RU2787420C1 - Cable car with stabilized cabins - Google Patents

Abstract

FIELD: cable cars.

SUBSTANCE: invention relates to a cable car. On the movable element (K) of the cable car (1), there is at least one contact rail (23) that propagates in the direction of movement of the cable car vehicle (5) and is stationary relative to the vehicle. At least one station (2) of the cable car is provided with at least one guide section (FA) having at least one stationary first guide device (22) extending in the direction of movement of the means of movement of the cable car (5). This first guiding device (22) at least during the movement of the cable car vehicle (5) through the guide section (FA) interacts with the contact bus (23) of the cable car vehicle (5) to generate a guiding force, this guiding force displacing movable element (K) relative to the hitch (17) from the initial position, in which the cable car vehicle (5) can move outside the guide section (FA), to the guided position, in which the cable car vehicle (5) can move through the guide section (FA).

EFFECT: in the simplest way, the safety and comfort of people when loading and unloading the cable car vehicles is improved.

17 cl, 4 dwg

Description

The present invention relates to a cable car having at least two cable car stations and having at least one cable car vehicle that can be moved by a traction rope between cable car stations, this cable car vehicle having a movable element and a linkage, this movable the element serves to accommodate people and/or objects, and the element to be moved is suspended on the hitch in a spring-loaded manner. The invention also relates to a method for operating a cable car having at least one cable car vehicle which can be moved by a hauling rope between cable car stations.

Cableways are used to transport people and materials between two or more cableway stations. To do this, a number of cable car vehicles, such as chairs or cabins, move between the stations of the cable car either in a ring or in a pendulum mode. The cable car vehicles move between cable car stations by means of at least one traction rope. The ropeway vehicle can be hung on at least one carrier rope or hauling rope (aerial ropeways), or be positioned to run on tires or ground (terrestrial ropeways) and driven by at least one hauling rope. However, the ropeway vehicle can also be detachable or rigidly clamped to the hauling rope and move together with the hauling rope. At ring lifts, the ropeway vehicles in the ropeway station are often uncoupled from the hauling rope, for example by means of detachable rope clamps, and travel through the ropeway station at a lower speed to facilitate getting on or off people or loading or unloading material.

It is known that with cable cars, certain functions are actuated by means of rocker controls, such as opening or closing the rope clamp, swinging up or down the roll bar or windshield of the chair, or opening and closing the car or gondola door in the cable car station. To do this, a stage is located motionless relative to the station, which, when passing, is copied by a copying element on the cable car vehicle. This copying element is located on a rotatably mounted lever that rotates when copying. Then, with the help of a Bowden cable or a linkage acting on the lever, a certain function is carried out. One example of a door opening and closing function is found in US 3,742,864 A, and EP 1 671 867 B1 shows an example of a roll up and down roll bar.

In particular, with cabins or gondolas as cable car vehicles, they can swing in the cable car station when people get on or off, because there is a gap between the platform and the cable car vehicle. The lowering or lifting of the cable car vehicle in the cable car station can also take place due to the weight of the persons embarking or disembarking. Such relative movements of the cable car vehicle relative to the apron can be unpleasant for people embarking or disembarking and impair the safety of the cable car operation. Similar problems can also arise when transporting material.

EP 3 299 243 B1 discloses a cable car having a cable car station in which the car moves longitudinally between two floor guide rails. To avoid blocking the cab, the distance between these floor guide rails in the transverse direction is greater than the width of the cab. Because of this, in particular when boarding the cab, the cab oscillates laterally, which leads to the knocking of the cab against the floor guide rails and to an insufficient feeling of safety for the passengers. To avoid this, EP 3 299 243 B1 proposes that the cab in the area of the landing platform be locked laterally by means of a locking device. This interlocking device may be in the form of a downwardly extending pin centrally located on the bottom of the cabin, which cooperates with a clamping rail located on the floor of the station. This locks the cab laterally in a central position between the floor guide rails. However, this blocking device can also be made in the form of an active slider, which is integrated into the landing platform. This slider can be activated by an electric motor and pressed laterally against a car standing in the area of the platform in order to press the car against the opposite floor guide rail. However, this has the disadvantage that this is only possible when the cabin is at rest and, moreover, the constructive implementation is very laborious.

Therefore, based on the state of the art, the object of the present invention is to provide a cable car in which the safety and comfort of people can be improved in the simplest and most economical way when loading and unloading the vehicles of the cable car.

According to the invention, this problem is solved in such a way that at least one contact rail extending in the direction of travel of the cable car and fixed relative to the vehicle is located on the movable element, and that at least one station of the cable car is provided with at least one a guide section having at least one stationary first guide device extending in the direction of movement of the cable car vehicle, this first guide device interacting with the contact bar of the cable car vehicle through the guide section at least during the movement of the cable car vehicle to create guiding force, this guiding force shifting the movable element relative to the hitch from the initial position, in which the ropeway vehicle can move outside the guiding section, to the guiding position e, in which the cable car vehicle can move through the guide section. As a result, on the one hand, lateral swing movements of the movable element in the loading and unloading area can be reduced, in particular prevented, thereby increasing the safety of passengers when boarding and disembarking the cable car vehicle. In addition, the rocking movements of the movable element in the direction of travel of the cable car vehicle can be reliably reduced. That is, the spring-loaded hitch of the movable element is deliberately used to shift the movable element relative to the hitch from the initial position to the guided position. Due to the fact that in the steered position a return force acts on the cable car vehicle, which wants to move the cable car vehicle against the guiding force back to the starting position, and the interacting guides that prevent this return, the stabilization of the cable car vehicle in the transverse and in longitudinal direction.

It can be advantageous if at least two cable car vehicles propagating in the direction of travel and spaced apart from each other transversely to the direction of travel, stationary with respect to the vehicle, are arranged on the movable element, and that in at least one guide section there are provided at least two stationary first guiding devices, each of these first guiding devices cooperating with respectively one contact bar to generate a guiding force. Due to this, the guiding force acts on the movable element in the transverse direction in several places, whereby a substantially pure vertical displacement of the movable element relative to the hitch can be achieved.

Preferably, at least one first guide device is in the form of a ceiling guide rail, which is located on a stationary structure in the upper area of the cable car station, and that a mating contact bar is located in the upper side area on the cable car vehicle. This arrangement is advantageous because the contact bar and the ceiling guide bar interact in an area that is not easily accessible to passengers and personnel. This can improve the safety of passengers and staff.

Preferably, at least one guide section is provided with at least one stationary second guide device extending in the direction of travel of the cable car vehicle, wherein the movable element in the area of the guide section is deflected by the guiding force in the direction of this second guide device, while the second guide device interacts with a part of the cable car vehicle in the area of the guide section for guiding the cable car vehicle, wherein preferably at least one second guide device is made in the form of a floor guide rail, which is located on a stationary structure in the lower region of the cable car station. As a result, the cable car vehicle is guided on two sides, whereby the transverse stabilization of the cable car vehicle can be further improved.

Preferably, at least one first guide device and/or at least one second guide device is made in the form of a skid, and/or at least one first guide device and/or at least one second guide device in the direction of movement of the vehicle of the cable car, several rollers installed with the possibility of rotation are located one behind the other. As a result, the friction between the overhead guide rail and the contact rail can be reduced and a smooth guiding of the cable car vehicle can be achieved.

Preferably at least one first guide and/or at least one second guide has a damping device and/or said at least one contact bar has a damping device. As a result, shocks of the cable car vehicle, which, for example, may occur when entering the guide section, can be damped and damped.

Preferably, the movable element is in the form of a cabin. Due to this, the invention can be used preferably at the gondola.

The problem is also solved by means of a method for operating a cable car in such a way that the cable car vehicle moves into the guide section of the cable car station, while extending in the direction of movement of the cable car vehicle, the stationary first guide device of the cable car station during the movement of the cable car vehicle interacts through the guiding section with a contact tire located on the movable element, propagating in the direction of movement of the cable car vehicle, stationary relative to the movable vehicle to create a guiding force, while the movable element moves through the guiding section by the guiding force relative to the hinge from the initial position, in which the cable car vehicle is moving outside the guidance section, to a guided position, in which the cable car vehicle is moving through the guidance section .

The present invention is explained in more detail below with reference to figures 1-4, which exemplary, schematic and non-limiting manner shows the preferred embodiments of the invention. This shows:

figure 1: a schematic cable car station in a known embodiment in plan view;

figure 2: a cable car vehicle in a cable car station according to one of the preferred embodiments of the invention in the view in the direction of travel;

figure 3: the cable car vehicle of figure 2 in side view and

4: schematic view of a cable car station according to one of the preferred embodiments of the invention in plan view.

The design and operation of the cable car installation are well known, so it is only briefly explained with reference to figures 1 and 2 on the example of the ring cabway. Figure 1 shows a station 2 (for example, a mountain or valley station) of the cable car 1. In the station 2 of the cable car, a rope pulley 3 is located, along which the circulating traction rope 4 of the cable car 1 is circled. The rope pulley 3 in at least one of the stations of the ropeway 1 is driven in a known manner by a drive in order to cause the hauling rope 4 to circulate in a loop around the rope sheave of another station. Similarly, it is known that the traction rope 4 is tensioned by a tensioning device acting on the rope sheave 3. The ropeway 1 is controlled by the ropeway control in the form of appropriate hardware and software. For the sake of clarity, and since they are not essential to the invention, the known devices, in particular the second station having a rope pulley, a drive, tensioning devices, a ropeway control, etc., are not shown. The cable car 1 can, of course, simultaneously move a very large number of cable car vehicles 5 with the hauling rope 4, typically about several tens or several hundred cable car vehicles 5, only a small number of which are shown for simplicity. A platform 6 is also provided in the cable car station 2 in order to enable or facilitate boarding and disembarking of people being transported, or loading and unloading in general.

If the cable car 1 is not equipped with cable car vehicles 5 fixedly clamped on the traction cable 4, the cable car 1 vehicle 5 entering the cable car station 2 is unhooked from the traction cable 4, as a rule, by means of a detachable cable clamp 10 (Fig. 2), and moves through the station 2 of the cable car along the guide rail 7, as a rule, at a significantly lower speed than in the area between the stations 2 of the cable car. A conveyor 8 is provided along the guide rail 7 with which the cable car vehicle 5 continues to move in the cable car station 2 . This conveyor 8 is designed, for example, in the form of drive conveyor wheels 9 located in the cable car station 2, which interact in the cable car station 2 with a friction lining 11 on the cable car vehicle 5 . When the cable car vehicle 5 leaves the cable car station 2, the cable car vehicle 5 is accelerated by the conveyor 8 at the exit and is reattached to the traction rope 4, for example by means of a rope clamp 10.

The cable car 1 can be made, for example, in the form of a cable car or, respectively, a gondola car, in which the vehicles 5 of the cable car vehicles have cabins or, respectively, gondolas, guided along the platform 6. From the platform 6 in the station 2 of the cable car, passengers can take boarding or disembarking in the means of movement of the cable car 5. The cable car vehicle 5 could, of course, also be used for loading and unloading objects to be transported, such as winter sports equipment, bicycles, prams, etc. For getting on/off people and/or generally for loading/unloading, usually along of the established section of the apron 6, a loading / unloading area is provided. This loading/unloading area can, for example, be specially marked and separated, for example, by barriers 18 from the rest of the area of the cable car station 2, in which unauthorized access is not allowed.

One common loading/unloading area could be provided, for example, in which both embarkation/loading and disembarkation/unloading take place. But usually, a separate loading area E and an unloading area A are provided, which are separated from each other, as shown in Fig.1. This is preferable as the people disembarking and the people making the landing do not interfere with each other. For example, looking in the direction of travel, the first barrier 18a may be located at the beginning of the discharge area A, and the second barrier 18b may be located at the end of the discharge area A. At the beginning of the loading area E, in turn, a barrier 18 can be located, which, for example, can also simultaneously be a second barrier 18b, and at the end of the loading area A, a third barrier 18c can be located. Then, for example, forcedly controlled opening of the doors of the ropeway vehicle 5 can take place, for example, in the region of the first barrier 18a, and closing of the doors in the region of the third barrier 18c. Of course, this is to be understood only as an example, and loading/unloading areas A, E could be arranged differently as well.

FIG. 2 shows the cable car vehicle 5 being detached from the hauling rope 4 in the cable car station 2 as viewed in the travel direction. This cable car vehicle 5 has a movable element K and a linkage 17, wherein the movable element K is located by means of the linkage 17 on the suspension 12 of the cable car vehicle 5 . The ropeway vehicle 5 can be connected via a suspension 12 to the hauling rope 4, for example hanging on the hauling rope 4. The movable element K is suspended on the hinge 17 in a spring-loaded manner, so that the movable element K is able to oscillate relative to the hinge 17. As a result, comfort can be increased. passengers, for example, when traveling on a roller battery of a cable car support, because the shocks that occur are damped. The spring-loaded suspension can, for example, be carried out by means of one or more shock-absorbing units 20, which, of course, can also have damping properties if required. The cable car vehicle 5 can be connected via a suspension 12 to a running gear 13, for example, from at least one running roller. A rope clamp 10 can be arranged on the hanger 12, which can clamp the traction rope 4 under the action of a clamp spring, and which can be mechanically actuated by means of the coupling roller 14 and the clamping lever 15. By means of guide wings in the station 2 of the cable car, which the coupling roller 14 copies when the ropeway vehicle 5 moves, the clamping lever 15 is actuated and the rope clamp 10 opens. The rope clamp 10 is activated for closing by another guide gate and held closed by the clamping spring. On the hanger 12 can also be located a guide roller 16, which in the station 2 of the cable car interacts with the guide rail 7. In the same way, a friction lining 11 can be located, which can interact with the conveyor 8, for example, rotating conveyor wheels 9, to move the unhooked means 5 for moving the cable car along the guide rail 7 through the station 2 of the cable car.

But of course, other embodiments of the cable car 1 and/or the cable car vehicle 5 are also possible, for example, the cable car 1 having the cable car vehicle 5 fixedly clamped on the traction rope 4, or having carrying ropes, on which, by means of the running mechanism 13 the ropeway vehicle 5 is suspended and driven by at least one traction rope 4. Similarly, the ropeway 1 can be designed as a pendulum road with or without a carrying rope, i.e. also with a traction rope 4 going back and forth instead of a circulating traction rope 4. However, the specific embodiment of the cable car 1 for the invention is not essential.

The depicted cable car 1 is designed as a ring road in the form of a cabway, i.e. the movable element K is here a cab. Cabinway cabins often have doors on only one side, since loading/unloading, for example, boarding/unloading people from platform 6, is usually carried out only on one side. For example, in the mountain station of the ring road, an unloading area A can first be provided, in which passengers, as a rule, during the movement of the cable car 5, can disembark from the cab, as shown in Fig.1. After disembarking, the cable car vehicle 5 (most often with an empty car) reverses direction and moves to the loading area E, in which passengers can enter the cabin of the cable car vehicle 5 through the same door 19 to travel to the valley. Of course, this is only an example, and also at the ring road, the doors 19 can be arranged on the cabins on both sides in the transverse direction, for example, in order to first unload the cable car vehicle 5 on one side, and then load it on the other side respectively, if on both sides 6 platforms are provided on the sides. Simultaneous loading and unloading would also be possible.

At the pendulum road, in principle, doors 19 are most often provided on both sides of the cab. However, despite this, boarding and / or disembarking is most often carried out only on one side. For example, at a pendulum road, the door 19 on one side for disembarkation is often opened first, and the opposite door 19 for ingression is staggered in time. Therefore, the ropeway vehicles 5, regardless of the specific embodiment of the ropeway (ringway or pendulum road), are loaded in the transverse direction when boarding or disembarking, most often on one side and eccentrically. Moreover, this load also strongly depends on the number, weight and process of movement of people or material, and therefore is very uneven. Until now, this has resulted in excitation of a swinging movement of the cable car vehicle 5 in the transverse direction (indicated by a double arrow in FIG. unpleasant. Such rocking movements also increase the risk of falling passengers, because the relative movement between the cable car vehicle 5 and the platform in the direction of travel (due to the movement around the ring through the station 2 of the cable car) is superimposed by the relative movement in the transverse direction (swing movement to the sides) and the movement swing in the longitudinal direction. In particular, this can make it difficult for passengers with winter sports equipment, such as ski boots, to get in/out, which can lead to falls and, in the worst case, to injuries. This also makes it difficult to load and unload material.

In the illustrated example, between the linkage 17 and the movable element K of the cable car vehicle 5, for example, a cabin, several shock-absorbing nodes 20 are provided, with which the movable element K of the cable car vehicle 5 is spring-loaded, that is, with the possibility of oscillation, fixed to the hinge 17, as schematically shown in Fig.2. These shock-absorbing units 20 serve in particular to increase the comfort of the passengers during the journey. This can, for example, reduce the unpleasant shocks of the movable element K of the cable car 5, which occur in the region of the cable car support when passing through the roller battery and are most often perceived as unpleasant by passengers. But in a cable car station 2, in which the cable car vehicles 5 most often move along the guide rail 7, being uncoupled from the hauling rope 4, the shock-absorbing units 20 can, however, adversely affect the rocking movements of the cable car vehicle 5 in the longitudinal and transverse direction. direction and, in particular, to strengthen them, because due to the elastic movement of the shock-absorbing units 20 in the vertical direction, the maximum deflection of the cable car vehicle 5 in the transverse direction also increases. Of course, this also depends on the type and design of the damping units 20. In the simplest case, the damping unit 20 can be made, for example, in the form of an elastic buffer element, for example, in the form of a rubber buffer, which also has certain damping properties. But the damping unit 20 could also have appropriate mechanical or pneumatic elastic elements and mechanical, pneumatic or hydraulic damping elements in a known manner. Under the weight of people embarking or disembarking, the movable element K of the cable car vehicle 5 (here, the cabin) in the cable car station 2, due to the elastic movement of the shock-absorbing nodes 20, is lowered or raised relative to the hinge 17, which means an additional relative movement of the cable car vehicle 5 in the direction of height relative to the apron 6. This can increase the swing movement and make it difficult to board or disembark, or, respectively, loading and unloading.

By means of the invention, the safety of passengers during embarkation/disembarkation or, respectively, in general, the safety during loading/unloading of the cable car vehicle 5 is to be increased, when the rocking motion of the cable car vehicle 5 in the transverse as well as in the longitudinal direction is reduced, at least in the area of the indicated loading/unloading areas.

According to the invention, therefore, it is provided that at least one contact rail 23 extending in the direction of travel of the cable car vehicle 5 and fixed relative to the vehicle is provided on the movable element K, and that at least one cable car station 2 is provided with at least one guide section FA having at least one stationary first guide device 22 extending in the direction of travel of the cable car vehicle 5. This first guide device 22, at least during the movement of the cable car vehicle 5 through the guide section FA, interacts with the movable element K by a contact rail 23 of the cable car vehicle 5 to generate a guiding force. As a result, this guiding force shifts the movable element K with respect to the linkage 17 from the initial position, in which the ropeway vehicle 5 can move outside the guide section FA, to a guided position, in which the ropeway vehicle 5 can move through the guide section FA. That is, the spring-loaded arrangement of the movable element K on the hinge 17 of the cable car vehicle 5 is deliberately used to shift the movable element K during movement through the guide section FA relative to the hinge 17 from the initial position to the guided position. In this steered position, the cable car vehicle is subjected to a return force due to the elastic force of the shock-absorbing assembly(s) and/or due to gravity, as a result of which the cable car vehicle 5 tends to return to its original position. In this way, the stability of the cable car vehicle 5 in the transverse direction and in the longitudinal direction can be increased, whereby the swinging movement to the sides, as well as the forward and backward swinging movement of the cable car vehicle 5, in particular the movable element K, can be reduced.

At the ring road, which is shown, for example, in Fig.4, the cable car vehicle 5 during movement through the guide section FAa or FAb is shifted relative to the hinge 17 to the guided position, and in the guided position advances through the corresponding guide section FAa, FAb. Loading / unloading is carried out here, as a rule, during movement in order to achieve the highest possible transport productivity. However, the loading/unloading could of course also be carried out in a state of rest of the cable car vehicle 5 in a steered position. At the end of each guiding section FAa, FAb in the direction of travel, the ropeway vehicle 5 is moved again from the stabilizing guiding position back to the starting position. The movement through the guide section FA can, of course, also be understood as the movement of the pendulum cable car vehicle 5 in the region of the guide section FA of the cable car station 2. At the pendulum road, the ropeway vehicle 5 would initially move in the direction of travel into the pre-set guide section FA on entry and come to rest in the region of this guide section FA. After loading/unloading, the cable car vehicle 5 would move to exit the cable car station 2 in the opposite direction from the guide section FA.

Preferably, at least one first guide device 22 is in the form of a ceiling guide rail 22a, which is located on a stationary structure in the upper area of the cable car station 2, as seen from FIG. The contact bar 23 is disposed respectively in the upper side region on the cable car vehicle 5 in order to cooperate with the ceiling guide bar 22a in the area of the guide section FA. This arrangement is preferred because this area is only barely accessible to people, in particular passengers or cable car personnel, thereby increasing safety.

Also, for improved stabilization of the cable car vehicle 5 in the transverse direction, at least one stationary second guide device 21 extending in the direction of travel of the cable car vehicle 5 can be provided in the guide section FA. 5 the cable car travel in the area of the guide section FA is deflected by the guiding force towards the second guide device 21. In this case, the second guide device 21 cooperates with a part of the ropeway vehicle 5 in the area of the guide section FA to guide the cable car vehicle 5, for example when the cable car vehicle 5 comes into contact with the second guide device 21. Preferably, at least one second guide device 21 is in the form of a floor guide rail 21a, which is located on the stationary structure in the lower area of the station 2 of the cable car, as shown in Fig.2. In this case, this floor guide rail 21a preferably interacts with a distance element 24 located on the cable car vehicle 5, in particular on the movable element K.

In the example according to FIGS. 2+3 along the platform 6 of the cable car station 2, on the platform 6 there is a stationary floor guide rail 21a and a stationary overhead guide rail 22a is located on the opposite side (when viewed in the direction of travel) of the platform 6 in the area above the area passage of passing vehicles 5 movement of the cable car. In the upper region of the movable element K, a contact rail 23 which is stationary with respect to the vehicle is located. The contact rail 23 is located here, for example, directly on the cab roof.

When passing through the cable car station 2, the contact bar 23 of the cable car vehicle 5 in the area of the guide section FA interacts with the ceiling guide bar 22a, for example when the contact bar 23 is in contact with the ceiling guide bar 22a. In this case, the ceiling guide rail 22a and the contact rail 23 are designed in such a way that the movable element K in the region of the guide section FA is pressed vertically downwards by the ceiling rail 22a shown in FIG. As a result of the guiding force acting on one side, the movable element K is additionally pressed in the transverse direction in the direction of or against the floor guide rail 21a (left in FIG. 2) which is respectively opposite when viewed in the direction of travel. As a result, the ropeway vehicle 5 in the region of the guide section FA is forcibly guided substantially along the floor guide rail 21a, so that only very small rocking movements are not possible or only possible. This not only increases the objective safety of passengers when boarding and disembarking, but also increases the subjective sense of security.

In the illustrated example in FIG. 2, the floor guide rail 21a is located on the side of the platform 6 and the ceiling guide rail 22a is permanently located on the opposite side in the area above the cable car vehicles 5 passing by, for example, on the appropriate structure of the cable car station 2. On the movable element K, only one contact bar 23 is provided here on only one side. But of course, the reverse arrangement would also be possible, as indicated in FIG. 2 by dashed lines. The floor guide rail 21a would in this case be located on the opposite side of the platform 6, for example on a suitable fixed structure of the cable car station 2. The ceiling guide rail 22a would accordingly be permanently located on the side of the platform 6 above the platform 6. The contact rail 23 would also be located on the said side of the cable car vehicle 5 facing the platform 6 on the movable element K in order to contact the ceiling guide rail 22a. If the cable car vehicle 5, as shown, includes a car as a movable element K, the contact rail 23 can be located, for example, on the roof of the car.

However, two cable car vehicles 5 propagating in the direction of travel and spaced apart transversely to the direction of travel and stationary with respect to the vehicle could also be arranged on the movable element K. For example, on both sides of the cable car vehicle 5 would be located on one contact bus 23 on the movable element K (in Fig.2 on the right is a solid line, and on the left is a dashed line). This could be advantageous, for example, if several aprons 6 are provided in the cable car station 2 in the direction of travel one after the other and on opposite sides in the transverse direction. , having an apron 6 on one side (for example, in the direction of travel on the left) and a subsequent loading area E having an apron 6 on the respectively opposite side (for example, in the direction of travel on the right). The cable car vehicle 5, in particular the cabin, could then preferably be provided on both sides with a loading/unloading door 19 (indicated by a dashed line in FIG. 2 on the right).

In this case, for the unloading area A, for example, a first guide section FA could be allocated, which presses the cable car vehicle 5 in the direction of the platform 6 of the unloading area (to the left), and for the subsequent unloading area E, a second guide section FA could be provided, having an arrangement of the floor guide rail 21a and the ceiling guide rail 22a reversed from that of the first guide section FA, which presses the cable car vehicle 5 towards the platform 6 of the loading area E (to the right). This embodiment could, for example, be advantageously provided at the middle station of the cable car 1 located between the mountain station and the valley station, since it does not turn around the means of transport of the cable car 5, but travel on two sides (uphill and into the valley). ). But if on both sides of the means of movement of the cable car (when looking in the direction of travel) there are contact bars 23 (Fig.2 dashed + solid), then, despite this, always, respectively, only one of the two contact bars 23 would interact with each ceiling guide rail 22a, resulting in a vertical elastic expansion of the movable element K relative to the hitch 17 in the area of the contact rail 23 and at the same time a slight deflection of the movable element K in the transverse direction, for example, in the direction of the floor guide rail 21a.

However, a combination of the two variants would also be possible, in which one floor guide rail 21a and a ceiling guide rail 22a are located on both sides. On the movable element K in this case, however, only one contact rail 23 would be provided (here, for example, above the car door 19), which then cooperates, for example, only with the ceiling guide rail 22a above the platform 6, in order to press the means 5 the movement of the cable car to the opposite floor guide rail 21a (dashed here). However, the contact bar 23 could in this case also be located on the opposite side in the upper lateral (here right) region of the movable element K (here, for example, on the cab roof). The contact rail would then cooperate with the ceiling guide rail 22a on the opposite side of the platform 6 and would press the cable car vehicle 5 in the direction of the floor guide rail 21a located on the platform 6. As a result, various cable car vehicles 5 can be used, in which the contact rail 23 is located either on the side facing the platform 6 in the upper region of the movable element K (in FIG. 2, for example, above the door 19 on the cabin roof) or on the opposite side in the top area of the floating element K.

The embodiment shown in FIG. 2, in which the floor guide rail 21a is located directly on the platform 6 and the ceiling guide rail 22a on the opposite side of the platform 6 in the upper region above the cable car vehicles 5 passing by, has the advantage that the movable element K is pressed in the direction of the platform 6. As a result, the gap between the cable car vehicle 5, in particular the movable element K, and the platform 6 or the floor guide rail 21a located thereon is minimized, in particular completely closed. This can further increase safety during loading/unloading, in particular when getting on/off people, because, for example, the risk of objects falling into the gap or getting parts of winter sports equipment stuck in it can be reduced.

Preferably, a spacer 24 is also located in a certain lower region of the cable car vehicle 5, which, in the region of the guide section FA, cooperates with the second guide device 21, for example, is in contact with the floor guide rail 21a, as shown in Fig. 2 on the left. If the cable car vehicle 5 has a cabin as the movable element K, it is particularly advantageous if the distance element 24 is located on the cabin under the door and is designed as a step. As a result, it is not directly the cabin and the floor guide rail 21a that are in contact, but the floor guide rail 21a and the spacer 24 or the step. Due to this, for example, less deviation is required towards the movable element K in the direction of the floor guide rail 21a. Alternatively or additionally, also on the side of the cable car vehicle 5 opposite the platform 6, a spacer element 24 can be arranged, here, for example, on the side of the cabin opposite the door 19 . If there is no door 19 on this side, the spacer 24 does not have to be made in the form of a step, but could also be made in any other way. For example, in the form of a suitable rail or in the form of a shaped tube, which is fixed to the cable car vehicle 5 at an appropriate distance in order to contact the floor guide rail 21a (here on the right) in the area of the guide section FA.

According to another embodiment of the invention, it can be provided that at least two cable car vehicles 5 propagating in the direction of travel and located at a distance from each other transversely to the direction of travel, stationary relative to the vehicle, are located on the movable element K, and that in addition, at least two stationary first guide devices 22 were provided in at least one guide section FA. Each of the first guide devices 22 interacts with one of the contact bars 23 to generate a guiding force. The contact rails 23 could, for example, be arranged transversely on both sides of the cable car vehicle 5, respectively in the upper region of the movable element K, here on the car roof, as shown in FIG. 2 (solid and broken lines). These two stationary first guides 22 can respectively be in the form of ceiling guide rails 22a and interact simultaneously with both contact rails 23 in order to move the movable element K relative to the hinge 17 into a guided position.

In this case, in contrast to the previously described embodiments, the movable element K is loaded by the first guide devices 22 simultaneously in two positions in the transverse direction. This has the effect that the movable element K on both sides respectively in the area of the contact bars 23 is pressed against the hinge 17 against the elastic force or the return force of the shock-absorbing units 20 vertically downwards. The return forces of the shock-absorbing units 20 counteract this displacement, as a result of which a stable position of the movable element K is established. limited, in particular completely suppressed. As a result, rocking movements in the direction of travel K are reliably reduced, preferably prevented. in the direction of travel (swing forward and backward). The second (double) embodiment has the advantage, compared to the first (one-sided) embodiment, that essentially no deflection to the sides of the movable element K takes place in the guide section FA. Through the guide section, the FA can be oriented essentially parallel to the platform 6, whereby the comfort of boarding/disembarking can be further increased.

Regardless of the implementation, preferably at least one first guide device 22 and/or at least one second guide device 21 is made in the form of a skid. Alternatively, or additionally, also on at least one first guide device 22 and/or at least one second guide device 21 in the direction of travel of the cable car vehicle 5, several rotatably mounted rollers 25 could be arranged one behind the other. the friction between the cable car vehicle 5 and the corresponding guide device 21, 22 can be reduced during the passage of the cable car vehicle 5 through the guide section FA.

In the example shown in FIG. 2, on the ceiling guide rail 22a in the direction of travel of the cable car 5, a number of rotatably mounted rollers 25 are positioned one behind the other. As a result, the friction during the passage of the cable car 5 can be reduced when these rollers 25 are rolled over. on the return contact bus 23 means 5 of the movement of the cable car. As a result, a smooth and low-noise direction is possible. For this, the contact bar 23 can also be provided with a suitable rolling surface for rolling the rollers 25. In general, the contact bar 23 is preferably made of a material having a sufficiently high strength, which is also suitable for the expected weather conditions. For example, the proper metal material or the proper plastic may be used for this. However, the contact rail(s) 23 could, for example, also be integrated directly into the movable element K, for example into the cab roof. As a result, the contact bar 23 could, for example, run essentially flush with the roof of the car, which improves the appearance of the cable car vehicle 5 and facilitates cleaning.

Figure 3 shows the means of movement of the cable car 5 from figure 2 in a side view from the opposite side of the platform 6 (figure 2 on the right). This image clearly shows the interaction of the stationary overhead guide rail 22a of the cable car station 2 and the contact rail 23 of the cable car vehicle 5 which is fixed relative to the vehicle. The floor guide rail 21a is here in the form of a skid, on which a cable car vehicle 5 slides in the area of the guide section FA, preferably having a distance element 24 attached to it. On the skid and/or on a component of the cable car vehicle 5 in contact , for example, the spacer 24, for this purpose, for example, an appropriate slippery pad can be provided. In this case, materials are preferably used as the slippery lining, which are suitable for minimizing friction and ensuring that the sliding movement is as quiet as possible, for example, plastic. As an alternative to the skid, also on the floor guide rail 21a, similarly to the ceiling guide rail 22a, several rollers (not shown) can be arranged one behind the other in the direction of travel.

These rollers would then roll over the cable car vehicle 5, preferably over the spacer 24 located thereon. at least one first guide device 22 and/or at least one second guide device 21 could be provided with a (not shown) damping device. Alternatively, or additionally, a damping device 26 could also be provided on at least one contact bar 23. This damping device can include, for example, a mechanical spring or a gas spring, as well as a mechanical, pneumatic or hydraulic damper, in a known manner. In the simplest case, for example, a suitable buffer element could also be provided, such as, for example, a rubber buffer. The damping device 26 shown in FIG. 3 serves to absorb and dampen the vertical movements of the cable car vehicle 5 which occur in particular when the cable car vehicle 5 enters the guide section FA.

In this way, hard shocks of the cable car vehicle 5 due to the hard impact of the contact bar 23 against the ceiling guide bar 22a can be prevented. In a similar way, alternatively or additionally, a damping device (not shown) could also be provided on the floor guide rail 21a in order to absorb and dampen the horizontal movements of the ropeway vehicle 5 in the area of the guide section FA. In this case, this damping device 26 would have to have a sufficiently soft damping characteristic so that shocks are reliably absorbed, but it would also have to be sufficiently rigid so that rocking vibrations of the cable car vehicle 5 are reliably suppressed. Therefore, all possible damping devices 26 on the contact bars 23 and/or on the guide devices 21, 22 would have to be made relatively inelastic compared to the spring-loaded attachment (for example, shock-absorbing nodes 20) of the movable element K on the attachment 17. In the case of a skid, it could a slippery pad is also used, which has certain elastic / damping properties.

As shown in figure 3, the contact bar 23, when viewed in the direction of travel, may also have rounded ends. Alternatively or additionally, the first guide device 22 can also have rounded ends when viewed in the direction of travel. This is advantageous because, at the beginning of the guide section FA, a clamping pressure that gradually increases in the direction of travel is achieved on the cable car vehicle 5 . As a result, the movable element K is not abruptly shifted from the starting position to the guiding position, but smoothly, whereby the comfort can be improved. In the same way, at the end of the guiding portion FA, a smoothly decreasing pressing pressure can be achieved. In the example shown, both the ceiling guide rail 22a and the contact rail 23 are rounded. In principle, however, it would also suffice if only the contact rail 23 or the ceiling rail 22a had curved ends. Between the contact rail 23 and the cable car vehicle 5, here the cabin roof 4, in the example shown there are two damping devices 26, the function of which has already been described. Figure 3 also shows that the contact bar/buses 23 in the direction of travel extend over a relatively large area of the element K to be moved. so that rocking movements of the movable member K in the direction of movement (forward-backward rocking) can be reliably prevented.

As already explained, the movable element K of the cable car vehicle 5 is spring-loaded, for example by means of at least one shock-absorbing unit 20, i.e. oscillatedly mounted on the linkage, in order to increase passenger comfort during the journey. In the illustrated example, four shock-absorbing nodes 20 are located between the hitch 17 and the movable element K (cab), as seen in figure 2 and figure 3. Due to the interaction of the overhead guide rail 22a and the contact rail 23 located on the cab, the shock-absorbing units 20 in the area of the guide section FA are preferably pretensioned so that when getting on/off people or generally when loading/unloading the cable car 5 is not possible or only possible very small rocking movements of the cable car vehicle 5 and/or only a slight lowering of the cable car vehicle 5 under the weight of the load.

In the one-sided version, the movable element K, due to the interaction of the contact bar 23 with the first guide device 22 of the cable car station 2, is pressed down on one side relative to the hinge 17. Therefore, the shock-absorbing units 20 on the respective side are resiliently released and thus pretensioned. The shock-absorbing units 20 on the respective other side are respectively compressed elastically because the movable element K on this side moves upward relative to the hinge 17 due to the torque generated by the guiding force. In the illustrated example according to FIGS. 2 and 3, the ceiling guide rail 22a and the contact rail 23 (and, if necessary, the floor guide rail 21a) could be designed so that the shock-absorbing units 20 on the apron side (on the left in FIG. 2) are as good as possible. more compressed in the vertical direction, and opposite/-th platform 6 shock-absorbing node/nodes 20 (figure 2 on the right) as much as possible stretched in the vertical direction. In this case, in the region of the guide section FA, usually (during a trip between cable car stations 2) the preferred oscillating suspension of the movable element K on the linkage 17 is essentially blocked, so that the cable car vehicle 5 can move through the guide section FA as freely as possible. from disturbing movements in a rocking manner.

In the double-sided version, the movable element K is pressed down on both sides relative to the suspension 17 by the interaction of the contact rails 23 which are transversely spaced with the ceiling guide rails 22a of the cable car station 2 . Therefore, the shock-absorbing units 20 on both sides are resiliently unclamped and thereby pretensioned. Ceiling guide rails 22a and contact tires 23 in figure 2 (dashed and solid) are preferably structurally designed so that the shock-absorbing node/nodes 20 from the side of the platform (left in figure 2) and the shock-absorbing node/nodes 20 opposite to the platform 6 (on the right in FIG. 2) are stretched as much as possible in the vertical direction, so that the return forces of the shock-absorbing units 20 stabilize the movable element K. In this case, in the region of the guide section FA, the spring suspension of the movable element K on the hinge 17 is essentially blocked, so that the means 5 movement of the cable car can move through the guide section FA as free as possible from disturbing rocking movements.

FIG. 4 shows a cable car station 2 according to the invention in the form of a ring cable car cabin, the basic design of which essentially corresponds to the cable car station according to FIG. The direction of movement of the traction rope 4 and thus the direction of movement of the ropeway vehicle 5 is indicated by arrows. Accordingly, on the platform 6 on the left, between the two barriers 18a, 18b, a landing area or, respectively, an unloading area A in general is provided. On the platform 6 on the right, between the two barriers 18c, 18d, a landing area or a loading area E in general is provided. As an example, the unloading area A extends here partly along the straight area of the apron 6 and partly up to the curved area of the apron 6. The loading area E extends here only along the straight section of the apron 6. But of course, this should only be understood as an example, and could be provided any other location.

A first guide section FAa is provided in the loading area E, and a second guide section FAb is provided in the loading area E. The guide sections FAa, FAb are made here according to the first embodiment, that is, they have one stationary first guide device 22 located on one side, as well as one stationary second guide device 21 located on the same side, as explained with the help of Fig.2+3 . On the platform 6 in the unloading area A there is a first floor guide rail 21a.1, and on the platform 6 in the unloading area A there is a second floor guide rail 21a.2. Opposite the platform 6 of the unloading area A in the upper area of the cable car station 2, above the passing vehicles 5 of the cable car vehicles, a first overhead guide rail 22a.1 is located, and opposite the platform of the loading area E in the upper area, a second overhead guide rail 22a.2 is located. For better visibility, the traction rope 4 and the rope pulley 3 are shown broken in the area of the ceiling guide rails 22a.1, 22a.2. On the moving elements K of the means 5 of the movement of the cable car is located only on one contact bus 23.

On both ceiling guide rails 22a.1, 22a.2, in the direction of travel, several rollers 25 are located one after the other, which interact with the contact rail 23 of the cable car vehicle 5 located in the corresponding guide section FAa, FAb, in particular they roll over it. In this way, the respective ropeway vehicle 5, as described, is pressed in the direction or respectively against the floor guide rail 21a.1, 21a.2. Ceiling guide rails 22a.1, 22a.2. run parallel to the corresponding apron 6, the first overhead guide rail 21a.1 extending up to the turning area and accordingly having a bend. So, as indicated by the dashed line between the two ceiling guide rails 22a.1, 22a.2, instead of two separate ceiling guide rails 22a.1, 22a.2, one single continuous ceiling guide rail could of course also be provided, and on the platform 6 could a single floor guide rail would likewise be provided.

The exemplary embodiments described with reference to FIGS. 1 to 4 are, of course, to be understood only as examples and in a non-limiting manner for the invention. The invention, for example, is not limited to the circular cable car depicted, but could, of course, also be applied to other versions of cable cars, for example at pendulum roads. Also, the means 5 of the movement of the cable car could be made in any other way. Essential to the invention is the principle of operation, according to which the rocking movements of the movable element K in the longitudinal and transverse direction in the area of the guide section FA are reduced when at least one stationary guide device 22 of the station 2 of the cable car interacts with the K located on the movable element, which is fixed relative to the means by the contact bar 23 of the cable car vehicle 5 to generate a guiding force on the movable element K, which shifts the movable element K from the initial position (outside the guiding section FA) to the guiding position within the guiding section FA. The specific constructive embodiment is left to the discretion of the specialist.

Claims (17)

1. Cable car (1) having at least two stations (2) of the cable car and having at least one means (5) of movement of the cable car, which can move with a traction rope (4) between the stations (2) of the cable car, and this means (5) of movement of the cable car has a movable element (K) and a hinge (17), and this movable element (K) serves to accommodate people and / or objects and the movable element (K) is suspended on the hinge (17), while on the movable element (K) there is at least one contact rail (23) that propagates in the direction of movement of the cable car vehicle (5), fixed relative to the vehicle, and at least one guide rail is provided in at least one station (2) of the cable car section (FA) having at least one stationary first guide device (22) extending in the direction of movement of the means (5) of movement of the cable car, characterized in that it moves the element (K) is suspended on the hinge (17) in a spring-loaded manner and that this first guiding device (22) interacts with the contact bar (23) of the means ( 5) movement of the cable car to generate a guiding force, this guiding force displacing the movable element (K) relative to the hinge (17) from the initial position, in which the means (5) of the cable car can move outside the guide section (FA), to the guided position , in which the means (5) of movement of the cable car can move through the guide section (FA). 2. Cable car according to claim 1, characterized in that on the moving element (K) there are at least two means (5) of movement of the cable car extending in the direction of movement and located at a distance from each other across the direction of movement, fixed relative to the means of movement contact rail (23) and that at least one guide section (FA) is provided with at least two stationary first guide devices (22), each of these first guide devices (22) interacting respectively with one contact bar (23) for creating a guiding force. 3. Cable car according to claim 1 or 2, characterized in that at least one first guide device (22) is made in the form of a ceiling guide rail (22a), which is located on a stationary structure in the upper area of the station (2) of the cable car, and that in the upper side area on the movable element (K) there is a mating contact bus (23). 4. Cable car according to one of claims 1 to 3, characterized in that at least one guide section (FA) is provided with at least one stationary second guide device (21) extending in the direction of movement of the means (5) of movement of the cable car , while the movable element (K) in the area of the guide section (FA) is deflected by the guiding force in the direction of this second guide device (21), while the second guide device (21) in the area of the guide section (FA) interacts with the vehicle (5) of movement cable car for directing means (5) of movement of the cable car. 5. Cable car according to claim 4, characterized in that at least one second guide device (21) is made in the form of a floor guide rail (21a), which is located on a stationary structure in the lower area of the station (2) of the cable car. 6. Ropeway according to one of claims 1 to 5, characterized in that at least one first guide device (22) is made in the form of a skid, and / or that at least one second guide device (21) is made in the form of a skid , and/or that on at least one first guide device (22) in the direction of movement of the means of movement of the cable car (5) there are several rotatably mounted rollers one after the other, and/or that on at least one second guide device ( 21) in the direction of movement of the means (5) of movement of the cable car, several rotatably mounted rollers are located one behind the other. 7. Ropeway according to one of claims 1 to 6, characterized in that at least one first guide device (22) and/or at least one second guide device (21) has a damping device and/or that said at least at least one contact bar (23) has a damping device (26). 8. Ropeway according to one of claims 1 to 7, characterized in that the movable element (K) is made in the form of a cabin. 9. A method for operating a cable car (1) having at least one cable car vehicle (5) that can be moved by a traction rope (4) between cable car stations (2), and this cable car vehicle (5) has a movable element (K) and hinge (17), and this movable element (K) serves to accommodate people and / or objects, and the movable element (K) is suspended on the hinge (17), while the means (5) of the movement of the cable car moves in guide section (FA) of the cable car station (2), wherein the stationary first guide device (22) of the cable car station (2) extends in the direction of movement of the cable car vehicle (5) during the movement of the cable car vehicle (5) through the guide section (FA) interacts with the cable car located on the moving element (K), which extends in the direction of movement of the means of movement (5), fixed relative to the means of movement by a contact bar (23), characterized in that the movable element (K) is suspended on the hitch (17) in a spring-loaded manner and that the first guide device (22) and the contact bar (23) interact to create a guiding force by which the movable element (K) during movement through the guide section (FA) moves relative to the hinge (17) from the initial position, in which the ropeway vehicle (5) moves outside the guide section, to the guided position, in which the ropeway vehicle (5) moves through the guide section (FA). 10. The method according to claim 9, characterized in that the two stationary first guides of the device (22) of the station (2) of the cable car extending in the direction of travel of the cable car (5) travel through the guide section (FA) interact with two located at a distance from each other on the movable element (K) across the direction of movement, extending in the direction of movement of the means of movement of the cable car (5), stationary relative to the vehicle contact tires (23) to create a guiding force, while each of these first guide devices (22) interacts respectively with one contact bar (23). 11. The method according to claim 9 or 10, characterized in that as the first guide device (22) a ceiling guide rail (22a) is used, which is placed on a stationary structure in the upper area of the station (2) of the cable car, and that in the upper side areas on the means (5) of movement of the cable car have a response contact bus (23). 12. A method according to one of claims 9 to 11, characterized in that the movable element (K) in the area of the guide section (FA) is deflected by the guiding force in the direction of the vehicle (5) spreading in the direction of movement located in the guide section (FA) cable car, a stationary second guide device (21), wherein the second guide device (21) in the area of the guide section (FA) interacts with the cable car vehicle (5) to guide the cable car vehicle (5). 13. A method according to one of claims 9 to 12, characterized in that a floor guide rail (21a) is used as the second guide device (21), which is placed on a stationary structure in the lower area of the cable car station (2). 14. A method according to one of claims 9 to 13, characterized in that a skid is used as at least one first guide device (22) and/or as at least one second guide device (21) and/or that according to at least one first guiding device (22) and/or at least one second guiding device (21) in the direction of movement of the means of movement of the cable car (5) there are several rotatably mounted rollers one behind the other. 15. A method according to one of claims 9 to 14, characterized in that at least one first guide device (22) and/or at least one second guide device (21) is provided with a damping device and/or that the at least one contact bar (23) is placed on the moving element (K) by means of at least one damping device (26). 16. A method according to one of claims 9 to 15, characterized in that at least one distance element (24) is located in the lower area of the cable car vehicle (5) on at least one side, which in the area of the guide section (FA ) interacts with the second guide device (21) to guide the means (5) of movement of the cable car. 17. A method according to one of claims 9 to 16, characterized in that a cabin is used as the moving element (K).

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