In a continuously moving cableway installation (9), a haul rope (13b) extends as a closed loop defining a transportation path (12). Suspended vehicles (14) can be connected to the rope by means of automatic coupling devices (24). Along the rope path, passenger stations (10) are provided, each providing ramps (22) to cause the clamping or release of the automatic coupling devices (24), fixed power supply conductors (30), and overhead rails (28). Mounted on board each vehicle (14) are: a motor-driven trolley (20), an electrical contact (30a) to contact one of the power supply conductors (30) in the passenger stations (10), an electric power battery (43), and an electric motor (42) with driving wheels (40) associated thereto, which are suitable for rolling on the overhead rails (28) in order to move the vehicle within and proximate to the passenger stations.

A zip line includes a substantially rigid track supported above a ground surface by a plurality of supports, a trolley which moves along the track, and a rider support suspended from the trolley. The track is comprised of a plurality of track segments connected together such that adjacent track segments have substantially no freedom of movement relative to each other, and such that adjacent track segments present a substantially smooth, continuous, and uninterrupted surface. The track includes a run and a flange extending upwardly from the run. The trolley comprises a frame having upper wheel mounts to which first and second upper wheels are rotatably mounted. The first upper wheels are oriented such that they engage an upper surface of the track run and the second upper wheels are oriented such that they will engage the track flange upon rotational movement of the trolley relative the track run.

A zip line includes a substantially rigid track supported above a ground surface by a plurality of supports, a trolley which moves along the track, and a rider support suspended from the trolley. The track is comprised of a plurality of track segments connected together such that adjacent track segments have substantially no freedom of movement relative to each other, and such that adjacent track segments present a substantially smooth, continuous, and uninterrupted surface. The track includes a run and a flange extending upwardly from the run. The trolley comprises a frame having upper wheel mounts to which first and second upper wheels are rotatably mounted. The first upper wheels are oriented such that they engage an upper surface of the track run and the second upper wheels are oriented such that they will engage the track flange upon rotational movement of the trolley relative the track run.

Emergency egress systems carry multiple riders simultaneously accessing zip line catenary from higher, inaccessible, working locations to lower, safer areas. Hangers above the track line suspend trolleys to avoid weighting the catenary unduly at the high end, which might otherwise alter (reduce) clearance distances and safety of riders above a launch platform (deck). Catenary shape is controlled against approaching a launch deck by sequencing the release from the hangers of each trolley to roll along the catenary with its own rider. Autonomous braking, inter-trolley bumpers, and vertical stabilizers enable each rider to quickly occupy a seat (harness, etc.) and launch onto the track line, unconcerned with riders ahead or behind until underway. Multiple trolleys may thus load, launch, and in close proximity on a single line, regardless of the total weight of multiple riders.

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 canopy tour system follow a route including multiple legs of track line, and may run multiple track lines in parallel along each leg, establishing the route of descent. Each leg extends between an associated upper station and lower station, used for loading, launching, receiving, and unclipping, respectively, riders of trolleys on the zip lines. A system of mechanical and electronic interlocks provides safety for users in remote locations, enabling individual riders to operate trolleys, including attaching and dis-attaching the trolleys from various track lines, unattended by other workers or employees of the canopy tour operation. Multiple trolleys may travel simultaneously and in close proximity to one another as a group on a single line. Each group traveling together is controlled by a single braking trolley ahead, behind, or in the midst of the group.

The disclosure relates to a transportation system for urban mass transit that employs an array of narrow, elevated towers supporting stationary electrified cables. Self-propelled gondolas equipped with electric motors and regenerative braking systems traverse these cables, transporting passengers between various ground-level stations. The gondolas are capable of attaching to and detaching from the cables via an automated mechanism controlled by an onboard computer. The system is modular, allowing for scalable adaptation to urban environments and incorporates solar panels for energy generation. The system's design minimizes urban land use, offering an environmentally conscious alternative to traditional mass transit systems.

Emergency egress systems carry multiple riders simultaneously accessing a zip line (catenary) from higher, accessible, working locations to lower, safer areas in a marine environment. Hangers above the track line suspend trolleys to avoid weighting the catenary unduly at the high end, which might otherwise alter (reduce) clearance distances and safety of riders above a launch platform (deck). Catenary shape is controlled against approaching the launch deck by sequencing the release from the hangers of each trolley to roll along the catenary with its own rider. Track line systems installed may be left undeployed indefinitely. Deployment of a track line will typically be fully effected at the time of egress, adding time but eliminating permanent obstructions that would result if a permanent deployment of track lines were undertaken. Terminal ends are anchored and configured to accommodate workers arriving after escape.

A single pole aerial tramway apparatus carries multiple cycles in an upright position along the path of overhead cables from an aerial tramway. A single, bowed pole supports a multi-cycle support assembly on which multiple cycles are mounted. The bowed pole has a medial region that arcs distally from the cycles, so as to create additional space for loading and carrying the cycles. A bracket forms a junction point that detachably connects a pole cable end of the bowed pole to a cable extension member from the cable. The bracket may be hinged to enable the pole to sway to reduce mechanical stress. A multi-cycle support assembly attaches to the pole cycle end. A primary stabilization bar and a secondary stabilization bar carry and balance the multi-cycle support assembly. Cycle racks set on the stabilization bars receive the cycles in a front tire depression and a rear tire brace.

Data are transmitted from a secondary station to a master station along a segmented path, wherein two contiguous segments are respectively connected by a node and wherein the path has at least three segments with at least two nodes. The data from the secondary station are split into N data packets, where N is the number of nodes. The data packets are marked distinguishably, each marking corresponding to a particular node on the path. Each data packet along the path is forwarded only to the adjacent node or adjacent station. Each node checks to determine whether the marking of the packet corresponds to the respective node. If so, data from the node are added to the data packet. The data packets are collected in the master station. The data transmission is concluded successfully if all N data packets with data from all N nodes are present.