This application claims the benefit of and priority to Italian Patent Application No. 102019000001097 filed on Jan. 24, 2019, the entire contents of which are incorporated by reference herein.
The present disclosure is included in the technical field of cable transportation systems. The term “cable transportation system” is understood to mean a system for the transport of passengers with at least one cable, in which a plurality of transporting units are moved in series, one after another, in a configuration suspended from the ground along a route, which extends between two terminal stations (known as the upstream and downstream station), in which the passengers can board and alight from the transporting units.
In particular, the technical field of the present disclosure comprises both “single-cable” cable transportation systems, in which the hauling cable also acts as a supporting cable for supporting the transporting units in a configuration suspended from the ground, and “two-cables” and “three-cables” transportation systems, in which, besides the hauling cable, one or two supporting cables are present respectively having the purpose of supporting the transporting units in a configuration suspended from the ground. As known, the hauling cable is driven in a ring and moved between the terminal stations, and the transporting units comprise special devices (for example, clamps) for staying coupled to the hauling cable at least in the section outside the stations. If at least one supporting cable is present, the latter is substantially fixed (i.e., not moved between the stations other than for periodic maintenance steps and only subject to limited movements due to the varying line load conditions), and the transporting units further comprise devices close to the clamp (for example, at least one roller) capable of sliding along the supporting cable. In the case of three-cables systems, the transporting units are provided with actual trolleys for sliding on the two supporting cables. Systems with two supporting cables (particularly for low inclines) can also be devoid of the hauling cable and provided with motorized trolleys.
The above-mentioned term: “in a configuration suspended from the ground” refers to the fact that the transporting units (at least in the stretch between the stations) do not rest, at the bottom, on any guiding or supporting structure as opposed to the technical field of transportation systems (also of the type with a hauling cable), in which the transporting units are guided and supported, at the bottom, by a fixed structure (for example, a rail). In fact, as will emerge below, neither in this last case do certain of the problems underlying the present disclosure arise.
Cable transportation systems are commonly used today, in which passengers are carried along a route inside special transporting units fed, one after another, between two terminal stations, known as upstream and downstream stations. In particular, the present disclosure relates to cable systems, in which such transporting units are moved in a configuration raised or suspended with respect to the ground level or with respect to other possible underlying fixed structures. In fact, this raised and suspended configuration is frequently advantageous when the conformation of the ground below, or other accompanying factors, do not make alternative land travel viable, in which the transporting units, such as, for example, the carriages of a train travel resting at the bottom on guides that, in turn, rest more or less directly on the ground. For example, such cable systems are used in the case in which the route to be covered involves significant jumps in altitude, including with considerable inclines. This route is typical of lift systems present in ski resorts/mountainous areas. In these types of systems, often, it is also necessary, for various reasons, to provide fixed supporting structures for the hauling cable and/or the supporting cables located along the route in an intermediate position between the downstream and upstream stations. One reason may be an excessive distance between the terminal stations, which is such as not to allow the cable to be arranged in a single span between the stations. Another reason may be the elevation profile of the path of the system if there are significant incline changes. In these cases, as in other non-listed cases, cable transportation systems are thus provided with one or more fixed intermediate structures for supporting the cables. Each fixed intermediate structure comprises a vertical supporting structure, such as, for example, a pylon or a pole, on top of which guiding devices for the cable are provided, for example, a series of rollers. These rollers act as a support for the hauling cable and can be arranged along a single row (known as a supporting or retaining roller conveyor) or along two overlapping rows between which the hauling cable is slid (double-action roller conveyor). In particular, these rows of rollers are installed on the top of the pylons by special fixed cantilever structures (also known as supporting heads), on the one side coupled to the pylon and on the other side supporting the aforesaid rollers. As known, this cantilever structure is not only present on one side of the pylon, but also on the opposite side, symmetrical to the pylon, so as to provide a substantially T-shaped fixed structure for supporting both the ascent and descent branches of the hauling cable. These cantilever structures are also configured for enabling a periodic inspection and maintenance of the rollers and to this end, they are provided with special platforms (protected with railings) for the service staff to walk on. If at least one supporting cable is present the latter is always supported at the head of the pylons in a special structure known as a shoe. At this shoe, the roller for rolling on the supporting cable rolls on the outer profiles of the shoe.
Current legislation prescribes a minimum safety distance, which must be present between these fixed supporting intermediate structures and the transporting units transiting along the system. It is also necessary to consider that the transporting units may tilt due to the presence of wind, both laterally (or make rolling movements around the axis defined by the hauling cable or advance directly in a tilted configuration) and longitudinally (or make pitching movements). Thus, the maximum admissible tilting of the vehicles is one of the design parameters of a cable system of these two types. On reaching and exceeding the critical wind speed, at which the transporting units tilt beyond a certain limit angle with respect to the gravity vertical, it is necessary to implement safety measures, such as reducing the advancing speed or stopping the system. For example, EP Patent No. 1837264 describes a cable transportation system provided with special sensors for monitoring the tilting of the transporting unit and consequently controlling the operation of the system.
However, in this scenario, it is also necessary to consider that the wind speed can also change relatively very quickly (so-called “gusts”). In this case, contact between the transporting units and the movable or fixed parts of the fixed intermediate structures (particularly with the platforms or cantilever supporting structures of the rollers or fixed supporting structures of the cables) cannot be excluded due to a lack of physical time needed to slow down or stop the system or due to the need to proceed with the operation for storing the transporting units in any case (an operation lasting about 30 minutes or more). The transporting unit, which comes into contact with the fixed intermediate structure, can also be hooked or blocked by the structure itself and, in such conditions, the transporting unit can fall to the ground or the hauling cable can slide in the clamp with consequent damage to the cable. Furthermore, in these conditions, the successive transporting units can hit the blocked one creating a relatively extremely dangerous situation.
Thus, in cable transportation systems, there is a need not only to monitor the tilting of the transporting units in transit, but also to have an immediate confirmation of any contact or collisions between the transporting units and the supporting intermediate structures arranged along the route.
Thus, one purpose of the present disclosure is to provide a cable transportation system of the single-cable or two-cables type, capable of overcoming certain of the drawbacks highlighted by certain of the prior art. In particular, the main purpose of the present disclosure is to provide a cable transportation system capable of giving relative immediate confirmation of a possible impact between a laterally tilted transporting unit due to crosswind, and the fixed support structures arranged along the route between the upstream and downstream stations.
In accordance with these purposes, and depending on the general definition thereof, the present disclosure relates to a cable transportation system of the type with at least one cable (thus, single-cable, two-cables, three-cables systems, or systems with two supporting cables and a motorized trolley), in which a plurality of transporting units advance, one after another, between two terminal stations—upstream and downstream—in a configuration suspended in the void (also at a considerable height).
As stated previously, the term “suspended in the void” is understood to mean that the transporting units do not rest on any supporting or guiding structure at the bottom and that, on the contrary, they can perform rolling movements around the axis of the hauling cable to which they are coupled at the top (normally due to a suspension arm installed above a cabin or a chair). The cable system of the present disclosure can also be a portion of a greater hybrid system provided with a portion of a system configured as a cable system and of a rail portion, in which the transporting units rest, at the bottom, on this rail.
Considering such general premises, a cable system in which the solution offered by the present disclosure can advantageously be integrated comprises:
Reviewing this list of characteristics, it is possible to specify some of them and make the following clarifications to further define the protective scope of the present disclosure.
The first characteristic (i.e., at least one cable) highlights the fact that the system, in which the present disclosure can advantageously be integrated, is a cable system, (i.e., a system, in which the transporting units are suspended to a cable to which they are coupled, such as clamped in the case of a hauling cable). In systems with a hauling cable, the latter is produced in the shape of a closed ring, sent back at the upstream and downstream stations, inside which there is a motorized pulley for moving the cable. Inside the stations, the transporting units unclamp from the hauling cable and advance (for example, by motorized rubberized wheels) so as to enable comfortable boarding/alighting of passengers, at a relatively low speed, without compromising the speed of the units outside the station and consequently, the hourly capacity of the system. In single-cable systems, in which only the aforesaid hauling cable is present, this also acts as a supporting cable. In two-cables and three-cables systems, these functions are divided between the hauling cable (advancing) and in the at least one supporting cable (support). In this case, the supporting cable is fixed and the transporting unit comprises at least one roller for advancing supported by the supporting cable and suspended in the void. Systems, which can integrate the present disclosure are hybrid systems, in which at least one advancing portion is also provided with the transporting units, which rest on guides, at the bottom (for example, rails).
Characteristic c) (i.e., a plurality of supporting intermediate structures for supporting the cable between the upstream and downstream stations) identifies the presence, in the system, of other fixed structures, for supporting the cable, arranged along the path between the upstream and downstream stations. In certain embodiments, these structures are vertical pylons or poles having a first end coupled to the ground and a second end where the cable is passed. These pylons are necessary for several reasons. For example, the distance between the upstream and downstream stations can be too great for a single span of hauling cable or the route can have varying inclines, which are such as to require, also in this case, the subdivision of the cable into two spans with a different inclination. Besides the aforesaid vertical pylon, the top of these supports comprises at least one cantilever supporting structure, which extends laterally (and, for example, at least a row of supporting rollers for the cable, specifically the hauling cable), and is constrained to the free end of the cantilever supporting structure. The latter serves to guarantee a correct safety distance between the vertical pylon and the transporting units in transit. The rows of rollers can be single (supporting or restraining roller conveyor) or superimposed (double-action roller conveyor); in the second case, the cable passes between these two rows. In both cases the grooves of the rollers are opportunely shaped to house both the cable and the clamp, which connects the cable to the relative transporting unit. The rows of rollers comprise outer shoes capable of supporting the cable and the clamp, including in the case of derailment. The cantilever structure also comprises a platform, in the shape of steps parallel to the row of rollers, to enable the periodic inspection of the same. For safety reasons, the platform is also provided with a fall-arrest railing. Two cantilever structures are usually provided, symmetrical to each other, to support both the outgoing and incoming branches of the hauling cable. If at least one supporting cable is present, a structure is also provided at the top of the pylons, known as a shoe, at which the rollers that roll on the supporting cable rest on the sides of the shoe.
According to characteristic d) (i.e., a plurality of transporting units coupled at the top to the cable in a configuration suspended in the void and free to roll around the hauling cable due to crosswind) the disclosure comprises a plurality of transporting units, which are coupled to the cable in a specific way (i.e., they are coupled to the cable “at the top”) and they are free to perform rotations, such as lateral rotations (i.e., rolling around the hauling cable) or longitudinal rotations. In certain embodiments, this configuration is obtained with a cabin, a chair, or other passenger transporting structures, characterized by a substantially vertical supporting arm (said suspension), which extends, at the top, beyond the volume of the cabin or chairs. In the case of a cabin, this arm is often coupled, at the bottom, to the roof of the cabin. A coupling device is mounted on the opposite and upper end of the suspension (such as a clamp which is releasable for the aforesaid reasons) with the hauling cable and, possibly, a roller for advancing on the supporting cable, if present. Since at the bottom, the floor of the cabin or the bottom of the chair is not resting on any guiding or supporting structure, the transporting unit is free to rotate or swing around the axis of the hauling cable, including longitudinally. In technical detail, it is worth pointing out that the transporting unit “doesn't rotate” in relation to the cable but integrally with the same. In fact, the cable also being clamped, it is pulled to rotate around the axis thereof by the rotation of the cabin.
Due to these possible rolling and/or pitching movements in the case of wind the transporting units can advance in a tilted position with respect to the natural position (by gravity) in wind-free conditions. Thus, geometrically, the volume (for example, the side volume) of the transporting units increases as the wind increases. It is known to include instruments capable of monitoring the tilting of the transporting units and control devices capable of modifying the speed of the system in the case of strong wind. In the case of relatively strong gusts of wind, the transporting unit can take on a tilt, which is such (i.e., beyond a limit angle) so as to lead to the impact against the lower end of the cantilever structures (particularly the lower part of the platform) at the pylons. The potential contact points between the transporting unit and the cantilever structure, as well as the aforesaid limit angle can be estimated, from a design point of view, fairly accurately.
As mentioned previously, this possible impact may have relatively very dangerous consequences. For example, the transporting unit, which comes into contact with the parts of the fixed intermediate structure, can also be hooked or blocked by the structure itself and, after this, fall to the ground, or the hauling cable can slide in the clamps with consequent damage to the cable. Furthermore, this event can result in a pileup between the successive transporting units and the blocked unit. Thus, it is necessary to have immediate confirmation of a possible impact of this kind.
To solve this problem, in the most general formulation thereof, the present disclosure thus requires that the system be provided with an alarm device configured for detecting contact between the transporting units and the supporting intermediate structures and emitting an alarm signal. The power supply of these devices is not a technical limit because electrically fed equipment or sensors are currently provided in similar positions.
From a technical point of view, this disclosure can be implemented in many ways; for example, by providing contact sensors or probes on the transporting units and/or on the fixed intermediate structures at least at the relative portions affected by the impact. Among the many possible embodiments, a particularly advantageous one of an electromechanical type will be described below. This solution will be relatively extremely simple and easy to inspect and can also be assembled on pre-existing systems and can relatively easily be adapted to different geometric shapes of the portions affected by a possible impact.
In certain embodiments, the alarm device can be configured not only for emitting an alarm signal, but also for transmitting this signal to the system control unit, for example, the system's surveillance system. This control unit, in turn, can be configured for automatically blocking the system on receiving the alarm signal or it can implement different control logics based on the alarm received. In fact, the alarm signal can be a signal not only containing information about the impact, but also information about the entity of the impact and/or the position of the collision.
The particularly advantageous solution, which will be described with reference to the attached figures, requires that the alarm device be made by at least one string electrically connected to the system's surveillance system and arranged along outer portions of the supporting intermediate structures (such as on the lower face of the platform) at those positions most at risk of an impact. For example, according to the present disclosure, the string electrically connected to the system's surveillance system can also be an electric cable (e.g., a simple string not electrically fed in itself, but connected, such as stretched, to a terminal), in which the terminal recognises an excess or lack of tension and, in such case, transmits an electric alarm signal. In certain embodiments, the string can be arranged in a zig-zag to cover the entire lower surface of the platform. This string electrically connected to the system's surveillance system can be configured for emitting the alarm signal in the case of breaking, but also in the case of simply varying the extent of the tensioning. In this last case, the string is previously pre-tensioned in a controlled manner. This controlled pre-tensioning enables an increase in tension to be recognized (e.g., if the string does not break but is pulled by the vehicle) or a reduction in tension (e.g., in the case of breaking or deforming/breaking caused by a hooking element with consequent shortening of the “theoretical” length of the string). This string can be kept in position by providing for special supporting elements (for example, eyebolts, such as eyebolts made of frangible or flexible material so as not to create a potential interlocking point for the transporting units) and possibly, a structurally more rigid string around which to wrap the “electrical” string. The transporting units, for their part, can also be provided with special portions (for example, small localized protrusions made of rubber) configured for possibly impacting against the string.
As said previously, this example is particularly advantageous; however, it is only one of the various embodiments of the disclosure. For example, it is possible to provide the exact opposite of the above (i.e., the string arranged on portions of the transporting units, for example, along the periphery of the roof of a cabin, and possible protrusions made of rubber on the lower surface of the platforms).
Additional features are described in, and will be apparent from the following Detailed Description and the figures.
Further features and advantages of the present disclosure will become clear from the following description of a non-limiting embodiment thereof, with reference to the figures of the accompanying drawings, wherein:
With reference to the accompany figures,
As said previously,
As said previously,
Thus,
Finally, changes and variations can clearly be made to the disclosure described herein, without departing from the scope of the accompanying claims. Accordingly, various changes and modifications to the presently disclosed embodiments will be apparent to those skilled in the art.
Number | Date | Country | Kind |
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102019000001097 | Jan 2019 | IT | national |
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7082880 | Schertler | Aug 2006 | B2 |
7802523 | Moritzhuber et al. | Sep 2010 | B2 |
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1034996 | Sep 2000 | EP |
1 837 264 | Sep 2007 | EP |
H01 204860 | Aug 1989 | JP |
H02 65667 | May 1990 | JP |
H0265667 | May 1990 | JP |
H07 108931 | Apr 1995 | JP |
H07108931 | Apr 1995 | JP |
WO 9530216 | Nov 1995 | WO |
WO-9530216 | Nov 1995 | WO |
WO 2010066712 | Jun 2010 | WO |
WO-2010066712 | Jun 2010 | WO |
WO 2019007870 | Jan 2019 | WO |
Entry |
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Italian Search Report for Italian Application No. IT 2019000001097 dated Oct. 1, 2019. |
Number | Date | Country | |
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20200239034 A1 | Jul 2020 | US |