EP0093680A1 - Cable car with two carrier and traction cables - Google Patents

Abstract

1. Overhead cable transport installation, namely a gondola lift with gondolas (24) coupled in line to two parallel continuous motion suspension/haulage cables (10, 12), by means of a suspension bar (46) hanging in the vertical plane equidistant of the two cables and articulated on a carriage (48) fitted with at least one pair of detachable grips (50-56) intended to connect the carriage (48) to the two cables in line and to disconnect the gondola (24) inside the terminals by detachment of the grips (50-56), so as to allow for embarkation and desembarkation of the passengers at null or reduced speed, characterized by the fact that every grip (50-56) has a body (63) that rests on the upper face of the cable (10, 12) in closed position of the grip and protrudes slightly upwards, and a pair of jaws (60, 62) protruding downwards from said body (63) and opening in downwards direction to clamp the sides of the cable, the end of the jaws coming level with, or protruding slightly lower than the lower face of the cable, in order to facilitate passing over or under the cable support rollers (42), and that inside the terminals (14, 15) guide rollers (92) deviate said cables so as to modify their clearance to each other and so to allow for passage of the carriage (48) disconnected from the cables from a position above the cable towards a lower position, or inversely.

Description

The invention relates to an overhead cable transport installation, in particular a gondola lift having vehicles coupled in line to two parallel carrier-tractor cables with continuous travel by a hanger extending in the vertical plane of symmetry of the cables and articulated at a carriage carrying at least one pair of disengageable clamps for securing the carriage to the two cables in line and for uncoupling the vehicle in stations by disengaging the clamps for boarding and / or disembarking at reduced or zero speed of passengers.

A gondola of the kind mentioned has many advantages, in particular simplicity, high throughput and ease of embarkation and disembarkation of passengers.

The suspension is arranged in the vertical plane of symmetry of the two cables and the support on two cables gives great lateral stability, the lateral forces exerted on the vehicles, in particular by the wind, being transmitted to the cables.

A known gondola (FR-A-1,249,949) comprises clamps gripping the cable from below, the jaws of the clamp ensuring the double function of supporting the weight of the cabin and immobilizing the latter on the cable.

The reliability of such pliers is not absolute, because the weight tends to open the jaws of the pliers. The size of the clamp, in particular the projection below and above the cable, prevents the passage of the clamps on the support rollers and under compression rollers and it is necessary to provide guides separating the cable from the rollers at passage of the clamp, which is practically impracticable in large installations with high voltage cable.

The object of the present invention is to remedy these drawbacks nients and allow the realization of an installation with two carrying cables-tractors retaining the advantages of simplicity of single cable gondolas.

The installation according to the invention is characterized in that each clamp comprises a clamp body bearing in the engaged position of the clamp on the upper face of the cable and having a slight upward projection and a pair of jaws projecting from said body by being open downwards to grip the cable laterally, the end of the jaws flush or slightly protruding from the underside of the cable to facilitate passage over and under the cable support rollers, and that in the guide roller stations deflects said cables to modify their spacing and allow disengagement of the uncoupled cable carriage.

By keeping the conventional clamps resting on the upper face of the cables, the problem of the passage of the rollers and the operational safety are resolved, but after opening the clamps in the stations the carriage remains trapped between the cables. According to the invention, cable guide rollers modify the spacing of the latter to allow the carriage to be released and the carriage to circulate on transfer rails independent of the path of the cables.

The distance between the cables results from a compromise between the need to keep the dimensions of the support structures within acceptable and manageable limits and, on the other hand, to have sufficient space between the cables to accommodate the horizontal guide rollers. in stations and to provide lateral stability. The difference is advantageously between 25 and 100 cm, preferably close to 75 cm. The diameter of the cables is within the range of 0.035 to 0.050 m and preferably close to 0.042 m.

To fully benefit from the lateral stability conferred rée by the double support of the carriage, the vehicle is fixed by its suspension to the carriage with a single degree of freedom corresponding to an oscillation in the vertical plane of symmetry.

According to a development of the invention, the carriage carries two pairs of disengageable clamps, two clamps for each cable, and these clamps can be offset with respect to each other in the direction of movement of the carriage or be arranged face to face two by two with a certain overlap, for example a coaxial arrangement of the springs. The two clamps coupled to the same cable are arranged symmetrically on either side of the transverse axis of symmetry of the carriage passing through the resulting points of coupling to the cables. The command to open and close the clamps at the entrance and exit of the stations can be common to all the clamps of the carriage, but it is preferable, for reasons of safety and standardization, to provide a lever individual control to each clamp, coming into the declutching and / or clutch zone in contact with a rail or a fixed cam in the usual manner. The control is then symmetrical with respect to the vertical plane of symmetry of the cables so as not to generate efforts to unbalance the carriage during the operation of the levers. Another control method is conceivable. Each clamp is advantageously mounted on the carriage by means of an elastic damping block allowing a slight rotation of one clamp relative to the other on the same cable and of the clamps of one of the cables relative to those of the other cable to prevent warping of the carriage.

The four clamps constitute a rigid quadrilateral connecting the two cables, which must move in synchronism. They have the same height of material symmetrically to pass under trains of parallel rollers without exerting asymmetrical forces tending to deform or warp the carriage.

Likewise the drive and / or braking systems of vehicles at entry, exit or at stations are double and symmetrical.

According to an important characteristic of the present invention, the two cable loops have a perfect symmetry of friction, that is to say that the resistances to the driving of the two cables are identical, this being achieved by symmetrical paths and / or brake regulating devices on one of the cables.

In the drive station each cable passes over an end pulley, the two pulleys being identical and superimposed. The two pulleys are driven by a differential system exerting the same tensile force on the two cables. This differential can be mechanical, hydraulic or electric. The combined action of the differential, the equality of friction and the connection between the two cables by the rigid quadrilaterals constituted by the clamps of the vehicles achieves a synchronous drive by avoiding any integration of offsets and obliquing of the vehicles. It is clear that similar precautions are essential during braking of the pulleys and according to another development of the invention, the braking device necessarily binds the two pulleys. A simple way is to insert the rims of the two coaxial pulleys. and very close to each other, between the brake caliper, the jaws applying the rims against each other when tightening. The use of a single caliper ensures a distribution of the braking force on the two pulleys and at the same time a friction connection between these two pulleys avoiding any offset. A braking band having a certain elasticity can be added to the outer periphery of each pulley.

As regards the differential, it can advantageously be produced electrically by working at equal power for the two strictly identical motors. If this is the case by construction, the forces to be overcome are the same for the two cable loops, the speed of movement of the cables will be the same, whatever or the compared diameters of the two drive pulleys, since the compared power is the product of the effort to be overcome by the speed of movement.

To produce such an electrical differential, a DC power source is provided common to the two motors with identical electrical characteristics.

If the two cable loops have equal forces to overcome in line, if the mechanical yields of the machinery are equal and if the motors are identical, when the latter are supplied with the same direct current source, the voltages and current intensities will be the same in the two motor supply circuits which will work well at equal power.

If, by countering an external element changes - and in particular if there is an inequality of efforts to be overcome in line - the motors will work asymmetrically, voltage and / or intensity varying.

One of the essential interests of this electric differential system is therefore to point out - compared to the initial state which can therefore be slightly asymmetrical - any unequal functioning of one loop compared to the other.

Dials, provided with various thresholds with control functions, then make it possible at any time to know the state of a loop with respect to the other and to automatically stop the installation in the event of an adjustment exceeding a predetermined value. This signaling and this control loop therefore constitute a fundamental safety device.

In the tensioning station, each cable passes over a loose return pulley, the two pulleys being mounted on a tension rudder balancing the tension in the two pulleys, mechanical, hydraulic or electric spreader. The return pulleys are advantageously offset laterally with respect to the direction of the cables by a distance corresponding to the spacing of the two cables in the station. The longitudinal spacing of the two pulleys compensates for slight differences in length of the two cable loops.

In the stations, the carriages are uncoupled from the cables and supported by transfer rails passing in front of the landing and embarkation platforms. The carriages have four wheels rolling on the rails, either by gravity, or under the action of a motor device, for example a chain with cleats. The wheels are arranged in pairs face to face and roll in the rectilinear parts on two parallel rails. In the curves, only one rail remains, inside the bend, which facilitates switches.

According to a preferred embodiment of the invention, the carriage is interposed between the two cables, the clamps projecting laterally from either side towards the outside. After opening of the clamps and exit of the cables by a relative movement towards the top of the carriage with respect to the cables, the latter are deviated with spacing to release the jig for passage of the clamps and allow the carriage to be disengaged from the bottom. This release takes place at the entrance to the station when the carriage passes over a release section, a symmetrical system at the station exit ensuring the engagement and re-coupling of the carriage to the cables.

The capacity of the vehicles, in particular from 12 to 30 passengers, makes it possible to limit the number of vehicles in service and it is advantageous to be able to store the vehicles or at least a sufficient number of vehicles in normal service on the transfer rails, departure of a vehicle made on demand.

Each carrier-tractor cable passes at the level of a pylon on a pendulum which may include support rollers or compression rollers. The two identical pendulums are perfectly symmetrical and their main axes are rigorously face to face. The inverted U supports of these axes are for example centered face to face in the factory by the same boring machine. The inverted U-shaped support allows the carriage to pass freely between the pendulums. The limited spacing of the cables, in particular 75 cm, makes it possible to maintain sufficient rigidity with conventional structures. To maintain the perfect symmetry of the two pendulums, the elements of the latter are connected together by inverted U's arranged at the entrance to each element, the entrance being defined relative to the direction of travel of the cables.

The inventive arrangement without lateral swinging of the passage of the pylons, allows the use of support rollers whose flanges inside the track are of an enlarged diameter to produce a very effective anti-derailleur device.

According to an alternative embodiment, the clamps are oriented inward, the U-shaped carriage framing the two cables. The size of the carriage is increased, but the support brackets of the pendulums are simplified and are limited to a simple cross member carrying at each of its ends a pendulum. Disengaging the carriage requires pinching the two cables.

• - la figure 1 est une vue schématique transversale d'un pylône d'une télécabine selon l'invention;
• - la figure 2 est une vue de côté du pylône selon la figure 1;
• - la figure 3 est une vue à échelle agrandie du chariot selon la figure 1;
• - la figure 4 est une vue en plan du chariot;
• - les figures 5 et 6 sont des coupes à échelle agrandie respectivement de la pince gauche et de la pince droite du chariot;
• - la figure 7 est une vue en plan d'une variante de réalisation du chariot;
• - la figure 8 est une coupe suivant la ligne brisée VIII-VIII de la figure 7;
• - les figures 9 et 10 sont des coupes suivant la ligne IX-IX de la figure 7, montrant la pince respectivement en position fermé et ouvert;
• - les figures 11 et 12 sont des vues à échelle agrandie respectivement en élévation et en plan d'un balancier selon la figure 2 à huit galets de support;
• - la figure 13 est une coupe suivant la ligne XIII-XIII de la figure 11;
• - la figure 14 est une vue en élévation du dispositif d'entraînement des deux câbles;
• - la figure 15 est une vue schématique en plan de la station d'entraînement;
• les figures 16, et 17 montrent respectivement en plan et en élévation le dispositif de mise sous tension des câbles;
• - les figures 18 et 19 sont des vues schématiques respectivement en plan et en élévation de la station de mise sous tension;
• - les figures 20 à 23 montrent le chariot, équipé d'un autre type de pinces, aux différentes positions de la figure 18;
• - la figure 24 illustre une variante de réalisation du chariot et du support de balancier selon l'invention;
• - la figure 25 est une vue analogue à celle de la figure 13, illustrant une variante de réalisation à balanciers inclinables;
• - la figure 26. est une vue analogue à celle de la figure 14, montrant un dispositif d'entraînement à différentiel électrique.
• - la figure 27 montre une autre variante ;

Other advantages and characteristics will emerge more clearly from the description which follows of different embodiments of the invention, given by way of nonlimiting examples and represented in the appended drawings, in which:

• - Figure 1 is a schematic transverse view of a pylon of a gondola according to the invention;
• - Figure 2 is a side view of the pylon according to Figure 1;
• - Figure 3 is an enlarged view of the carriage according to Figure 1;
• - Figure 4 is a plan view of the carriage;
• - Figures 5 and 6 are sections on an enlarged scale respectively of the left clamp and the right clamp of the carriage;
• - Figure 7 is a plan view of an alternative embodiment of the carriage;
• - Figure 8 is a section along the broken line VIII-VIII of Figure 7;
• - Figures 9 and 10 are sections along the line IX-IX of Figure 7, showing the clamp respectively in the closed and open position;
• - Figures 11 and 12 are views on an enlarged scale respectively in elevation and in plan of a pendulum according to Figure 2 with eight support rollers;
• - Figure 13 is a section along the line XIII-XIII of Figure 11;
• - Figure 14 is an elevational view of the device for driving the two cables;
• - Figure 15 is a schematic plan view of the drive station;
• FIGS. 16 and 17 respectively show in plan and in elevation the device for tensioning the cables;
• - Figures 18 and 19 are schematic views respectively in plan and in elevation of the energizing station;
• - Figures 20 to 23 show the carriage, equipped with another type of clamps, in the different positions of Figure 18;
• - Figure 24 illustrates an alternative embodiment of the carriage and the pendulum support according to the invention;
• - Figure 25 is a view similar to that of Figure 13, illustrating an alternative embodiment with tilting pendulums;
• - Figure 26. is a view similar to that of Figure 14, showing an electric differential drive device.
• - Figure 27 shows another variant;

In the figures, two carrier cables 10, 12 of a gondola extend in a closed circuit between two stations 14, 15 passing through the stations on pulleys 16, 17; 18, 19 of vertical axis ends 20, 21; 22, 23. The end pulleys 16, 17 of the station 14 are drive pulleys driving the cables 10, 12 continuously at the same speed. The vehicles 24 are coupled to the cables 10, 12 in line, several vehicles 24 being able to follow one another or be staggered along the cables 10, 12. At the entrance to a station 14, 15, the vehicles 24 are uncoupled from the cables 10 , 12 and supported by rails transfer 26 passing in front of landing and loading docks. The passengers get on and off the vehicles 24 at a standstill or traveling at low speed and at the exit from the station the vehicles 24 are accelerated by any appropriate means before being re-coupled to the cables 10, 12 on the opposite lane. This operation of cable cars is well known to specialists.

The cables 10, 12 tractor-carriers are parallel and at the same level in line, their constant spacing being within the range of 0.25 to 1.00 m, preferably close to 75 cm. Each cable 10, 12 has a diameter in the range of 0.035 to 0.050 m, preferably close to 0.042 m. The cables 10, 12 are supported by support and support pylons of identical structure, only a support pylon being described below with reference to Figures 1 and 2. At each end of a span or bracket 30 is suspended a bracket U-shaped upturned respectively to support the cables 10, 12 of the uplink and the downlink. At the end of each branch of the stirrup 32 is fixed an axis 38, 40 of articulation of a pendulum 34, 36 carrying the rollers 42 for supporting the cables 10, 12. The spacing of the pendulums 34, 36 corresponds to that of the cables 10, 12 and the caliper assembly 32, pendulums 34, 36 is symmetrical relative to the vertical plane of symmetry of the cables 10, 12 of trace XX in FIG. 1. The axes 38, 40 are perfectly aligned, their supports having been centered face to face in the factory on the same boring machine. The pendulums 34, 36 struggle in parallel vertical planes and include a number of secondary pendulums suitable for the load. To preserve the perfect symmetry of the pendulums 34, 36 it is advantageous to connect the secondary axes, even tertiary, by stirrups 44 in inverted U imposing a symmetrical pivoting. In FIGS. 11 to 13, only the last elements of the pendulums 34, 36 are interconnected by stirrups 44, arranged at the entrance, relative to the direction of travel of the cable 10, 12 of the element. Cables 10, 12 pass on the rollers 42 of the support beams 34, 36, in the usual manner and it is easy to see that the interval between the cables 10, 12 is entirely cleared for the passage of vehicles 24. The cables 10, 12 obviously pass under the rollers of a holding balance (not shown). The flanges, interior with respect to the track, of the rollers 42 are enlarged to properly frame the cables 10, 12 and prevent any derailment.

Each vehicle 24 comprises a suspension 46 articulated at its upper part to a transverse axis 58 of a carriage 48 carrying four clamps 50, 52, 54, 56 for coupling to the cables 10, 12. The width of the body of the carriage 48 is slightly jnféricurc at the spacing between the cables 10, 12 while the jaws 60, 62 of the clamps 50 to 56 protrude from the two lateral sides of the carriage to grip the cables 10, 12. Figures 5 and 6 schematically show a clamp bearing on the cable and having a movable jaw 62 disposed respectively inside and outside. The jaws 60 _; 62 are biased in the closed position by a spring 64 and each clamp 50 to 56 comprises a control lever 66 cooperating in the stations with a cam or a rail extending along the trajectory of the carriage 48 to control the opening and closing the clamp. The clamps can be of a different type, in particular from those described below.

The clamps 50 to 56 can be offset in the longitudinal direction of the carriage for reasons of space, but it is clear that clamps of a different structure can be used and that the clamps 50, 54; 52, 56 facing each other can be aligned and nested. The springs can be coaxial and certain elements, in particular the control lever 66, can be common to several clamps. The control levers 66 are arranged face to face so that the operating forces are balanced and exert no transverse reaction on the carriage 48.

The jaws 60, 62 are shaped to pass over and under the rollers 42 without a noticeable jerk and the height of projection of the carriage 48 above the cables 10, 12 is reduced to the maximum to facilitate the release. In addition, in any plane perpendicular to the line, this projection height is equal from one cable to the other, so as to avoid any twisting of the carriage when passing under the compression pendulums. The carriage 48 carries four wheels 68 for moving on the rails 26 of the stations 14, the wheels 68 being arranged face to face. Elastic blocks (not shown) for fixing the clamps 50-56 allow a slight pivoting.

Another embodiment of the carriage 48 is illustrated in FIGS. 7 to 10, the four clamps 50, 52, 54, 56 being of the type described in French patent application No. 81 00432 of January 9, 1981. The movable jaw 62 is carried by the control lever 66; articulated on a clamp body 63 bearing on the cable. The lever 66 carries at the opposite end a control roller. The spring 64 attacks said opposite end to urge the clamp in the cable clamping position 10. The clamps 54, 56, associated with the cable 12 are arranged symmetrically on either side of the transverse axis YY of the carriage 48 while the clamps 50, 52, also symmetrical, frame the clamps 54, 56. The fictitious coupling points of the clamps 54, 56; 50, 52 to the cables 10, 12 are thus located on the YY axis, avoiding an asymmetry in driving the carriage 48. The operation of the clamps is obvious and the reader can refer to the aforementioned patent application for more details . In stations, the wheels 68 roll on two parallel rails 26, one of the rails being advantageously removed in the curves, which. facilitates referrals. The carriage 48 carries two friction plates 70 capable of cooperating with drive wheels 72 in the stations (fig. 20). This training is perfectly symmetrical.

The suspension 46. is straight in the plane of symmetry of the cables 10, 12 and the only authorized movement, relative to the carriage 48, is a pivoting on the axis 58 resulting in by a movement in said plane of symmetry. It is understood that the suspension 46 is always perpendicular to the axis 58, that is to say to the level line of the two cables 10, 12. Like the cables 10, 12 are necessarily at the same level in line with the pendulums 34 , 36 the suspension 46: is vertical and the stability of the vehicles 24 when the towers pass is remarkable. The return torque exerted on the cabin 24 at the entry of the pendulums 34, 36 is proportional to the spacing of the cables 10, 12 and it is advantageous to separate the cables 10, 12 as much as possible. A large gap also allows the housing of the carriage 48 between the cables 10, 12 and the deflection of the cables 10, 12 in the stations 14 by rollers with a vertical axis as described below. Conversely, the support structures, in particular the stirrups 32, 44, quickly become too large and a spacing distance of 75 cm is a valid compromise. The suspension with two cables 10, 12 of large section provides increased security and the vehicles 24 can be relatively large, for example for transporting several tens of passengers.

The cables 10, 12 form two endless loops extending between the drive 14 and tensioning stations 15. The drive pulleys 16, 17 of the station 14 are superimposed and coaxial, the spacing between the two pulleys 16., 17 being very weak. The drive pulleys 16, 17 are advantageously each provided with a braking track 71, 73 extending the inner flange of the pulley and of less inertia than the pulley. A brake caliper 74 encloses the two tracks 71, 73 so that one 76 of the brake pads engages the free face of one of the tracks and the other 78 of. skates engage the free face of the other track. The brake is for example of the hydraulic type imposing a bringing together of the pads 76, 78 which are applied to the tracks 71, 73 with the same force, the caliper 74 being mounted floating. During braking, the tracks 71, 73 are applied to one another, so as to secure the pulleys 16, 17.

The axes 20, 21 of the pulleys 16, 17 are connected by transmissions 80, 82 to the planet gears 84, 86 of a differential mechanism 88 whose pinions 90 are driven by a motor 92. This differential mechanism can be hydraulic or electric, the result being an equal force drive of the two cables 10, 12 and a permanent rebalancing of these forces.

With particular reference to FIG. 15, it can be seen that the cables 10,12 pass over guide rollers 92 at the entry and exit of the pulleys 16,17 to define the two strands of each track, the spacing of the cables 10, 12 being slightly increased on sections, before and after the pulleys for the reasons described below. The arrangement of the cables 10, 12 is symmetrical, the cable 10 inside the track before the pulley being outside at the outlet and vice versa, the two loops thus passing over the same number of guide rollers 92 and undergoing the same braking or the same running resistance.

With particular reference to Figs. 16 to 19, it can be seen that the cables 10, 12 pass through the tensioning station 15 on idler idler pulleys 18, 19 which are identical, but laterally offset by a distance corresponding to the spacing of the cables. The pulleys 18.19 are mounted on sliders 94.95 movable in the general direction of the line and biased by jacks 96.9T in the direction of tensioning of the cables 10.12. The cylinders 96, 97 are strictly identical and supplied by the same pressure source 98, so as to provide equal tensions to the cables 10, 12, while compensating for slight differences in length of the cable loops 10, 12. The cylinders 96, 97 constitute a lifting beam which can be mechanical. The cylinders 96, 97 can be replaced by two counterweights or any other similar device. The on-line operation of the cable car speaks for itself and only the passage through station 15 is described below with reference to FIGS. 18 to 23, the passage through station 14 being identical. Assuming that the cables 10, 12 run synchronously in the direction indicated by the = arrow in FIGS. 18, 19, the lower channel in FIG. 18 constitutes the entry channel, that is to say that is to say the uncoupling and disengagement path of the vehicle 24 from the cables 10, 12 and the upper path the output path, in this case engagement and re-coupling of the vehicle 24 to the cables 10, 12.

When the vehicle 24 enters the station 15, the wheels 68 of the carriage 48 roll on the rails 26 shown in phantom, and the levers 66 control the opening of all the clamps 50 to 56 in the usual manner (position A, fig . 20). The rails 26 subsequently slightly deviate the carriage 48 upwards with respect to the cables 10, 12 to release the clamps 50 to 56 from the cables 10, 12 (position B, fig. 21). Downstream of position B, seen in the running direction of the cables 10, 12, the latter pass over guide rollers 92 with a vertical axis to diverge and reach a spacing greater than the total width of the carriage 48, the jaws 60, 62 being in the open position. In this zone the trajectory of the rails 26 is lowered with respect to the cables 10, 12, which pass under guide rollers 100 with a horizontal axis to release the carriage 48 downwards (position D, fig. 22 and position C, fig . 23), the carriage 48 passing under the end pulleys 18, 19. The slowing down of the vehicle 24 can be engaged as soon as the clamps 50 to 56 are opened. The outlet from the station 15 is arranged in a symmetrical manner for the coupling of vehicles 24 to the cables according to the reverse sequences: passage of the carriage 48 under the pulleys 18, 19, insertion of the carriage between the cables 10, 12, bringing the cables together, forcing the jaws on the cables with synchronization of the speed of the carriage with that of the cables, and closing of the clamps. The symmetry of the two cable loops 10, 12 is preserved.

The vehicles 24 disengaged from the cables run in the station on the usual transfer and possibly storage channels, allowing disembarkation and embarkation of passengers at a standstill or at reduced speed of circulation.

At the outlet, the vehicles 24 are re-coupled to the cables 10, 12 in the aforementioned manner. The layout of the other end station 14 is identical and need not be described. It can be noted that all of these operations can be easily automated as in conventional gondolas and that they are carried out without stopping the vehicle by requiring only conventional devices whose efficiency and reliability have been proven.

The large capacity of the vehicles makes it possible to limit the number of vehicles in line while ensuring a significant throughput and it is possible to store the vehicles 24 on the transfer rails 26 of the stations while ensuring a departure on demand. This avoids empty operation and unnecessary wear.

FIG. 24 illustrates an alternative embodiment of the invention in which the line 46 of the vehicles 24 is articulated to a carriage 102, the U-shaped frame 104 of which externally frames the two cables 10, 12. The clamps 50-56, carried by the frame 104, are oriented inward towards the cables 10, 12 enclosed by the jaws 62 facing each other. The pylons are arranged accordingly for a free passage of the carriage 102, by mounting the rockers with support rollers 42 at the two ends of a crosspiece 106 extending transversely between the two cables 10, 12. This reverse arrangement does not modify the operation of the installation, but requires pinching of the cables 10, 12 in the stations for clearing or engaging the carriage 104. The arrangement of the carriage 104 is more complicated and more bulky, that of the pylons being on the other hand simpler .

It is clear that the invention is applicable to installations having a different number of clamps or clamps of a different structure.

Fig. 25 shows a preferred embodiment of the cable support pendulums 10, 12. Each pendulum with support rollers 42 is carried by the end of an arm 108, 110 articulated at 112, 114 to the bracket 30 to allow movement in the plane transverse to the cables 10, 12. A spacer 116 connects the arms 108, 110 to constitute a deformable quadrilateral maintaining the rollers 42 parallel and at constant spacing whatever the travel of the arms 108, 110.

The drive of the pulleys 16, 17 may include an electrical differential shown diagrammatically in FIG. 26. Each pulley 16, 17 is driven by an electric motor 118, 120, which is perfectly identical. The two motors 118, 120 are connected by supply lines 122, 124 to the same source of electrical power 126. Measuring devices 128 inserted in the lines 122, 124 permanently signal the intensity and the voltage of the current d power to each motor 118, 120. The two cable loops being symmetrical, the powers supplied by the motors 118, 120 are identical and the currents and voltages are the same. There is of course always a slight asymmetry which results in a difference in the intensities and / or voltages, but this difference in measurement can be identified or compensated for. In normal operation, the two cables are driven at the same speed and the measurement difference remains constant. An incident, for example an increase in the resistance to advancement of one of the cables is automatically signaled by a variation of said measurement difference and depending on the magnitude of this variation, the fault is simply signaled or causes the stop of the installation.

FIG. 27 illustrates a real embodiment in which the two clamps 50.54, respectively 52.56 are superimposed, the cables 10.12 being slightly offset in height. This offset may correspond to that of the end pulleys in the stations.

Claims (14)

1. Overhead cable transport installation, in particular a gondola lift having vehicles (24) coupled in line to two parallel carrier-tractor cables (10,12) with continuous travel by a hanger (46) extending in the vertical plane of cable symmetry and articulated to a carriage (48) carrying at least one pair of disengageable clamps (50 - 56) for securing the carriage (48) to the two cables in line and for uncoupling the vehicle (24) in stations by disengaging the clamps (50-56) for boarding and / or disembarking at reduced or zero speed of passengers, characterized in that each clamp (50-56) comprises a clamp body (63) bearing in the engaged position of the clamp on the upper face of the cable (10,12) and having a small upward projection and a pair of jaws (60,62) projecting from said body (63) being open downward, for laterally enclosing the cable, the end jaws flush with or slightly protruding from the underside of the cable to facilitate passage over and under the rollers (42) for supporting the cables and in the stations (14,15) of the guide rollers (92) deflect the said cables to modify their spacing and allow the carriage (48) to be released uncoupled cables. 2. Installation according to claim 1, characterized in that each carriage (48) comprises two pairs of clamps (50-56) to form in the coupled position a rigid quadrilateral connecting between the two cables (10,12) imposing a synchronous movement Cables. 3. Installation according to claim 2, characterized in that said clamps (50-56) are nested, the two clamps (50.52; 54.56) coupled to the same cable (10,12) being arranged symmetrically on one side and on the other side of the transverse axis of symmetry of the carriage (48) passing through the resulting points of coupling to the cables. 4. Installation according to claim 3, characterized in that said small upward projection of the clamps (50-56) is symmetrical to avoid any asymmetry in the passage of the clamps under compression rollers. 5. Installation according to any one of the preceding claims, characterized in that the two cables (10,12) form two endless loops having perfect symmetry of friction, tension, setting in motion and therefore trajectory and speed . 6. Installation according to claim 5, characterized in that each cable (10,12) passes in the drive station (14) on a drive pulley (16,17), the two drive pulleys being connected by a system differential (88) rebalancing at all times the traction forces and the speeds of movement of the two cables. 7. Installation according to claim 6, characterized in that said differential system comprises a source (126) of electric current supplying two identical electric motors (118, 120), each motor driving one of the cables (10, 12, J and measuring devices (128) for detecting any difference in supply of the two motors and any variation of this difference reflecting an incident on one of the cables. 8. Installation according to claim 6, or 7, characterized in that the two drive pulleys (16,17) are superimposed at small spacing to allow free relative rotation and that a braking device (74) cooperates with said two pulleys to secure the latter in rotation during braking. 9. Installation according to claim 5, characterized in that each cable (10,12) passes through the tensioning station (15) on a mad idler pulley (18,19), the two idler pulleys being mounted on a spreader, so that at all times the tension is the same two by two in the four strands of cable. 10. Installation according to any one of the preceding claims, characterized in that each pylon (28) comprises two symmetrical pendulums (34, 36), each associated with one of said cables (10, 12) and that elements of the two pendulums are mechanically connected (44) so as to ensure a symmetrical pivoting of said elements, and a constant spacing corresponding to the spacing of the clamps (50-56) of the carriages. 11. Installation according to any one of the preceding claims, characterized in that the clamps (50, 56) project laterally on either side of the carriage (48) interposed between the two cables (10, 12), said cables being supported in line by pendulums (34,36.) carried by stirrups (32) in inverted U integral with the pylons and said cables being deviated with spacing in the stations for a downward clearance of the carriage uncoupled from the cables. 12. Installation according to any one of the preceding claims, characterized in that each pylon (28) comprises two symmetrical pendulums (34,36), each associated with one of said cables (10, 12) and fixed to one sides (108, 110) of an articulated parallelogram allowing a symmetrical lateral movement with respect to the longitudinal direction of the cables (10, 12). 13. Installation according to claim 1, characterized in that the two cables (10, 12) are carried by pendulums attached to the ends of a crosspiece (106) suspended from a pylon, the clamps (50-56;) carried by the carriage framing the two cables from the outside. 14. Installation according to any one of the preceding claims, characterized in that the clamps (50,52) coupled to one (10) of the cables are superimposed on the clamps (54,56) coupled to the other (12) of the cables , the two cables (10,12) being offset in height.

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