EP0503276B1 - Cable attachment for a funicular vehicle - Google Patents

Description

The invention relates to a pull cable linkage for funicular railways in which the pull cable is held in a conical sleeve which is connected to the construction to be held via a tilting bearing.

From GB-A-499.406 and GB-A-25.079 A. D. 1899 it is known to fasten rope ends in conical bushings and to store the bushings in tilting bearings which are connected to the running gear. These publications do not address the problem of regulating the length of the rope in fine steps.

WO 87/01080 shifts an entire rope deflection station for the fine adjustment of the length of the rope. In the case of funicular railways, this construction is synonymous with the displacement of the mountain station or larger parts of it.

It is also known from AT-B-312.680 to hold the traction cable in funicular railways by means of an angle lever in the car area and to determine the respective dead weight of the funicular railway car with the movement of the angle lever or its pretensioning via the pull cable tension in order to derive the necessary braking energy therefrom to be able to. This construction allows a shorter adjustment path for the adjustment of the cable car, especially if one takes into account the different rope lengths in winter and summer operation solely due to temperature fluctuations. In addition, there are elongations that result from the tension of the traction cable and that practically do not come to a standstill during the life of the cable. Most of these elongations are corrected by shortening the rope, which requires the railway to stand still for a long time and is therefore undesirable. At the same time, the flexible integration also requires increased maintenance, so that certain restrictions can be expected in practice.

The invention has set itself the task of addressing these disadvantages and to provide a continuously adjustable rope hitch that can be adjusted with a few simple steps and at the same time meets the spatial requirements, so that when building the funicular, the rope integration can be done practically at the top edge of the rail. Another advantage of the design is seen in the fact that the sensitive components such as the spring assembly and tilting bearings are largely protected from dirt in an easily removable sleeve, so that the function absolutely necessary for traffic safety is guaranteed. In addition, it is advantageous to determine the rope force directly.

The invention is characterized in that the sleeve is designed as a fork, on the fingers of which a transverse bolt is provided, which is mounted in a continuously adjustable threaded bolt, the nut of the threaded bolt being fastened to the structural part to be held via the tilting bearing and springs. In particular, a sleeve with a switching ruler for triggering the slack rope safety device is arranged between the tilting bearing and the springs, and preferably the bolt is designed as a load measuring bolt.

By the measures of claim 2 and 3, the security is increased even further, so that the weight of the respective carriage or its tractive force can be read directly, in particular by the design of the bolt as a load measuring bolt.

The invention is shown, for example and schematically, in the attached figure.

In the conical sleeve 2 of a fork-shaped device, the traction cable 1 is cast, and electrical insulation can be provided for the electrical decoupling between the two components, so that the traction cable can also be used as a transmission means for electrical impulses. The sleeve 2 is formed with two fingers, a transverse bolt 4 being mounted on their fingers, which is designed as a load measuring bolt by the arrangement of strain gauges or similar devices, so that the tensioning force of the pulling rope can be read at any time. The measurement serves to "pre-determine" the braking force in the event of a rope break and is therefore part of the safety equipment. Approximately in the middle of the bolt 4, a threaded bolt 5 is arranged, which carries the thread at its other end, and is thus infinitely adjustable by means of nuts, which are designed as counter nuts. The nuts 6 are supported on a tilting bearing 7, so that the threaded bolt 5 can be freely adjusted and the thread does not have to absorb any bending stress. The sleeve 2 is thereby set up in the direction of the force. The tilting bearing 7 is supported with its other end on springs 8, which are ultimately fastened to the structural part 9 to be hooked in, such as, for example, the chassis or carriage frame. Springs 8 and tilt bearing 7 are covered by a cylindrical sleeve 10, so that neither dirt or other interference elements can penetrate into the components. Finally, on the outside of the sleeve 10 there is also a switching ruler 11, which guides the release valve 12 for the brake (not shown) of the carriage, such as a rail brake.

The special advantages of the described device are the simple structure, the assembly effort, the ease of maintenance, the spatial self-centering and the simple, reliable slack rope release as well as, above all, the possibility of direct, direction-free cable pull measurement with the help of an electronic circuit, as well as the easy displacement of the exact vehicle attachment point Adjustment of a mother 6 given. As already stated, this has the advantage that stretching of the rope due to aging can be compensated for over a certain period of time by simply adjusting the attachment point, which means that the period between the time-consuming rope shortening work can be extended. The bolt 4 is formed by the arrangement of strain gauges, not shown, as a load measuring device, so that the cable can be measured directly and without direction. This results in a further peculiarity of the device according to the invention, so that the required braking force and also the brake release in the case of slack rope can be predetermined. As springs 8, for example, disc springs are used, which work in the smallest space and, as a proven component, have a positive effect on the functional reliability. In addition, the functionality of the system can also be checked by suitably designing the sleeve 10 as a hydraulic device, in particular by replacing the spring assembly. The sensible shape of the housing or the sleeve 10 avoids overloading the release spring, which also results in an upper limitation of the release force or the housing movement. Finally, a guide plate covers the housing and supports it towards the car body. Removable covers under the entire suspension device provide additional protection from below, so that the sensitive parts of the adjustment device are arranged protected from the weather.

Claims (3)

1. Traction cable coupling for funiculars equipped with a traction rope (1) held in a conical sleeve (2) which is linked with the structure to be held by means of a swing bearing (7), characterized in that the sleeve (2) is designed as fork the arms of which are provided with a traverse bolt (4) linked with a continuously adjustable threaded bolt (5), whereby the nut (6) of the threaded bolt (5) is attached on the structural element to be held (9) by means of the swing bearing (7) and springs (8).
2. Traction cable coupling according to claim 1, characterized in that between the swing bearing (7) and the springs (8) a sleeve (10) with activating bar (11) for the release of the slack rope safety device (12) is located.
3. Traction cable coupling according to claim 1, characterized in that the bolt (4) is designed as load measuring bolt.

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