EP0711696A1 - Garage for the vehicles of an aerial tramway with endless loop - Google Patents

Abstract

The garage (1) is for the vehicles (5) of a cable railway which slowly circulate around the platform of a station rail (2), having been uncoupled from the conveyor cable (9). It has several parallel parking rails (3) arranged in a rectangle, with a feeder rail (4) between the station rail and the parking rails. Exit points and entry points are arranged between the station rail and feeder rails. Points (7) are arranged between each parking rail and the rails feeding in and out, and conveyor devices bring the vehicles from these station rail via the feeder rail to the parking rails and back again. Between the feeder rail (41) feeding the station rail and the feeder rail (42) removing vehicles from it, a crossing (6) is provided controlled with two points pieces (6).

Description

The invention relates to a garage for the vehicles of a circulating ropeway, which slowly bypass the platform of a station track, uncoupled from the conveyor cable, with several parallel, preferably arranged in a rectangle siding, with a feeder track between the station track and the siding, with an outlet switch and with an inlet switch between the station track and the feeder track that sends or emits it, with one switch between each siding and the feeder track that sends or send it and with conveyors that move the vehicles from the station track over the feeder track to the siding and back again promote.

At the stops of a cable car, there are usually coupling points at the inlet and outlet. At the inlet coupling point, the vehicles conveyed at up to about 6 m / sec on the conveyor rope are uncoupled from the rope and decelerated to a slow loading speed of about 0.2 to 0.8 m / sec, with which they land a platform on the track of a station track drive around the incoming to the outgoing rope while the passengers can leave or climb onto the platform. At the outlet coupling point, the vehicles must be accelerated until they are synchronized with the conveyor cable and then coupled to the cable again.

In order to adapt the circulating ropeway to the transport capacity required in each case, it is known to park currently unused vehicles at the stops on siding of garages; the garage capacity can be measured on all vehicles, which are then parked protected from the weather when the cable car system is shut down. The siding of known garages are mostly arranged in a loop, are loaded from the station track via an incoming switch and sent via an outgoing switch, cf. eg EP 306 771 B1, EP 245 163 B1 or FR 24 96 029. The loop shape has the advantage that the Siding on, if necessary, existing storage rooms can be adjusted, but such a siding can not be loaded flexibly, that is, the vehicles must drive out of it in the order in which they enter the garage. The space utilization is not optimal due to the wide, semicircular arches to be traversed in such a garage.

A garage made known by EP 369 981 B1 with the features mentioned at the beginning has only a single feeder track, the conveying direction of which is reversible from the station track to the siding for loading or unloading with vehicles. When loading the station track with vehicles from the siding, the cable car conveys in the normal operating direction; however, the direction of conveyance at the cable car system must also be reversed to load the siding. This disrupts the normal operating process, especially if, in order to adapt to the transport capacity currently used, only a few vehicles are to be taken out of the cable car operation because the cable car system must then carry out pilgrim steps, e.g. two steps forward, then one back. Also, no passengers are allowed to be on the conveyor line before all vehicles are merged. A switch to the feeder track is arranged on the station track and on each siding; Thus, a flexible loading and unloading of the siding is already possible with this known garage. The use of space is also cheaper compared to the loop shape, the parallel siding can be placed closer together because only one quarter of a circle can be passed on each turnout.

In contrast, the task is to be solved to allow flexible loading of the siding without disturbing normal operation of the cable car system.

This object is achieved in the garage according to the invention with the features that in each case a separate feeder track, which is continuously conveying in only one direction, is available for loading the siding from the station track or for loading the station track from the siding, and that between that A feeder track supplying the station track and the feeder track emitting it is arranged an intersection controlled by two switch pieces.

Gondolas, armchairs or the like are provided as vehicles in the invention, which can be coupled to the conveyor cable of the cable car system via a hanger with at least one cable clamp. In order to always convey such vehicles with continuous conveyors forward in the direction of travel, the hanger of each vehicle must necessarily be led to the other side of the other feeder track once before entering or leaving the garage; this is done in the invention at the individual intersection between the two feeder tracks, where each vehicle crosses the other guide rail with its hanger. Each switch piece has two connecting pieces with which it alternately engages in the guide rails on one or the other feeder track. The inserted connector provides guidance between adjacent conveying devices, the other connector, which is out of engagement, creates a gap in the other guide rail for the passage of the hanger.

With this measure according to the invention, the vehicles with continuous conveyors can always be conveyed forward in the direction of travel.

The funding institutions are known per se. Chain conveyors or ramp conveyors are used, each of which positively engages the vehicle's hanger. Pneumatic wheel conveyors frictionally drive onto the rope clamps, they can convey in a straight line or in an arc; in the case of gondolas, the tire wheel conveyors can also frictionally drive onto the floor of the vehicles. At the connection points between adjacent conveyors, the vehicles are alternately handed over to the subsequent conveyors in a frictional or form-fitting manner.

In the case of the invention, preferably at the entrance and at the exit to the garage on the feeder track, a sliding switch with a sheet conveyor can be moved between the individual siding, which connects the respective feeder track and the siding. The sheet conveyor on it can also be used to move the sheet conveyor on the siding, which provides a cost-effective solution, especially for more than three or four siding.

In a particularly advantageous development of the invention, a storage section with defined stops for several vehicles to form a buffer is arranged on each feeder track between adjacent conveying devices. Individually controllable individual drives define several stops for successive vehicles within each storage section. The storage section arranged on the feeder track feeding the station track forms a trailing buffer from which it can be conveyed in the direction of the station track as long as the sliding switch on the siding is moved; then it is refilled with vehicles. The storage section arranged on the feeder track feeding the garage forms a lead buffer, which is always refilled with vehicles when the sliding switch on the siding is moved.

The buffer feeding the station track is preferably clocked via a control line from the station track, which ensures that vehicles are inserted into the gaps on the conveyor cable with accurate dimensions.

In a still further embodiment of the invention, a connecting piece enables the vehicles at the intersection to preferably pass straight from one feeder track to the other. A vehicle that has just been serviced on the feeder track emitting the garage can thus be brought directly back to the feeder track loading the garage and parked on one of the siding tracks without having to pass through the cable car. Preferably, the two switch pieces inserted at the intersection serve directly as a connecting piece.

Fig.1

ist die erfindungsgemäße Garage dargestellt;

• a) ist eine Seitenansicht,
• b) ist eine Draufsicht. In

Fig.2

ist die Kreuzung zwischen den beiden Zubringergleisen samt den Staustrecken in einer Draufsicht dargestellt.

Fig.3

zeigt die Schiebeweiche mit dem Bogenförderer,

• a) ist eine Draufsicht,
• b) zeigt sie von vorn gesehen. In

Fig.4

ist der Antrieb für die beiden Weichenstücke an der Kreuzung dargestellt,

• a) ist eine Draufsicht,
• b) ist eine Vorderansicht.

A preferred embodiment according to the invention is explained in more detail below with reference to the drawing: In

Fig. 1

the garage according to the invention is shown;

• a) is a side view,
• b) is a top view. In

Fig. 2

the crossing between the two feeder tracks together with the storage sections is shown in a top view.

Fig. 3

shows the sliding switch with the sheet conveyor,

• a) is a top view,
• b) shows them seen from the front. In

Fig. 4

the drive for the two switch pieces is shown at the crossing,

• a) is a top view,
• b) is a front view.

According to Figure 1 , the station track of a stop station of a circulating cable car is designated by 2; in the illustrated embodiment, this is the valley station of a four-seater chairlift, whose vehicles 5 are uncoupled from the conveying rope 9 when entering the holding station, on a cf. slow driving speed are decelerated, with which they bypass the platform of the holding station on the track of the station track 2 (clockwise in the plan view according to FIG. 1b); there (up to four) passengers can get in before the vehicle 5 accelerates again to the cable conveying speed, is coupled to the conveyor cable 9 and exits the holding station in the direction of arrow B uphill.

In addition to the station track 2, a garage (designated underground as 1) is arranged. Seven parallel siding tracks 3 ₍₁₎ to 3 ₍₇₎ are arranged in a rectangle and have open track ends on two opposite sides of this rectangle. The garage 1 is connected to the station track 2 via two feeder tracks 4 1, 4 2, on which the vehicles 5 can be conveyed in one or the other direction. The feeder track 4 1 which feeds the garage 1 is passable from the station track 2 via an outgoing switch 2 1; the feeder track 4₂ loading the station track 2 from the garage 1 has on Station track 2 is an incoming switch 2₂ which is arranged in relation to the outgoing switch 2₁ on the track of the station track 2 in the direction of travel. Both feeder tracks 4₁, 4₂ are on both ends at right angles to the open track ends of the seven siding 3 ₍₁₎ to 3 ₍₇₎ .

Between the open track ends of the siding 3 ₍₁₎ to 3 ₍₇₎ and the associated feeder track 4₁ or 4₂, a sliding switch 7₁ or 7₂ between the seven siding 3 ₍₁₎ to 3 _{(7) is} movable and on each loading siding 3 _{(i) can be} locked, on which the vehicles 5 can be conveyed to the respective siding 3 _(i) via a quarter circle. On both feeder tracks 4 ₁ and 4 2 and on the siding 3 ₍₁₎ to 3 ₍₇₎ , corresponding conveying devices 10 are arranged, which alternately attack the hanger 5 1 at the respective transfer points or drive onto the cable clamps 5 2 of the vehicles 5.

Between the two feeder tracks 4₁ and 4₂ a single, generally designated 6 intersection is arranged, which is controllable with two switch pieces 6₁ and 6₂. If the garage loading feeder track 4 ₁ is used by vehicles 5, then the associated switch piece 6 1 is inserted at the intersection 6 and connects the adjacent guide rails, while the other switch piece 6 2 is disengaged, on the other guide rail of the feeder track 2 feeding feed track 4₂ to clear a gap for the passage of the hanger 5₁.

In the embodiment shown in Fig.1, the two feeder tracks 4₁, 4₂ in parallel to each other are brought vertically to the siding 3, are deflected at the intersection 6 at right angles, run parallel to them over the length of the siding 3 and are then over the corner of the rectangle is brought up to the track ends of the siding 3 that are open on both sides. At the intersection 6 is in the conveying direction, in the plan view according to Fig.1b counterclockwise, a straight passage from one 4 ₁ to the other Feeder track 4₂ possible if both switch pieces 6₁ and 6₂ are inserted.

Two buffers are provided for the continuous loading of both the station track 2 and the siding 3 with vehicles 5 conveyed on continuous conveyors 10. So on the one hand on the garage 1 loading feeder track 4 1 in the conveying direction after the intersection 6, a storage section designated as 8 1 for six vehicles 5 is set up; on the other hand, on the feeder track 4₂ feeding the station track 2 in the conveying direction in front of the intersection 6 there is a storage section labeled 8₂ for likewise six vehicles 5. The storage section 8₂ loading the station track 2 is also clocked via a control line 9 from the station track 2.

The control of the storage sections 8 1 and 8 2 is explained in more detail with reference to FIG. 2 :

On each of the feeder tracks 4₁ and 4₂, six individually controllable individual drives 8₁₁ to 8₁₆ or 8₂₁ to 8₂₆ each define six consecutively arranged stops for six vehicles 5 ₍₁₎ to 5 ₍₆₎ within the storage sections 8₁ and 8₂ between adjacent conveyors. The individual drives 8₁₁ to 8₁₆ or 8₂₁ to 8₂₆ drive frictionally via tire wheels on the rope clamps 5₂ of the vehicles 5. The storage section 8₂ arranged in the feeder track 2 feeding the station track 2 serves as a follow-up buffer; the in the garage 1 loading feeder 4₁ arranged storage section 8₁ serves as a lead buffer, each seen in the conveying direction to the associated sliding switch 7₁ or 7₂.

In the operating mode shown in FIG. 2 "loading station track with vehicles", all continuous conveyors of the feeder track 4₂ feeding the station track 2 are put into operation, convey in the direction of arrow S, and the switch piece 6₂ belonging to the feeder track 4₂ is inserted at the intersection 6. The conveyors 10 of the other feeder track 4 ₁ are not required, are therefore conveniently turned off; to the feeder track 4 ₁ associated switch piece 6₂ the intersection 6 is out of engagement. Before the station track 2 is loaded, the buffer within the storage section 8₂ must first be filled with six vehicles 5 ₍₁₎ to 5 ₍₆₎ . As soon as the buffer is full, the individual drive 8 2 ₁ located in the conveying direction S at the front via the control line 9 from the station track 2 follows the respective cycle sequence at which time intervals the continuously running follow-up conveyor must be loaded with a vehicle 5 _(i) ; in the meantime, the stagnation route 8₂ is filled up again and again from behind. If a siding 3 _{(i) is} completely emptied, the associated sliding switch 7₂ moves to another; meanwhile, the station track 2 from the buffer of the storage section 8₂ is further loaded.

In this operating mode, when the cable car system is started up, all vehicles 5 from the garage 1 can be coupled to the conveyor cable 11 in a continuous sequence; however, it is also possible, if necessary, to put only a part of the vehicles 5 into operation and to hang them on the conveyor cable 11 at correspondingly greater distances from one another. The gaps between the vehicles 5 can be filled when a higher transport capacity is needed on the cable car system.

The operating mode "loading garage with vehicles" runs essentially analogously in the direction of arrow G. First, the buffer of the storage section 8 1 is to be filled with six vehicles 5, then a siding 3 _{(i) is} loaded by starting up the subsequent conveyor; The start signal for loading garage 1 is given by the last individual drive in the garage conveying direction as soon as a vehicle 5 is at this stop. When the respective siding 3 _{(i) is} filled, the storage section 8 1 is filled; meanwhile, the sliding switch 7 ₁ moves to another siding. In this operating mode, when the cable car system is taken out of operation, all vehicles 5 located on the conveyor cable 10 can be trained; it can, however, only be used for adjustment to the transport capacity required, if necessary, only every second or third vehicle 5 located on the conveyor cable 10. In this operating mode it is also possible, for example, to collect vehicles in need of maintenance on one of the siding 3 _(i) before they are moved to one of the siding according to FIG Garage 1 detachable feeder track 4₂ arranged maintenance station 12 to be overhauled.

The continuous conveyors on the feeder tracks 4₁ or 4₂ and the siding 3 ₍₁₎ to 3 ₍₇₎ can work with different conveyor speeds; this is shown in the top view according to FIG. 1b from the different distances between successive vehicles 5.

A particularly preferred embodiment of the sliding switch 7 is movable according to FIGS. 3a and b with three wheels 7 angeordneten₁ to 7₄₃ arranged on a frame on two rails 7₆₁ and 7₆₂ between the siding (3 ₍₁₎ to 3 ₍₇₎ according to Fig.1) ; a single drive 7₅ drives on an impeller 7₄₁ on the rail 7₆₁. On each siding 3 _(i) , the sliding switch 7 is locked with a lock 7₃₄. A total of 7₃ designated sheet conveyor drives frictionally via a total of six tire drives 7₃₁ on rope clamp-fixed walkways 5₂₂, the rope clamps 5₂ roll with two rollers 5₂₁ in a quarter circle over two associated rails 7₃₃ on the respective siding 3 _(i) . The tire wheel drives 7₃₁ are inevitably driven in the same direction by a single drive 7₃₂ via traction means.

The drive of the switch pieces 6₁ and 6₂ at the intersection 6 is shown in Fig.4a and b , in which the switch piece shown in Fig.1b and 2 is again designated 6₁. On both feeder tracks 4 1 and 4 2, a straight piece 6 11 and an arch piece 6 12 are inserted alternately to control the crossing 6 on the switch piece 6 1 (or 6 2) as connecting pieces. The straight piece 6₁₁ creates the connection on the guide rail of the garage 1 loading feeder track 4₁. The bow piece 6₁₂ belongs to the other guide rail of the feeder track 2 loading feeder track 4₂; in the designed state it creates the gap for the passage of the hanger 5 1 and in the inserted state the connection on the guide rail for the passage of the arch on the feeder track 4 2.

The drive is via a total of 6₃ designated crank arm, consisting of drive motor 6₃₁ with reduction gear, crank 6₃₂, coupling 6₃₃ and swing arm 6₃₄. The straight piece 6₁₁ and the curved piece 6₁₂ are firmly connected to the rocker 6₃₄; the engagement position of the straight piece 6₁₁ is shown in Figure 4a with solid lines, its disengaged position is shown with dashed lines. On the rocker 6₃ the coupling 6₃₃ engages pivotally, which is rotatably connected to the driven crank 6₃₂ on its crank pin.

Claims (7)

Garage (1) for the vehicles (5) of a cable car that slowly bypasses the platform of a station track (2), uncoupled from the conveyor cable (9),
with a plurality of siding tracks (3) parallel to one another, preferably arranged in a rectangle, with a feeder track (4) between the station track (2) and the siding tracks (3),
with an outlet switch (2₁) and with an inlet switch (2₂) between the station track (2) and the feeder track (4), which sends or sends it, with
one switch (7) between each siding (3) and the feeder track (4) that sends or emits it, and with conveyors that move the vehicles (5) from the station track (2) over the feeder track (4) to the siding (3 ) and back again,
characterized,
that in each case a separate feeder track (4₁ or 4₂), which is continuously conveying in only one direction, is available for loading the siding (3) from the station track (2) or for loading the station track (2) from the siding (3), and
that between the station track (2) feeding feeder track (4₁) and the sending track (4₂) it is a two-way pieces (6₁ or 6₂) controlled crossing (6) is arranged. Garage according to claim 1, characterized in
that at the entrance and at the exit to the garage a sliding switch (7₁ or 7₂) with a sheet conveyor (7₃) on the feeder track (4₁ or 4₂) between the individual siding (3 _(i) ) can be moved. Garage according to claim 1 or 2, characterized in
that on each feeder track (4₁ or 4₂) between adjacent conveyors a storage section (8₁ or 8₂) with defined stops for several vehicles (3) is arranged to form a buffer. Garage according to claim 3, characterized in
that each individually controllable individual drives (8₁₁ to 8₁₆ or 8₂₁ to 8₂₆) in each storage section (8₁ or 8₂) define a stop. Garage according to claim 4, characterized in
that the storage section (8₂) is clocked on the feeder track (4₂) feeding the station track (2) via a control line (9) from the station track (2). Garage according to one of claims 1 to 5, characterized
characterized in that at the intersection (6) a connector allows the vehicles (5) a preferably straight passage between the two feeder tracks (4₁ and 4₂). Garage according to claim 6, characterized in
that serve as a connector the two at the intersection (6) inserted switch pieces (6₁ and 6₂).

Images