fig. 1. In contrast, the weft threads 4 are oriented perpendicularly thereto, extending substantially radially with respect to the loops. In order to be able to produce the individual threads 3, 4 from the plastic fibers 2, the plastic fibers 2 are twisted relative to one another according to this exemplary embodiment, but can also be connected to one another by means of eddy current deformation, as already described at the outset.

According to this embodiment, the warp threads 3 each have the same diameter according to the variant according to fig. 2A. Similar applies to the weft threads 4 in this variant, the diameter of which corresponds to the diameter of the warp threads 3 here. However, in the scope of the variant according to fig. 2B, working with warp threads 3 or 3' of different diameters, in contrast, in this variant, weft threads 4 of the same diameter are reused. In fig. 2B, in fact, a warp thread 3 with a relatively small diameter or cross section can be seen, whereas in this respect a warp thread 3' has a relatively larger diameter.

Thus, the warp threads 3 or 3' in combination with the weft threads 4 define as a whole a cord 1 made of plastic fibres 2. For this purpose, the entire rope 1 is designed as a circularly woven rope 1 consisting of warp threads 3, 3' and weft threads 4. In this connection, the warp threads 3 each define different layers 5 lying one above the other, as is indicated, for example, in fig. 2A. In practice, three layers 5 of warp threads 3 are realized here, which are woven together by means of corresponding weft threads 4 and which overall form and predetermine a more or less circular cross section of the cord 1. The weaving process is carried out in detail by means of a device or machine for circular weaving, as described in detail in EP 0059483 a1, which was already cited at the outset.

In a particularly preferred variant of the rope 1 according to fig. 2C for producing a circular weave, provision is made for one or more layers 5 of a respectively one tubular fabric to be produced from warp threads 3 or weft threads 4. In this connection, in fact, the circularly woven rope 1 is produced in a single-layer or double-layer cylindrical fabric weaving method. The tubular fabric is in turn composed of warp threads 3 in the longitudinal direction and of weft threads 4 extending in the opposite transverse direction, as already explained above. Furthermore, a lining, not shown, can be realized. The inner liner may be a fabric composed of additional plastic filaments, not shown. In principle, other liners are also conceivable.

According to this embodiment, the filaments 3, 4 have a fineness of at least 20 dtex. Furthermore, the threads 3, 4 have a maximum tensile force with respect to fineness of at least 10cN/dtex as the high tensile strength threads 3, 4. The filaments 3, 4 are plastic filaments 3, 4 and in particular thermoplastic filaments. That is, the plastic fibers 2 made of, for example, PE, PA, PET, PP, etc. are used for the filaments 3, 4 composed of the individual plastic fibers 2.

Plastic fibers 2 made of polyolefins having an ultrahigh molecular weight, so-called UHM-WPE (ultrahigh molecular weight polyethylene), are particularly preferred here. For example, can purchaseA brand of this type of plastic fibre 2 and filaments 3, 4 made therefrom. It is obvious that the invention is not limited thereto. Since plastic fibers 2 made of Polyamide (PA) or polyester or polyethylene terephthalate (PET) can also be used in principle here. Obviously, also a combination scheme is conceivable. That is, in this case, the threads 3, 4 concerned are composed of and made of plastic fibers 2 of different plastics.

The breaking force of the loop produced in this way is designed or determined in its entirety such that the sum of the individual rope breaking forces is obtained. That is, each individual cord 1 has a corresponding breaking force. For example, if the maximum tension with respect to the fineness is 10cN/dtex and the rope 1 in question has a fineness of 20dtex, for the rope 1 in question, the maximum tension up to 200cN or 2N (10cN/dtex 20dtex — 200cN) is determined. However, in the usual case, work with a fineness of at least 100dtex, so that the maximum tension of the rope 1 is 10N.

A typical cord diameter of e.g. 4mm results in a strength of typically more than 100N, so that when e.g. 6 cords 1 are used for the cord structure shown in fig. 1, a breaking force of at least 600N is observed. In order to be able to determine and predetermine the breaking force of the loop as a whole, the loss of setting force must then also be subtracted from the sum of the individual rope breaking forces. Typically, the placement force loss is about 10% of the sum (i.e., 10% of 600N — 60N), so that in an example case, a ring breaking force of at least 500N may be assumed.

The chain link 6 made of a ring and thus the breaking force of the chain are then also constructed in a similar manner.