CONDUCTOR CLAMP FOR A TRAILING LINE

Abstract

A conductor clamp (4) for a trailing line (5) which is secured to crabs (7) which can be moved along a carrier rail (1) comprises a support (8) for the trailing line, a clamping device (9) for securing the trailing line to the support and a shock absorber (10) for absorbing an impact of the first crab on the conductor clamp. The shock absorber has at least two spring bodies (20, 22) which have different characteristics and which are arranged one behind the other in the anticipated direction of action of the shock absorber. In this context, the most resilient spring body (20) is arranged closest to the end of the shock absorber which is provided for the application of an impact force. The shock absorber also has a lifting rod (16) which can be displaced under the effective impact force in the anticipated direction of action of the shock absorber. At the two ends of the lifting rod, spring bodies with different characteristics are arranged. The shock absorber has a housing in which the lifting rod is movably mounted, with an internal end of the lifting rod being located inside the housing, and an external end of said lifting rod being located outside the housing.

Description

FIELD OF THE INVENTION

The invention relates to a conductor clamp for a trailing line according to the preamble of Claim 1. Such a conductor clamp is used for securing one end of a trailing line to one end of a carrier rail, along which the trailing line can be towed by means of several crabs. For this purpose, the conductor clamp is mounted stationary on the carrier rail.

BACKGROUND OF THE INVENTION

In the course of the movement of the trailing line, when the crabs are moved away from each other, tensile forces must be transmitted between the individual crabs and, when the crabs are moved toward each other, compressive forces must be transmitted between the individual crabs, wherein the loading takes place abruptly and therefore high peak values of the forces occur if countermeasures are not taken. For this purpose, DE 1 193 333 A provides coil springs on the crabs, wherein these springs are arranged in cylinders and are compressed by pistons running in the cylinders both when the crabs are moved away from each other and also when the crabs are moved toward each other, i.e., when one crab impacts another, and in this way, the peak force values appearing in both load cases are absorbed. Other elastic elements are not provided for this purpose.

DE 32 36 992 A1 teaches a structurally simpler and likely more economical solution. Here, damping elements are used in the form of chain pieces, which are vulcanized in place to form a rubber package, for damping abrupt mechanical loads in the traction cables, through which the individual crabs are coupled with each other, when the crabs are moved away from each other. For damping the impacts caused by collisions between crabs when they are moved toward each other, rubber bumpers are provided on the end faces of the crabs. Due to the moving support of the crabs on the carrier rail, such simple damping elements already obviously have adequate effectiveness for damping impacts.

However, the conductor clamp, which secures one end of the trailing line to one end of the carrier rail, is mounted stationary on the carrier rail and cannot yield by means of its own movement, when the first crab impacts against it with the return movement of the trailing line. Therefore, more resilient damping for the impacts caused by contact of the first crab must be provided on the conductor clamp.

SUMMARY OF THE INVENTION

The present invention is based on the task of providing a solution for damping the impact of the first crab of a trailing line on its conductor clamp, wherein this solution is distinguished by effectiveness according to the requirements with a simple construction.

This task is achieved according to the invention by a conductor clamp with the features of Claim 1. Advantageous improvements are specified in the subordinate claims.

According to the invention, the conductor clamp is equipped with a shock absorber, which has at least two spring bodies, which have different characteristics and which are arranged one behind the other in the anticipated direction of action of the shock absorber, wherein at least one of the spring bodies (20) is made from an elastic material with a cellular structure, and in that the overall characteristics of the shock absorber are non-linear and have an initial region with a small increase in the spring force over the deflection and a following region with a greater increase in the spring force over the deflection. In this way, the total characteristics of the shock absorber can be achieved, which are optimally adapted to the requirements of the impact damping at the end of a trailing line. The intensity of an impact of the first crab on the conductor clamp can vary, namely within wide limits, so that for a high impact intensity, sufficiently hard damping characteristics are required that would barely have a damping effect for a low impact intensity. Here, especially suitable for a spring body of large resilience, like that needed for a low impact intensity, is an elastic material with a cellular structure. By means of the invention, the different requirements on the damping characteristics across the entire incident range of the impact intensity can be satisfied.

It is especially useful to arrange a resilient spring body at the end of the shock absorber, wherein this spring body is provided for introducing an impact force, so that this spring body can take over the damping essentially by itself for an impact of low intensity, without other components of the shock absorber being significantly deflected.

One advantageous solution for coupling spring bodies of different characteristics is their arrangement at different ends of a lifting rod, which can be displaced under the effective impact force in the anticipated direction of action of the shock absorber. Here, stiff spring bodies support the lifting rod on a housing, which functions as a bearing for the lifting rod and as a carrier for the stiff spring bodies. It is especially advantageous when the housing simultaneously forms a part of the holder for mounting the conductor clamp on the carrier rail.

The arrangement of at least two similar spring bodies one next to the other in the housing, to which the total effective force is distributed at least approximately uniformly, permits an especially compact construction of the shock absorber and a stable guidance of its moving components in the case of a deflection.

BRIEF DESCRIPTION OF THE DRAWINGS

Below, an embodiment of the invention will be explained with reference to the enclosed drawings. Shown in these are

FIG. 1, a schematic diagram of a trailing line system,

FIG. 2, a conductor clamp according to the invention in three views,

FIG. 3, enlarged partial views of the shock absorber of the conductor clamp from FIG. 2,

FIG. 4, the characteristic curve of one of the spring bodies of the shock absorber from FIG. 3, and

FIG. 5, the characteristic curve of the entire shock absorber from FIG. 3.

DETAILED DESCRIPTION OF THE INVENTION

As shown schematically in FIG. 1, in a trailing line system, several moving crabs 2 and 3 are guided on a carrier rail 1, wherein their number is generally significantly larger than two. Starting from a conductor clamp 4 mounted rigidly on one end of the carrier rail 1, one or more lines 5, for example, electrical lines, are guided via the crabs 2 and 3 to a line clamp 6 of a moving work device 7, for example, a derrick car. Because the crabs 2 and 3 can collide with each other in the course of their movements following the work device 7 along the carrier rail 1, they are equipped with shock absorbers that are not shown in FIG. 1. These shock absorbers do not need to have a very resilient construction, because the crabs 2 and 3 can also yield due to their own movement when there is an impact. However, this does not apply for the conductor clamp 4, which would be subjected to relatively large vibrations when the trailing line is moved back into the starting position shown at the top in FIG. 1 due to the impact of the first crab 2 together with this clamp, and therefore a more resilient shock absorber is needed than the moving crabs 2 and 3.

FIG. 2 shows a conductor clamp 4 according to the invention in three views, wherein at the top right, the side view corresponding to FIG. 1 is to be seen, so that the trailing line not shown in FIG. 2 would extend outward to the right from the conductor clamp 4. Next to this on the left, the front view is to be seen and at the bottom right, the top view is to be seen. As can be seen best in the side view, the conductor clamp 4 includes a support 8 that is essentially semicircular in this view for the trailing line, clamping devices 9 for securing the trailing line to the support 8, and a shock absorber 10, which is connected to the support 8 by a carrier plate 11. The support 8 is made from two symmetric parts, which each have a flange 8A, at which they are screwed both to each other and also to the carrier plate 11.

At its upper end, a plate 12, which is a component of a housing of the shock absorber 10, i.e., forms its base plate 12, is attached, e.g., fused, to the carrier plate 11 perpendicular to this carrier plate. Other essential components of the housing of the shock absorber 10 are a front wall 13 and a rear wall 14. The rear wall is supported by a support angle 15, which is connected, e.g., hooked, to the base plate 12 with a positive fit. Furthermore, the housing also comprises a cover, which is not shown in FIG. 2 and which closes the other three sides. The housing also forms a part of a holder, with which the conductor clamp 4 can be attached to the carrier rail 1, in that it is designed to be connected to a component, which can be connected on its side directly to the carrier rail 1. Such a component can be shaped, in particular, so that it partially encompasses the housing, contacts the bottom side of the base plate 12, and can be connected to this base plate by boreholes that are aligned with each other.

The components of the shock absorber 10 are shown enlarged in FIG. 3 without the base plate 12 and the cover that is also not visible in FIG. 2. These components include a moving lifting rod 16, which, in its rest position, is located predominantly outside the housing, but projects into this housing through the front wall 13. On its outer end with respect to the housing, an outer end plate 17 is attached to the lifting rod 16 and on its inner end in this respect, an inner end plate 18 is attached.

A resilient spring body 20, which is made from a plastic, such as polyurethane, with a cellular structure, is attached to the outer end plate 17 by means of a connection plate 19. Such spring bodies 20 also known as cell bumpers are distinguished by high compressibility for only small lateral expansion and as such are also known. A typical characteristic curve of such a spring body 20 in the form of a cell bumper is shown in FIG. 4 as an example. It is characterized in that the force via the relative compression initially rises with only a small slope and this slope changes nearly abruptly to a significantly larger value only at a considerable compression of, in this case, approximately two thirds of the length.

The inner end plate 18 is attached to a pressure plate 21, which clamps two rows of similar, relatively stiff spring bodies 22 one next to the other between themselves and the rear wall 14 of the housing. These stiff spring bodies 22 are each made from a rubber-elastic solid material with an essentially linear spring characteristic curve and have the shape of a hollow cylinder, which is not visible in the figures. In each of the two rows, several such spring bodies 22 are placed one behind the other on a guide rod 23 running between the front wall 13 and the rear wall 14, wherein together, they enclose the guide rod 23 along the entire distance between the pressure plate 21 and the rear wall 14. In this way, the stiff spring bodies 22 support the lifting rod 16 in the axial direction against the rear wall 14 of the housing of the shock absorber 10. For redirecting a force exerted by the spring bodies 22 on the rear wall 14 due to this support into the base plate 12, the support angle 15 is provided.

The guide rods 23 are attached to the front wall 13 and to the rear wall 14 of the housing and project through the pressure plate 21 and the inner end plate 18. In interaction with the opening, at which the lifting rod 16 projects through the front wall 13 of the housing, they form a guide for a movement of the lifting rod 16 and the components connected rigidly to it, namely the plates 17, 18, 19, and 21, as well as the spring body 20, which, in the case of a sufficiently large application of force of the lifting rod 16 in its axial direction, which represents the direction of action of the shock absorber 10, is introduced against the supporting force of the spring body 22. Such a movement of the lifting rod 16 is thus guided at three different positions, which guarantees high stability and security against tipping.

The crabs 2 and 3 of the trailing line, which are not described in more detail here, are each equipped with shock absorbers of simple type, for example, in the form of rubber bumpers. In the ready-for-use, assembled state of the trailing line, the longitudinal center axis of the lifting rod 16 aligns with that of the shock absorber of the crabs 2 and 3, so that, when the first crab 2 impacts the conductor clamp 4 when the trailing line is moved back, the shock absorber of the first crab 2 facing the conductor clamp 4 impacts against the spring body 20 in the axial direction of the lifting rod 16.

If the impact has only a small intensity, then due to the relatively large support force of the spring body 22 and also the inertia of the lifting rod 16 and the plates 17, 18, 19, and 21 connected rigidly to it, essentially only the resilient spring body 20 absorbs the impact energy and thus damps the vibrations of the first crab 2 and the conductor clamp 4. However, if the impact has an intensity that exceeds the energy absorption capacity of the resilient spring body 20, then after a maximum compression of this resilient spring body, a significant deflection of the lifting rod 16 is introduced against the support force of the stiff spring body 22, wherein this deflection is guided as described before. The deflection ends at a certain point and the lifting rod 16 is forced back by the spring bodies 22 into the starting position shown in FIGS. 2 and 3.

Due to the arrangement described above, overall a characteristic of the force via the deflection, as shown in FIG. 5 as an example, is given for the shock absorber 10. It is characterized by a non-linear profile, which initially begins very flat and transitions into a linear increase with a significantly larger slope after a deflection, which already accounts for a significant percentage of the anticipated maximum deflection. In the shown example, the transition takes place in a region of approximately one third of the maximum deflection. Here, the force in the flat initial section of the characteristic curve is not constant, contrary to the first appearance of FIG. 5, but instead also rises linearly, however, with a significantly smaller slope than in the end section. The flat initial section in FIG. 5 corresponds namely definitively to the section of smaller slope of the characteristic curve of FIG. 4. If the elasticity of the resilient spring body 20 is exhausted with the characteristic curve of FIG. 4 and the force increases further, then the linear characteristic curve of the stiffer spring body 22 begins to dominate the further profile, from which the transition to a linear profile with greater slope is given.

From the embodiment described above, a few possible modifications of the invention emerge for someone skilled in the art. Thus, for example, the overall characteristics of the shock absorber 10 can be varied through suitable selection of resilient and stiff spring bodies 20 or 22 and/or through a change in the number of spring bodies 22 arranged one behind the other in wide limits. Also, if necessary, more than two rows of spring bodies 22 could be arranged one next to the other and/or more than two different types of spring bodies could be arranged one behind the other in the direction of action of the shock absorber 10. Although the previously mentioned rubber-elastic solid material is preferred for the stiffer spring body 22, it would also be conceivable to use other elastic elements, such as, for example, coil springs made from metal for this spring body. Modifications such as these and other comparable modifications lie within the discretion of someone skilled in the art and should be included within the protection of the claims.

Claims

1-10. (canceled)

11. Conductor clamp for a trailing line secured to crabs that can move along a carrier rail, with a support for the trailing line and with a clamping device for securing the trailing line to the support, characterized in that the conductor clamp (4) has a shock absorber for absorbing an impact of the first crab (2) on the conductor clamp (4), in that the shock absorber (10) has at least two spring bodies (20, 22), which have different characteristics and which are arranged one behind the other in the anticipated direction of action of the shock absorber (10), and in that the overall characteristics of the shock absorber (10) are non-linear and have an initial region with a small increase in the spring force via the deflection and a following region with a greater increase in the spring force via the deflection.

12. Conductor clamp according to claim 11, characterized in that the most resilient spring body (20) is arranged closest to the end of the shock absorber (10) provided for the application of an impact force.

13. Conductor clamp according to claim 11, characterized in that the shock absorber (10) has a lifting rod (16), which can be displaced under the effective impact force in the anticipated direction of action of the shock absorber (10), and in that spring bodies (20, 22) with different characteristics are arranged at the two ends of the lifting rod (16).

14. Conductor clamp according to claim 13, characterized in that the shock absorber (10) has a housing, in which the lifting rod (16) is movably mounted, with an internal end of the lifting rod (16) being located inside the housing and an external end being located outside the housing, in that the most resilient spring body (20) is arranged at the external end of the lifting rod (16), and in that the internal end of the lifting rod (16) is supported in the housing on at least one stiffer spring body (22).

15. Conductor clamp according to claim 14, characterized in that at least two similar spring bodies (22) are arranged one next to the other for supporting the lifting rod (16) in the housing, and in that the effective total force is distributed at least approximately uniformly onto this spring body (22).

16. Conductor clamp according to claim 15, characterized in that the internal end of the lifting rod (16) is connected to a plate (21), which is mounted in the housing so that it can be displaced in the anticipated direction of action of the shock absorber (10) and which clamps the spring body (22) in the housing between itself and a wall (14) of the housing.

17. Conductor clamp according to claim 11, characterized in that the shock absorber (10) has a housing, which forms a part of a holder for attaching the conductor clamp (4) to the carrier rail (1).

18. Conductor clamp according to claim 11, characterized in that at least one of the spring bodies (20) is made from an elastic material with a cellular structure.

19. Conductor clamp according to claim 11, characterized in that at least one of the spring bodies (22) is made from an elastic solid material.