INSTALLATION AND METHOD OF TRANSPORT BY OVERHEAD CABLE

Abstract

Installation of transport by overhead cable including at least one chair configured to be suspended on the overhead cable and including a pivoting seat surface, a back rest and a pivoting mechanism to modify the inclination of the seat surface with respect to the back rest, the installation including an actuator configured to cooperate with the pivoting mechanism so as to control pivoting of the seat surface, the actuator being mounted movable between a raised position in which the actuator controls raising of the seat surface in the direction of the back rest and a lowered position in which the actuator controls lowering of the seat surface.

Claims

1. An installation of transport by overhead cable, comprising: at least one chair configured to be suspended on the overhead cable and comprising a pivoting seat surface, a back rest and a pivoting mechanism to modify the inclination of the seat surface with respect to the back rest, at least one actuator configured to cooperate with the pivoting mechanism so as to control pivoting of the seat surface, wherein said at least one actuator is mounted movable between a raised position in which said at least one actuator controls raising of the seat surface in the direction of the back rest and a lowered position in which said at least one actuator controls lowering of the seat surface.

2. The installation according to claim 1, wherein the pivoting mechanism comprises a transmission element connected to the seat surface and mounted movable between a first position in which the transmission element raises the seat surface in the direction of the back rest, and a second position in which the transmission element lowers the seat surface.

3. The installation according to claim 2, wherein the pivoting mechanism comprises a transmission cable connecting the transmission element with the seat surface.

4. The installation according to claim 2, wherein the pivoting mechanism comprises a motor connecting the transmission element with the seat surface.

5. The installation according to claim 2, wherein said at least one actuator comprises a cam provided with two surfaces of opposite inclinations so that in the raised position a first surface moves the transmission element to the first position, and in the lowered position a second surface moves the transmission element to the second position, the cam being mounted movable in translation between the raised position and the lowered position.

6. The installation according to claim 2, wherein said at least one actuator comprises a rail provided with two opposite slopes so that in the raised position a first slope moves the transmission element to the first position, and in the lowered position a second slope moves the transmission element to the second position, the rail being movable in rotation between the raised position and the lowered position.

7. The installation according to claim 1, comprising a first terminal for disembarking the passengers comprising a first actuator located in an exit region of the chairs of the first terminal and occupying a raised position, and a second terminal for embarking the passengers comprising a second actuator located in an entry region of the chairs into the second terminal and occupying a lowered position.

8. A method of transport by overhead cable, comprising: providing an installation having at least one chair configured to be suspended on the overhead cable and comprising a pivoting seat surface and a back rest, using of at least one actuator mounted movable to occupy a raised position in which said at least one actuator controls raising of the seat surface in the direction of the back rest and to occupy a lowered position in which said at least one actuator controls lowering of the seat surface.

9. The method according to claim 8, wherein the installation comprises a first terminal for disembarking the passengers provided with an exit region of the chairs from the first terminal and with a first actuator, and a second terminal for embarking the passengers provided with an entry region of the chairs to the second terminal and with a second actuator, wherein: the first actuator raises the seat surface in the direction of the back rest when said at least one chair is running in the exit region, and the second actuator lowers the seat surface when said at least one chair is running in the entry region.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] Other advantages and features will become more clearly apparent from the following description of particular embodiments and implementation modes of the invention given for non-restrictive example purposes only, and represented in the appended drawings, in which:

[0022] FIG. 1 schematically illustrates a perspective side view of an embodiment of a cable transport installation according to the invention where the operating means is in the lowered position; and

[0023] FIG. 2 schematically illustrates a perspective side view of an embodiment of a cable transport installation according to the invention where the operating means is in the raised position;

[0024] FIGS. 3 and 4 schematically illustrate an embodiment of the operating means respectively occupying a raised position and a lowered position;

[0025] FIGS. 5 and 6 schematically illustrate another embodiment of the operating means respectively occupying a raised position and a lowered position; and

[0026] FIGS. 7 to 10 schematically illustrate other embodiments of the cable transport installation.

DETAILED DESCRIPTION

[0027] In FIG. 1, an embodiment of a transport installation 1 by overhead cable 2 has been represented. The installation 1 comprises at least one chair 3 configured to be suspended and hauled by the cable 2 in order to transport passengers. The installation 1 is also called chair lift. The chair lift 1 generally comprises several chairs 3, and the cable 2 is an overhead cable, i.e. the chairs 3 are suspended above the ground. A single chair 3 has been represented in FIGS. 1 and 2 for reasons of simplification. Furthermore, the cable 2 is preferably both a hauling and a carrier cable. The installation 1 generally comprises a terminal 4 for embarking and a terminal 40, as illustrated in FIG. 7, for disembarking the passengers. At least one chair 3, and preferably each chair 3, comprises at least one seat surface 5, several seat surfaces 5 situated next to one another, designed to seat a passenger. In general manner, a chair 3 comprises as many back rests 6 as seat surfaces 5, and a chair structure 7 on which the back rests 6 and seat surfaces 5 are mounted. The chair 3 comprises a hoop guard 8 mounted pivoting on the chair structure 7 for protection of the passengers seated on the chair 3. Each chair 3 further comprises a clamp 9 to suspend it on the cable 2. The clamps 9 can be fixed, and in this case the chairs 3 are suspended in permanent manner onto the cable 2. Preferentially, the clamps 9 are detachable, and in this case the chairs 3 are attached in removable manner to the cable 2.

[0028] A chair 3 further comprises at least one seat surface 5 mounted pivoting on the chair structure 7 between a raised position R, as illustrated in FIG. 1, in which the seat surface 5 is situated against the back rest 6, and a lowered position A, as illustrated in FIG. 2, in which the seat surface 5 is away from the back rest 6 and enables a passenger to sit on the seat surface 5. Preferentially, all the seat surfaces 5 of a chair 3 are mounted pivoting. For example, all the chairs 3 of the installation 1 each have their seat surfaces 5 mounted pivoting. Furthermore, each chair 3 comprises a pivoting mechanism 10 configured to modify the inclination of at least one seat surface 5 with respect to the back rest 6, and more particularly the inclination of all the seat surfaces 5 of the chair 3. More particularly, the pivoting mechanism 10 comprises a transmission element 11 connected to the pivoting seat surface 5. The transmission element 11 is further mounted movable on the chair structure 7 between a first position P in which the transmission element 11 raises the seat surface 5 in the direction of the back rest 6, and a second position Q in which the transmission element 11 lowers the seat surface 5. What is meant here by raises is the fact that the seat surface 5 is directed upwards, in particular towards the back rest 6, until it is in contact with the back rest 6 or leaves a narrow space between the back rest 6 and the seat surface 5 so as to reduce the volume comprised between the seat surface 5 and the back rest 6 to limit build-up of snow on the seat surface 5. More particularly, in the raised position R of the seat surface 5, the distance separating the back rest 6 from a front edge of the seat surface 5 is less than half the length of the seat surface 5. In other words, in the raised position R, a passenger cannot sit on the seat surface 5. On the contrary, what is meant by lowers is the fact that the seat surface 5 is directed downwards, in other words the seat surface 5 is located away from the back rest 6 to again occupy its initial position, called normal operating position.

[0029] For example, the transmission element 11 is mounted rotating on the structure 7 around an axis X perpendicular to the direction Y of movement of the chair 3. The transmission element 11 can be a sheave mounted fixed, or movable, on an arm mounted movable on the chair structure 7. In general manner, the pivoting seat surface 5 is mounted on the chair structure 7 by a pivot link 13. For example, the seat surface 5 comprises a pivoting shaft mounted rotating around an axis perpendicular to the direction Y. Pivoting of the seat surface 5 can be achieved in different manners. For example, the pivoting mechanism 10 comprises a drive system, not represented for the sake of simplification, which causes pivoting of the seat surface 5 with respect to the back rest 6 according to the position of the transmission element 11. The drive system can comprise a gear system formed by a set of cog-wheels. As a variant, the drive system comprises a set of smooth wheels and belts, or a combination of smooth wheels and cog-wheels. In particular, the drive system is connected to the pivoting shaft to pivot the seat surface 5. The transmission element 11 can be connected to the drive system by means of an arm 11a mounted rotating around the axis X, as illustrated in FIGS. 8 and 9. In this case, the transmission element 11 is situated at the level of the seat surface 5 to reduce the overall dimensions of the chair 3. As a variant, the pivoting mechanism 10 comprises a transmission cable 12 connecting the transmission element 11 with the pivoting seat surface 5. In particular, the transmission cable 12 is connected to the drive system described above. In this case, the transmission element 11 can be located away from the seat surface 5. In general manner, the transmission cable 12 is flexible. As a variant, the transmission cable 12 can be replaced by several rods articulated on one another. The transmission cable 12 enables the drive system to be actuated to cause raising and/or lowering of the seat surface 5. In general manner, the pivoting mechanism 10 is reversible. According to yet another embodiment, illustrated in FIG. 10, the pivoting mechanism 10 comprises a motor M connecting the transmission element 11 with the seat surface 5. The motor M is configured to animate the pivoting shaft in rotation to pivot the seat surface 5 according to the position of the transmission element 11.

[0030] In FIG. 1, the seat surface 5 has been represented by a broken line in a lowered initial position and by an unbroken line in a raised position R. In opposite manner, in FIG. 2, the seat surface 5 has been represented by a broken line in the raised position and by an unbroken line in the initial lowered position A. The seat surface 5 pivots from one position to the other, and vice versa, by means of the pivoting mechanism 10.

[0031] The installation 1 comprises at least one operating means 14, 44, such an actuator, configured to cooperate with the pivoting mechanism 10 so as to control pivoting of the seat surface 5. For example, the installation 1 can comprise a single operating means 14 situated in one of the terminals 4, 40. The operating means 14 may be situated outside the terminals, for example it can be mounted on a pillar located near a terminal 4. As a variant, as illustrated in FIG. 7, each terminal 4, 40 comprises an operating means 14, 44. In particular, the operating means 14 is mounted movable between a raised position R1, as illustrated by an unbroken line in FIGS. 2, 3 and 5, and a lowered position A1, as illustrated by an unbroken line in FIGS. 1, 4 and 6. In the raised position R1, illustrated in FIG. 2, the operating means 14 is configured to control raising of the seat surface 5 in the direction of the back rest 6. More particularly, in the raised position R1, the operating means 14 cooperates with the pivoting mechanism 10 when the chair passes in front of the operating means 14. In other words, when the chair 3 passes in front of the operating means 14, the transmission element 11 comes into contact with the operating means 14 and the latter moves the transmission element 11 to the first position P. The change of position of the transmission element 11 controls pivoting of the seat surface 5. When the pivoting mechanism 10 comprises a transmission cable 12, the transmission element 11 exerts a first tension on the transmission cable 12, which makes the seat surface 5 pivot to the raised position R. When the pivoting mechanism 10 comprises a motor M, the transmission element 11 controls the motor M to animate the pivoting shaft in a first direction of rotation, which makes the seat surface 5 rotate to the raised position R. All the seat surfaces 5 of the chairs 3 of the installation can thus be raised by positioning the operating means 14 in the raised position R1.

[0032] The operating means 14 is further configured to occupy a lowered position A1 in which the operating means 14 controls lowering of the seat surface 5. In the lowered position A1, illustrated in FIG. 1, the operating means 14 cooperates with the pivoting mechanism 10 when the chair 3 passes in front of the operating means 14. In other words, when the chair 3 passes in front of the operating means 14, the transmission element 11 comes into contact with the operating means 14 and the latter moves the transmission element 11 to the second position Q. The change of position of the transmission element 11 makes the seat surface 5 pivot to the lowered position A. When the pivoting mechanism 10 comprises a transmission cable 12, the transmission element 11 exerts a second tension, opposite to the first tension, on the transmission cable 12, which makes the seat surface 5 pivot to the lowered position A. When the pivoting mechanism 10 comprises a motor M, the transmission element 11 controls the motor M to animate the pivoting shaft in a second direction of rotation, opposite to the first direction of rotation, which makes the seat surface 5 pivot to the lowered position A. All the seat surfaces 5 of the chairs 3 can thus be lowered to replace the seat surfaces 5 in the normal operating condition. In general manner, the position of the operating means 14 can be modified by a lever actuating a mechanical system or by means of an actuator controlling an electric, pneumatic or hydraulic motor.

[0033] After the seat surface 5 of a chair 3 has been lowered, the operating means 14 which remains in their lowered position A1 no longer cooperates with the pivoting mechanism 10 of the chair 3 when the chair 3 passes in front of the operating means 14 again. In this case, the seat surface 5 keeps its lowered position A and no longer pivots. The installation 1 can thus be operated under normal conditions to allow embarking on and/or disembarking of the passengers from the chairs 3.

[0034] An embodiment of the operating means 14 has been represented in FIGS. 3 and 4. In this embodiment, the operating means 14 comprises a rail 20 provided with a first slope 21 located on a first surface of the rail 20, and with a second slope 22, called opposite slope, located on a second surface of the rail 20 opposite the first surface. The rail 20 is mounted movable in rotation around a main axis 23, between the raised position R1, illustrated in FIG. 3 and the lowered position A1, illustrated in FIG. 4. Under normal operating conditions of the installation, the operating means 14 is in the lowered position A1 and the seat surfaces 5 pivot to their lowered position A, or remain in their lowered position A if they have been previously lowered. When the seat surfaces 5 of the chairs 3 are to be raised, the operating means 14 is placed in the raised position R1 in which the first slope 21 cooperates with the transmission element 11 to move the latter to the first position P. Indeed, as illustrated in FIG. 3, the chairs 3 move in the running direction Y and, for each chair of the installation 1, the transmission element 11 translates in a direction Z1 perpendicular to the direction Y in contact with the first slope 21 of the rail 20. On the contrary, the operating means 14 is positioned in the lowered position A1 to lower the seat surfaces 5 of the chairs 3. In this case, the transmission element 11 comes into contact with the second slope 22 of the rail 20, when the chair 3 is running in the direction Y, and it follows the second slope 22, translating in the direction Z2 until it occupies the second position Q. The position A1, R1 of the rail 20 modifies the position P, Q of the transmission element 11 to make the seat surfaces pivot to the desired position A, R. The position A1, R1 of the rail 20 is modified by performing a rotation of the rail 20 around the main axis 23.

[0035] Another embodiment of the operating means 14 has been represented in FIGS. 5 and 6. In this embodiment, the operating means 14 comprises a cam 30 provided with a first surface 31 and a second surface 32 located opposite the first surface 31 and inclined with respect to the latter. The cam 30 is mounted movable between the raised position R1 and the lowered position A1. More particularly, the cam 30 is movable in translation along an axis Z3 perpendicular to the running direction Y of the chairs 3. In the raised position R1, the cam 30 presents the first surface 31 to move the translation part 11 to the first position P. In the raised position R1, the transmission element 11 comes into contact with the first surface 31 to be translated in the direction Z1. In the lowered position A1, the cam 30 presents the second surface 32 to move the translation part 11 to the second position Q. In the lowered position A1, the transmission element 11 comes into contact with the second surface 32 to be translated in the direction Z2. The position A1, R1 of the cam 30 is modified by moving it by translation along the axis Z3.

[0036] In FIG. 7, an embodiment has been represented in which each terminal 4, 40 comprises an operating means 14, 44. In this embodiment, the installation 1 comprises a first terminal 40 designed for disembarking the passengers and a second terminal 4 designed for embarking the passengers on the chairs 3. The first terminal 40 comprises an exit region M1 of the chairs 3, and a first operating means 44 located in the exit region M1 and occupying a raised position R1. In this case, when the chairs 3 are in the first terminal 40, before the exit region M1, the seat surfaces 5 are lowered and the passengers can disembark. Then, when the chairs 3 leave the first terminal 40, they pass in front of the first operating means 44 and their seat surfaces 5 are raised as the first operating means 44 is in the raised position R1. The chairs 3 which are not transporting passengers and which are directed to the second embarking terminal 4 are in this way protected from build-up of snow when running from the first terminal 40 to the second terminal 4. In particular, the first operating means 44 can be located at the entry or at the exit of the exit region M1, and it can also be located between the entry and the exit of the exit region M1. Furthermore, the second terminal 4 comprises an entry region M2 of the chairs 3, and a second operating means 14 located in the entry region M2 and occupying a lowered position A1. In this case, when the chairs 3 are located before the entry region M2, the seat surfaces 5 are raised. Then, when the chairs 3 enter the second terminal 4, they pass in front of the second operating means 14 and their seat surfaces 5 are lowered as the second operating means 14 is in the lowered position A1. The passengers can therefore embark on the chairs 3. In particular, the second operating means 14 can be located at the entry or at the exit of the entry region M2, and it can also be located between the entry and the exit of the entry region M2.

[0037] An overhead cable transport method can be implemented by the installation 1 which has just been described in the foregoing. In this method, the seat surface 5 is raised in the direction of the back rest 6 when the chairs 3 are running in the exit region M1 and the seat surface 5 is lowered when the chairs 3 are running in the entry region M2. Raising of the seat surfaces 5 is performed by moving the first operating means 44 to the raised position R1 and lowering is performed by moving the second operating means 14 to the lowered position A1.

[0038] The installation which has just been described is particularly suitable for automatically raising and lowering the seat surfaces of the chairs according to the user's requirements. In particular, the user will be able to raise all the seat surfaces at the end of operation, and will be able to simply and automatically lower all the seat surfaces again at the beginning of operation so as to be able to operate under normal conditions.