A kayak launching system provides a vertical support pole and submersible rack arms extending out from a dock beneath the water. The rack arms may be lowered to allow a kayak to be positioned above them and then raised to stabilize the kayak during entrance or exit.

A kayak launching system provides a vertical support pole and submersible rack arms extending out from a dock beneath the water. The rack arms may be lowered to allow a kayak to be positioned above them and then raised to stabilize the kayak during entrance or exit.

A cylinder mounting assembly for a hydraulic boat lift includes a plurality of H-frame components for pivotally connecting a pair of bunks to side beams of the lift. A trailing pair of hydraulic cylinder actuators pivotally interconnect the side beams to respective trailing H-frame components. The cylinders are selectively operated to pivot the trailing H-frame components closed such that a first longitudinal channel of each trailing H-frame component receives a respective actuator and an opposite, second longitudinal channel of the trailing H-frame component receivably interengages a respective side beam, which lowers the bunks of the lift sufficiently to facilitate driving a vessel onto and launching a vessel from the lift in shallow water conditions.

A cylinder mounting assembly for a hydraulic boat lift includes a plurality of H-frame components for pivotally connecting a pair of bunks to side beams of the lift. A trailing pair of hydraulic cylinder actuators pivotally interconnect the side beams to respective trailing H-frame components. The cylinders are selectively operated to pivot the trailing H-frame components closed such that a first longitudinal channel of each trailing H-frame component receives a respective actuator and an opposite, second longitudinal channel of the trailing H-frame component receivably interengages a respective side beam, which lowers the bunks of the lift sufficiently to facilitate driving a vessel onto and launching a vessel from the lift in shallow water conditions.

A shiplift transfer system for moving a ship between a shiplift platform and a shipyard is disclosed. The system includes transition rails coupled with the shipyard that are pivotable about trunnion pins between a position that bridges a gap between the shipyard and the shiplift platform and a position that is clear of the gap and of the shiplift platform. The pins are positioned such that the load is not transferred to the pins. Load on the transition rails is reacted at curved surfaces of the transition rails that are engaged with curved surfaces on the yard. The transition rails are accessible for maintenance and replacement via removable plates. The rails include beveling to accommodate misalignment between the yard and platform.

A shiplift transfer system for moving a ship between a shiplift platform and a shipyard is disclosed. The system includes transition rails coupled with the shipyard that are pivotable about trunnion pins between a position that bridges a gap between the shipyard and the shiplift platform and a position that is clear of the gap and of the shiplift platform. The pins are positioned such that the load is not transferred to the pins. Load on the transition rails is reacted at curved surfaces of the transition rails that are engaged with curved surfaces on the yard. The transition rails are accessible for maintenance and replacement via removable plates. The rails include beveling to accommodate misalignment between the yard and platform.

An automated system is provided for moving a boat from a storage position in a boat garage to a deployed position in a dock channel. The system can include a boat trolley. The boat trolley can include a frame that couples to and rides on rails of a track that extends between the boat garage and the dock channel. The boat trolley can also include bunker supports for supporting the hull of the boat. A dock lift mechanism can lower the trolley frame into the water, from which the boat can be deployed. Once done using the boat, the user can navigate the boat onto the trolley frame, and the dock lift mechanism used to lift the trolley frame and boat out of the water, and the boat trolley operated to move the boat from the dock to the boat garage for storage.

An automated system is provided for moving a boat from a storage position in a boat garage to a deployed position in a dock channel. The system can include a boat trolley. The boat trolley can include a frame that couples to and rides on rails of a track that extends between the boat garage and the dock channel. The boat trolley can also include bunker supports for supporting the hull of the boat. A dock lift mechanism can lower the trolley frame into the water, from which the boat can be deployed. Once done using the boat, the user can navigate the boat onto the trolley frame, and the dock lift mechanism used to lift the trolley frame and boat out of the water, and the boat trolley operated to move the boat from the dock to the boat garage for storage.

A watercraft lift system including one or more laterally-adjustable or rotating components and related methods are disclosed. The watercraft lift system can include a cradle assembly and optionally at least one side guide, which can (but need not) be connected to the cradle assembly. The cradle assembly can include first and second cradle rails. One or both of the first cradle rail and the at least one side guide can be movable between a wider watercraft-receiving position and a narrower watercraft-received position. In an example, movement of the first cradle rail and/or the at least one side guide from the watercraft-receiving position to the watercraft-received position occurs automatically upon entry of a watercraft into the confines of the watercraft lift system. The watercraft lift system can further comprise an actuator to cause lateral or rotational movement, for example, of the first cradle rail and/or the at least one side guide. In an example, the actuator can be operably connected to the first cradle rail and/or the at least one side guide via one or more cables or extension plate members.

A watercraft lift system including one or more laterally-adjustable or rotating components and related methods are disclosed. The watercraft lift system can include a cradle assembly and optionally at least one side guide, which can (but need not) be connected to the cradle assembly. The cradle assembly can include first and second cradle rails. One or both of the first cradle rail and the at least one side guide can be movable between a wider watercraft-receiving position and a narrower watercraft-received position. In an example, movement of the first cradle rail and/or the at least one side guide from the watercraft-receiving position to the watercraft-received position occurs automatically upon entry of a watercraft into the confines of the watercraft lift system. The watercraft lift system can further comprise an actuator to cause lateral or rotational movement, for example, of the first cradle rail and/or the at least one side guide. In an example, the actuator can be operably connected to the first cradle rail and/or the at least one side guide via one or more cables or extension plate members.