An integrated bollard, anchor, and tower (IBAT) system constructed as a single monolith may be formed of a single material, such as concrete or steel, or assembled from components of distinct materials, such as reinforced concrete with metal brackets, fixtures, fasteners, and so forth. An anchor (e.g., base, pad), sized to engage the ground therebelow by weight and friction, includes a mass sufficient to provide frictional stability (no appreciable movement) of the IBAT unit at each end of a track line (cable, wire rope, line, etc.), which wraps around the bollard portion of each upright (tower, fin) portion at an operational height defining the path of a trolley carried on the free span of the resulting catenary.

A system, method and device for moving gondola cabins in a single vertical loop so as to pass above and below with end stations turning wheels placed vertically. The hauling ropes operate in a vertical loop and permit the vertical circulation of the cabins between stations with passenger boarding and deboarding of the cabins in the stations at two different levels. The system may be twinned to provide two parallel, horizontally adjacent systems operating on common towers to double the capacity of a single system. Both the single and twinned systems possess a smaller footprint than conventional horizontal transport systems.

A system, method and device for moving gondola cabins in a single vertical loop so as to pass above and below with end stations turning wheels placed vertically. The hauling ropes operate in a vertical loop and permit the vertical circulation of the cabins between stations with passenger boarding and deboarding of the cabins in the stations at two different levels. The system may be twinned to provide two parallel, horizontally adjacent systems operating on common towers to double the capacity of a single system. Both the single and twinned systems possess a smaller footprint than conventional horizontal transport systems.

A cable car system includes vehicles that are clamped to a hauling cable along the route and decoupled from the hauling cable upon entering the stations. The vehicles are moved through the stations by control tires which are coupled to one another by gear mechanisms and driven via a supporting pulley for the hauling cable. The control tires are mounted on a supporting frame on at least one supporting structure. The rotation of the supporting pulley that drives the control tires is derived from the hauling cable by way of a drive belt. The drive belt runs over the supporting pulley, which is mounted on a pivotable rocker, and over at least one control tire. The pivotable rocker is mounted on the supporting structure for the supporting frame, or the pivotable rocker is mounted on a supporting structure to which the supporting frame is not attached.

A cable car system includes vehicles that are clamped to a hauling cable along the route and decoupled from the hauling cable upon entering the stations. The vehicles are moved through the stations by control tires which are coupled to one another by gear mechanisms and driven via a supporting pulley for the hauling cable. The control tires are mounted on a supporting frame on at least one supporting structure. The rotation of the supporting pulley that drives the control tires is derived from the hauling cable by way of a drive belt. The drive belt runs over the supporting pulley, which is mounted on a pivotable rocker, and over at least one control tire. The pivotable rocker is mounted on the supporting structure for the supporting frame, or the pivotable rocker is mounted on a supporting structure to which the supporting frame is not attached.

An aerial ropeway hazard sensing system including a radar sensing unit mounted at a position along a ropeway that generates radar data representative of predetermined ropeway conditions proximate the radar sensing unit, and a processor that analyzes data from the radar sensing unit to detect predetermined hazard conditions and to generate a hazard detection signal indicative thereof. A method of performing an aerial ropeway safety function comprises using radar to detect a hazard condition and generating a hazard detection signal in response thereto; generating a control signal in response to the hazard detection signal; and initiating a safety with the control signal.

An aerial ropeway hazard sensing system including a radar sensing unit mounted at a position along a ropeway that generates radar data representative of predetermined ropeway conditions proximate the radar sensing unit, and a processor that analyzes data from the radar sensing unit to detect predetermined hazard conditions and to generate a hazard detection signal indicative thereof. A method of performing an aerial ropeway safety function comprises using radar to detect a hazard condition and generating a hazard detection signal in response thereto; generating a control signal in response to the hazard detection signal; and initiating a safety with the control signal.

This invention is a gravity powered Dual Cable Zipline Trolley Transfer System comprising, a dual cable zipline trolley and dual cable zipline transfer unit which work in conjunction of each other. The trolley comprises tandem wheels that traverse over the dual cables and are pivoted in the center to allow the trolley to pass smoothly over the transfer unit, which is suspended on support structures. Unlike the traditional zipline which has a path between two stations, this system is designed to allow the participant to travel in a continuous uninterrupted path without the need to detach from one cable to another in order to sustain the journey beyond the station. The transfer unit is lengthened to create curves both horizontal and vertical. This invention eliminates the menacing sag in the cable that occurs over distance.

This invention is a gravity powered Dual Cable Zipline Trolley Transfer System comprising, a dual cable zipline trolley and dual cable zipline transfer unit which work in conjunction of each other. The trolley comprises tandem wheels that traverse over the dual cables and are pivoted in the center to allow the trolley to pass smoothly over the transfer unit, which is suspended on support structures. Unlike the traditional zipline which has a path between two stations, this system is designed to allow the participant to travel in a continuous uninterrupted path without the need to detach from one cable to another in order to sustain the journey beyond the station. The transfer unit is lengthened to create curves both horizontal and vertical. This invention eliminates the menacing sag in the cable that occurs over distance.

Cable transport installation, including: at least one carrier, a first hauling cable to haul at least one carrier and describing a first closed loop, and a second hauling cable to haul at least one carrier and describing a second closed loop, the second loop surrounding the first loop so as to create a separating space between the first and second hauling cables.