DE1530004C - Towing system for ski lifts - Google Patents

Description

The invention relates to a towing hanger for Sklifte with a tow rope receiving Cable drum, on which a braking device acts in the pull-out direction of rotation, and with a pretensionable one Spiral ribbon spring, which is on a common shaft with the spring winding mandrel that accommodates it is arranged.

With such tow hangers, the deceleration of the unwinding device increases with increasing freedom Tow rope length, whereby the passengers from a standing start without noticeable start-up impact on the circulating speed of the hoisting rope are to be brought. These tow hangers mostly also have a centrifugal brake in addition to the starting shock brake to regulate the winding speed of the tow rope so that the one released by the passenger Towbar not like a catapult when the tow rope is wound up by the spring of the rope drum is accelerated and beats over the hauling rope.

There are tow hangers known that have a brakable unwinding device for the tow rope, which requires a complicated gear that is driven by the unwinding of the tow rope is operated and a brake is operated via an eccentric linkage. Such facilities are costly and Due to their complexity, they do not meet the practical requirements for easy maintenance and independence from weather influences. It is also known to place the tow rope spirally one above the other on a correspondingly shaped tow rope drum wind up, whereby the tow drum accelerates more and more during the unwinding process this acceleration via flyweights is used for braking.

Such devices have the disadvantage that the braking is not sufficient. Neither it is sufficient to put the spiral band springs previously used against their inner end by several To reinforce layers and to reduce the start-up damping by spiraling the tow rope raise. Such a design requires preformed internal reinforcements of the spiral ribbon spring, without the necessary increase in tensile force of up to 90 kp when unwinding the tow rope for steep approach routes and lifts with high conveying speed can be reached. Also known is the spiral ribbon spring to be reinforced by an inserted, corrugated band in order to achieve an increase in tensile force or braking of the tow rope due to the friction and deformation work. The lifespan However, such spiral ribbon springs is too low, apart from the fact that in all designs on additional flyweight brakes, which the winding speed of the tow rope, cannot be dispensed with.

The invention has for its object to avoid these disadvantages, i. i.e. the damping of the start-up shock to improve.

This object is achieved according to the invention in that the braking device assigned to the cable drum in the pull-out and pull-in directions depending on the respective torque of the Spiral ribbon spring is effective.

Cable drums and spiral ribbon springs of any known design can be connected to one another by a torque-dependent braking device of the type according to the invention. To increase the braking torque z. B. also a bobbin-like or cone-like rope drum, which winds the tow rope in a known manner spirally one above the other and / or a coil spring designed according to the invention to be multilayered against the outer spring end can be used, the torque of which increases steeply when the unwinding process of the tow rope comes to an end approaching.
The tow hangers built according to the invention

ίο can be constructed so that an additional centrifugal brake in a known manner the winding speed of the released tow rope: regulates; but they can also be built in a very simplified way that the winding speed is also controlled by the torque-dependent braking device, which slows down the unwinding of the tow rope, is regulated, so that all components that the winding speed regulate and all otherwise required freewheeling parts, which the start-up brake only in a rotary

let ao direction work, omit.

The inventive arrangement of the torque-dependent braking device offers the advantage that the largest part of the tensile forces, which towards the end of the unwinding process on the spiral ribbon spring act via the brake lever operated by the braking device from the brake drum of the Towing hanger are included, so that the spiral ribbon spring has a longer service life. For example, when the towing hanger is implemented, the spring force is on the wound Tow rope initially 3 kp, what the operating staff the pulling out of the tow bar facilitates the waiting passenger, while towards the end During the unwinding process, the tensile force on the tow rope increases by up to 90 kp, so that the passenger is boarding s ^ nft to the speed of the conveyor rope ♦ -accelerated.

Further advantages according to the invention emerge from the following description and the drawings but the invention is not intended to be limited to the examples shown; it shows

1 shows a towing hanger in axial center section,

F i g. 2 and 3 cross-sections along lines I-I and IMI of Fig. 1, and

, F i g. 4 and 5 further exemplary embodiments.

The towing hanger consists of a housing 1,

; to which a spring housing 2 is flanged. A shaft 3 is in ball bearings 4 in these two housings centrally stored. A partition S with its seals ensures the tightness of the spring housing 2. A cable drum 6 is freely rotatably mounted on the shaft 3; a spreading lever 11 and a spiral band spring 14 with a spring winding mandrel 13 are firmly connected to the shaft 3 by a key 12. The cable drum 6 carries flyweight brakes 22 on one side to regulate the winding speed, on the other side two brake levers 8, which are mounted on grooved pins 9 and supported by a tension spring 10 are connected. A brake drum 16 is rotatably mounted on the expansion lever 11 and has pawls 18 or locks 19, which do not allow the brake drum 16 to run free only in the winding direction 21 but enable 20 in the unwinding direction. Is the cable drum 6 by the unwinding tow rope 7 set in rotation, the brake levers 8 lie against the spreading lever 11 and 11 which spread them set this and thus the shaft 3 in revolutions,

whereby the spiral band spring 14 is drawn up and its torque and thus the force of the expansion lever 11 on the brake lever 8 is constantly increased. The tension springs 10 are dimensioned so that they over some Revolutions to keep the torque of the spiral ribbon spring 14 in balance, causing the tow rope 7 can easily be unwound from the cable drum 6 for the entry of the passengers. But then overcomes the constantly increasing rotating rope 7 immediately in the initial stage of the unwinding process braked and not only after a few revolutions of the cable drum 6 as in the first embodiment according to FIG. 1. This disadvantage for the operator is due to the very gently rising characteristic the spiral ribbon spring 14 is so insignificant in the initial stage that it can be neglected.

F i g. 5 shows a further exemplary embodiment of the invention with a brake disc. F i g. 3 represents the

moment of the spiral ribbon spring 14 the bias of the io cross section along the line IV-IV in F i g. 5. Die-tension springs 10 and spreads over the spreading lever 11, this embodiment differs from this embodiment Brake lever 8, which leads to the desired braking the first according to FIG. 1 by the type of rotator Cable drum on the brake drum 16 leads. This torque-dependent braking device is between the rope but through the pawls 18 or locks 19 on it drum 6 and spiral ribbon spring 14. The cable drum 6 prevented from being taken along in the unwinding direction of rotation 20 is firmly connected to the shaft 3 by the feather key 24

to become men. In this way, the unwinding process of the tow rope 7 is slowed down more and more and the passenger jumps to the speed of the Conveyor rope accelerated.

By rotating the spring housing 2 with respect to the housing 1, the preload of the spiral ribbon spring 14 and thus the starting braking can be set for each slope of the starting route. Are the passenger releases the tow rope 7, so the winds

the and the spring winding mandrel 13 are coupled to the shaft 3 by a thread 29. But it can the cable drum 6 must also be coupled to the shaft 3 by means of a thread, then the spring winding mandrel 13 rigidly connected to the shaft 3. In the example shown in FIG. 5 is through the thread 29 the coupling between the cable drum 6 and the spiral ribbon spring 14 is established. The brake disc 26 with The pawl 18 or lock 19 is by means of a spherical spiral band spring the tow rope 7 is mounted on the coupled 25 bearing 25 on the shaft 3. Through the bolt Cable drum 6 because the brake drum 16 with 31 with the rivets 30 is the spiral ribbon spring 14 With the help of the pawls 18 or locks 19 in the winding end, for example, articulated; after direction of rotation runs freely. The winding is F i g. 1 and 4 it is speed by a screw 35 by the flyweight brakes 22 solidified. The compression spring 28 holds the spiral ribbon spring 14 regulated. During the unwinding process, the brake 3 ° rotates during a few revolutions of the cable drum 6 drum 16 so long until the bias of equilibrium. Then the increasing torsional coil spring creates 14 has dropped so far that the moment of the spiral ribbon spring 14 by means of the thread Tension springs 10 are again able to exert an axial force on the brake disk 26 and the brake 29 pull lever 8 against each other. presses this against the cable drum 6. The braking

F i g. 4 shows an exemplary embodiment. The winding and winding process now goes as it did with the addition however, the cable drum shown is not play according to FIG. 1 in front of you.

The * connection of the housing 1 with the hoisting rope In all the exemplary embodiments of the invention, this usually takes place via a hanger support rod 32.

Subject of the invention. The cross-section along the line III-III is similar to F i g. 2 except for the brake ring 34 and the position of the brake lining 15. In this embodiment, those in FIG. 1 and 3 shown Brake drum 16 with pawl 18 or lock 19 and ball bearing 17 and the flyweight brakes 22. The brake ring 34 is rigidly connected to the housing 1 and the brake lining 15 is connected to the brake lever 8 offset from the pivot point to about the middle of the brake lever (paragraph 23) (shown in FIG. 2 with dotted lines). Due to this arrangement of the brake pads 15 with respect to the pivot point of. Brake lever 8 results for the unwinding direction of rotation 20 a significantly greater braking torque than for the winding direction of rotation 21, because the tangential frictional force in the unwinding direction of rotation additional contact pressure of the brake lining 15 is generated. As the final torque of the spiral ribbon spring 14 is always greater than the braking torque it generates in the winding direction 21, that will Tow rope 7 coiled. During the unwinding and winding process of the tow rope 7, the brake levers 8 drag middle. Brake lining 15 on the brake ring 34 and generate Due to the torque of the spiral band spring 14 in both directions of rotation 20 and 21 braking torques. The tension springs 10 are dimensioned weaker in this embodiment and hold the preloaded Spiral ribbon spring 14 only in the rest state of the towing hanger the equilibrium, d. h., the The winding speed of the tow rope 7 is regulated over the entire length of the tow rope. In the embodiment according to FIG. 4 is the tow-The invention is not only for ski lifts, but generally usable for conveyor systems.

Claims (8)

Patent claims: 1. Towing suspension for ski lifts with a cable drum that takes up the towing cable and onto which a braking device acts in the pull-out direction, and with a pre-tensionable spiral ribbon spring, which are arranged on a common shaft with the spring winding mandrel that accommodates them is, characterized in that the brake device assigned to the cable drum (6) (8, 11, 26, 29) in the pull-out and pull-in directions depending on the respective Torque of the spiral band spring (14) is effective. 2. towing hanger according to claim 1, characterized in that on the freely rotatable on the Shaft (3) mounted cable drum (6) brake lever (8) are pivotably mounted, which by means of a Spreading lever (11) can be placed against a brake ring (34) or a brake drum (16), and that the expansion lever (11) is attached to the shaft (3) together with the spring winding mandrel (13). 3. towing hanger according to claims 1 and 2, characterized in that the brake ring (34) is firmly connected to the housing (1). 4. towing hanger according to claims 1 and 2, characterized in that the brake drum (16) when pulling in the rope opposite the housing (1) is freely rotatable, but with the latter when pulling out the tow rope (7) is to be connected in a known manner by means of pawls (18) or locks (19). 5. towing hanger according to claims 1 to 4, characterized in that the brake lever (8) to delay the engagement of the brake when starting by means of tension springs (10) in their rest position are kept. 6. towing hanger according to claim 1, characterized in that the cable drum (6) or the The spring winding mandrel (13) is axially displaceable and freely rotatable on the shaft (3) are, whereby they are at least in one direction on the foot or on the bearing (ball bearing 25) a brake disc (26) (Fig. 5). 7. towing hanger according to claim 6, characterized in that the spring winding mandrel (13) is screwed onto a thread (29) provided on the shaft (3) and on the foot or the Bearings (ball bearings 25) of the slidably held on the shaft (3) and towards the cable drum (6) by means of a compression spring (28) acting in the unwinding direction of rotation of the cable drum (6) Brake disc (26) rests, the brake disc (26) on one side with a annular closed braking surface (27) is provided (Fig. 5). 8. towing hanger according to claim 1 or one of the preceding claims, characterized in that that the spiral ribbon spring (14) consists of several layers (33) against its outer end consists, which are rigidly or articulated on the spring housing (2). For this purpose 2 sheets of drawings