FR3001689A1 - BALANCING BONDING DEVICE-CABLE MECHANICAL REMOTE POTENCY - Google Patents

Abstract

The present invention relates to a connecting device between a bracket and a hardened mechanical lift balance (3) comprising a connecting shaft (1), said connecting device comprising at least one passive deformation sensor (7), said passive sensor of deformation (7) being capable of allowing the counting of the number of deformations undergone by the connection axis (1) exceeding at least one determined deformation threshold.

Description

Rocker-stem connecting device for ropeway.

Description. The present invention relates to the field of cable ski lifts and more specifically the field of parts and maintenance elements used during the life of the ski lift at the pylons and balances in connection with the cable. A wired mechanical lift tower usually has a pylon at the top of which is mounted a bracket. On both sides of the stem, are connected balancers carrying rotating rollers in contact with the cable. The mechanical lift pylon may be in compression, that is to say that the cable passes under the rollers, or in support, that is to say that the cable passes over the rollers, or compression-support that is, the cable passes between the rollers.

The rockers are linked to the stem by means of a connecting device comprising a connecting pin, which allows rotational movements thereof around said link axis. These connecting axes are therefore subjected to great mechanical stress, in fact they support the weight of the balance, the weight and tension of the cable as well as the vibrations and deformations generated by the movement of the cable, the passage of transport vehicles such as seats, cabins or poles and the loading of said transport vehicles. BRT1112 Because of these constraints, these connecting axes deform more or less periodically, gradually producing a deterioration of the latter. They are therefore strongly inspected after disassembly during scheduled inspection visits according to time intervals that vary according to the different laws and regulations. The schedule for control, disassembly and change is defined in relation to the applicable regulations and management choices made in agreement with the regulatory body in charge. The checks carried out on the connecting axes are of a visual nature and / or non-destructive, only defects in surfaces, cracks, corrosion, lightning strikes or dimensional defects are sought. Nevertheless, in order to space the controls of these links and to avoid a complete dismantling, the operators of the ski lifts tend to change these parts to be cautious during the dismantling and to start again on new assemblies while the connecting axes are in good condition and could be reassembled or could have not been disassembled. One of the aims of the invention is therefore to propose a connection device whose control of the connection axis is improved and does not require complete disassembly before said connection axis has accumulated significant damage. link that can be reused or stored while respecting the standards and requirements of the regulatory body. BRT1112 The present invention thus relates to a connecting device between a stem and a cable mechanical lift rocker having a connecting axis, said connecting device comprising at least one passive deformation sensor, said passive deformation sensor being able to allow the accounting the number of deformations undergone by the connection axis exceeding at least one determined deformation threshold. The presence of such a sensor thus makes it possible to measure wear, fatigue and any other form of damage, produced by the mechanical stresses, of the connection axis so that it can, if necessary, not be replaced. and stay in place. According to one aspect of the invention, the connecting device comprises at least one passive deformation sensor capable of accounting for the strains-related deformations along the axis defined by the resultant of the forces exerted on the connecting axis 1. According to In another aspect of the invention, the connecting device comprises at least one passive deformation sensor capable of recognizing the deformations linked to stresses perpendicular to the axis defined by the resultant of the forces exerted on the connecting axis 1. According to another aspect of the invention, the counting of the number of deformations is controllable by means of electromagnetic waves. BRT1112 According to another aspect of the invention, the counting of the number of deformations is controllable visually. According to another aspect of the invention, the at least one passive deformation sensor 5 is fixed at the level of the maximum accessible deformation point of the connection axis. According to another aspect of the invention, the passive deformation sensor is attached to the connection axis. According to another aspect of the invention, the connecting shaft is fixed by a first end to the bracket and by a second end to the balance, said connecting axis being supported, between its first and second end, on a ful point of support of the bracket and that at least one passive deformation sensor is fixed at the point of support on the connecting axis. According to another aspect of the invention, the passive deformation sensor is attached to the balance. According to another aspect of the invention, the balance comprises a tubular orifice, the bracket comprising at least two mounting brackets pierced with orifice between which is inserted the rocker, the connection axis passing through the at least two fasteners supports as well as the tubular orifice, and that the at least one passive deformation sensor is fixed at the level of the tubular orifice. BRT1112 According to another aspect of the invention, the passive deformation sensor is an autonomous passive mechanical sensor of the ChronoMEMS® type.

According to another aspect of the invention, the passive deformation sensor is a deformation sensor with calibrated fuse blades. According to another aspect of the invention, the passive deformation sensor is an autonomous electronic deformation sensor.

According to another aspect of the invention, the attachment between the passive deformation sensor and the surface of the connecting shaft comprises a tamper-proof device.

According to another aspect of the invention, the passive deformation sensor comprises an individual identification marking. The invention also relates to a mechanical lift tower comprising at least one connecting device as described above. Other features and advantages of the invention will emerge more clearly on reading the following description, given by way of illustrative and non-limiting example, among which: FIG. 1a, showing a schematic representation of a pylon beam wired top-view mechanical lift, BRT1112 FIG. 1b, showing a schematic representation of a mechanical lift mast rocker beam in profile view, FIG. 2a, showing a schematic representation of a gimbal-balance beam connection axis. 2b, showing a schematic representation of a gimbal-beam connecting axis in top view, FIG. 2c, showing a schematic representation of a gimbal-beam connecting axis in front view, FIG. Figure 3 showing an exploded schematic representation of a connecting device according to another embodiment. The identical elements bear similar references in the different figures.

The pendulums 3 of cableway lifts wired are generally related to the gallows (not shown) by means of a connecting device comprising a connecting pin 1 around which a rocker 3 can rotate.

FIGS. 1a and 1b respectively show a view from above and from the side, a rocker 3 and its connecting pin 1 which allows the connection with the bracket (not shown) of a mechanical lift mast wired according to a first embodiment .

In the example illustrated by Figures 1a and 1b, the balance comprises four assemblies 2 composed of two rotary rollers 5. The sets 2 of rollers 5 are connected to the balance 3 by means of axes 4 BRT1112 over which they can tilt so to follow the curvature of the cable. FIGS. 2a, 2b and 2c respectively show a profile view, from above and from the front, of the connecting pin 1 according to the first embodiment shown in FIGS. 1a and 1b. The connecting pin 1 makes the connection between the stem and the rocker 3, said stem is fixed to the connecting pin 1 at a first end 10a and the rocker 3 is in turn fixed to the axis of link 1 to 10 at a second end 10b. As shown in Figures 2a and 2b, the first end 10a of the connecting pin 1 may comprise for example fasteners 12 for fixing said connecting pin 1 to the bracket. These fixing members 12 make it possible to block the connecting axis 1 in all the directions of space represented by the x, y and z axes. The fasteners 12 may, for example, be threaded rods 11 passing right through the first end 10a of the connecting pin 1. Thus, in order to block the link axis 1 in all directions, the fastener 12 may comprise two threaded rods 11 having an angle of 90 ° with each other. The threaded rods 11 are then fixed to the bracket with bolts. Adjustment of the position of the connecting pin on the threaded rods 11 can be achieved by means of nuts 13 and makes it possible to finely adjust the positioning of the connecting pin 1 relative to the stem. The attachment between the connecting pin 1 and the stem also comprises a fulcrum 16 on which the connecting pin 1 is based. The BRT1112 fulcrum 16 is integral with the stem and bears against the link axis 1 between the first 10a and second 10b ends. The connection between the connecting pin 1 and the beam 3 at the second end 10b is a rotary connection, that is to say that the rocker can tilt around the connecting axis 1. The balance 3 can thus include an orifice into which the second end 10b of the connecting pin 1 is inserted. The rocker 3 can be retained on the connecting pin 1 on one side by a shoulder 10c formed on the connection axis 1 and 10 on the other side by a housing 10b attached to the end of the connecting pin or by a pin. The connecting device also comprises at least one passive deformation sensor 7. The passive deformation sensor 7 is a sensor capable of enabling the number of deformations exceeding at least one determined deformation threshold of the connection axis 1 to be accounted for. Passive means that the passive sensor deformation 7 requires no energy input other than the deformation itself to achieve the accounting. The passive deformation sensor 7 is preferably fixed at the level of the maximum accessible deformation point of the connecting axis 1. By accessible maximum deformation point means the point of the connecting axis 1 which undergoes the strongest deformations while being accessible for attachment and consultation of the passive deformation sensor 7. In the first embodiment described above and illustrated in FIGS. 2a, 2b and 2c, the maximum deformation point BRT1112 accessible is located at the point 16 and the passive strain sensor 7 can be fixed to the connecting pin 1. According to a second embodiment shown in FIG. 3, the deformation sensor 7 is fixed to the balance 3 at the axis link. In this second embodiment of the connecting device, the balance 3 comprises a tubular orifice 21, the bracket comprises at least two mounting brackets 23 pierced with an orifice between which is inserted the balance 3. The connecting pin 1 crosses the orifice of the at least two fastening supports 23 and the tubular orifice 21. The connecting pin 1 is held in place on the one hand by a shoulder 10c at one of its ends and secondly by a fastener 25 at its opposite end, for example a flange. The at least one passive deformation sensor 7 can thus account for the deformations exceeding at least a certain threshold, according to different orientations. The same passive deformation sensor 7 can account for the number of deformations exceeding one or more different thresholds in one or more directions, for example deformations linked to stresses along the axis defined by the resultant of the forces exerted on the axis of deformation. link 1 and / or deformations perpendicular to said axis defined by the resultant forces. The recognition of the deformations undergone by the connecting axis 1 can be consulted by means of electromagnetic waves. Thus the passive deformation sensor 7 can be consulted for example visually or by other means using a communication without BRT1112 son such as for example infrared communication, radio frequency or any other means known to those skilled in the art. The passive deformation sensor 7 can thus be an autonomous passive mechanical deformation sensor of the ChronoMEMS® type developed by SilMach®. This autonomous passive mechanical deformation sensor comprises one or more dials on which the deformation accounting is mechanically inscribed.

The passive deformation sensor 7 may also be a deformation sensor with fuse blades. This type of sensor makes it possible to calculate the number of deformations taking into account the number and calibrated fusible blades that have yielded. The passive deformation sensor 7 may also be an autonomous electronic deformation sensor. These different types of sensors make it possible to overcome the constraints of power supply related to the use of conventional strain sensors and thus allow easy installation in difficult locations. In addition, these sensors have increased resistance to weather conditions. The passive deformation sensor 7 can be attached, whether to the connection axis 1, to the balance 3 or to any other element of the connecting device by various means such as for example by gluing, screwing on its support or by fastening by means of flanges. BRT1112 The consultation of the accounting of the deformations undergone by the connecting axis 1 makes it possible to determine the state of wear of said connecting axis. Thus, during the safety checks carried out on the pylons, it is no longer necessary to dismantle the balance to be aware of the state of damage and wear or fatigue of the connecting pin 1. In coordination With the regulatory body in charge of the standards and controls concerning the ski lifts, it is therefore possible to determine a limit of the number of deformations beyond which the connecting pin 1 is considered as worn and must be replaced. In order to guarantee the recognition of deformation performed by the passive deformation sensor 7, its attachment with the connecting pin 1 includes a device for guaranteeing tamperproofness. For example, this tamper-proof device may be screws or bolts having sealing plummets that break upon disassembly of the passive strain sensor 7. In addition, for ease of control and authentication of the sensor 7, always in the interests of guaranteeing the counting, the latter may comprise an individual identification marking, for example an engraved identification number or a contactless electronic chip, for example by radio-identification or communication type in the near field.

Thus, it is clear that the connecting axis 1 because it comprises a passive deformation sensor 7, allows a less expensive maintenance of cable ski lift. Indeed, the disassembly of the balance 3 is no longer necessary to carry out the controls on the BRT1112 link 1 axis and its replacement is only necessary depending on the constraints and deformations that it has undergone throughout its use. BRT1112

Claims (16)

REVENDICATIONS1. Connecting device between a bracket and a hardened mechanical lift beam (3) comprising a connecting pin (1), characterized in that said connecting device comprises at least one passive deformation sensor (7), said passive deformation sensor (7) being able to allow the counting of the number of deformations undergone by the connection axis (1) exceeding at least one determined deformation threshold. 2. Connecting device according to the preceding claim, characterized in that it comprises at least one passive deformation sensor (7) capable of accounting for the deformations along the axis defined by the resultant forces exerted on the connecting axis 1 . 3. Connecting device according to one of the preceding claims, characterized in that it comprises at least one passive deformation sensor (7) capable of accounting for deformations related to constraints perpendicular to the axis defined by the resultant forces exerted on the connecting axis 1. 4. Connecting device according to one of the preceding claims, characterized in that the counting of the number of deformations is controllable by means of electromagnetic waves. BRT1112 5. Connecting device according to the preceding claim, characterized in that the counting of the number of deformations is controllable visually. 6. Connecting device according to one of the preceding claims, characterized in that the at least one passive deformation sensor (7) is fixed at the maximum accessible deformation point of the connecting axis (1). 7. Connecting device according to one of the preceding claims, characterized in that the passive deformation sensor (7) is fixed to the connecting axis (1). 8. Connecting device according to the preceding claim, characterized in that the connecting shaft (1) is fixed by a first end (10a) to the bracket and a second end (10b) to the balance (3), said axis link (1) being supported, between its first (10a) and its second (10b) end, on a fulcrum (16) integral with the bracket and that the at least one passive deformation sensor (7) is fixed at the point of support (16) on the connecting shaft (1). 9. Connecting device according to one of claims 1 to 6, characterized in that the passive deformation sensor (7) is fixed to the beam (3). 10. Connecting device according to the preceding claim, characterized in that the rocker (3) has a tubular orifice (23), the bracket BRT1112comportant at least two mounting brackets (23) pierced with orifice between which is inserted the pendulum ( 3), the connecting pin (1) passing through the at least two attachment supports (23) and the tubular orifice (23), and that the at least one passive deformation sensor (7) is fixed at the level of the tubular orifice (23). 11. Connecting device according to one of the preceding claims, characterized in that the passive deformation sensor (7) is an autonomous passive mechanical sensor type ChronoMEMS®. 12. Connecting device according to one of claims 1 to 10, characterized in that the passive deformation sensor (7) is a deformation sensor with calibrated fuse blades. 13. Connecting device according to one of claims 1 to 10, characterized in that the passive deformation sensor (7) is an autonomous electronic deformation sensor. 14. Connecting device according to one of the preceding claims, characterized in that the attachment between the passive deformation sensor (7) and the surface of the connecting pin (1) comprises a tamper-proof device. 15. Connecting device according to one of the preceding claims, characterized in that the passive deformation sensor (7) comprises an individual identification marking. BRT1112 16. Lift installation comprising at least one connecting device according to one of claims 1 to 15. BRT1112