An adapter assembly for lifting a vehicle includes an adapter defining a first pin aperture, a second pin aperture, and an adapter aperture, a first pin, a second pin, and a cross member removably received by the adapter aperture. The first pin is configured to be removably received by the first pin aperture and a first aperture defined by a frame of the vehicle to selectively couple the adapter to the frame. The second pin is configured to be removably received by the second pin aperture and a second aperture defined by the frame of the vehicle to selectively couple the adapter to the frame.

A jack, comprising: a top plate adapted to contact a load; a base plate positioned below the top plate; at least one actuator coupled perpendicularly between the base plate and the top plate; wherein the at least one actuator is operable to move the top plate between a lowered position and a raised position to thereby lower and raise the load; and, at least one locking assembly adapted to lock the top plate in the raised position.

A jack, comprising: a top plate adapted to contact a load; a base plate positioned below the top plate; at least one actuator coupled perpendicularly between the base plate and the top plate; wherein the at least one actuator is operable to move the top plate between a lowered position and a raised position to thereby lower and raise the load; and, at least one locking assembly adapted to lock the top plate in the raised position.

Vessel transfer systems are provide herein. The systems include bogies, including a pivoting bogie and a rack and pinion bogie, as well as associated cradles, carriages, and power and control units. The pivoting bogie includes a first side frame, a second side frame, at least one wheel coupled with each of the first and second side frames, and a lift member coupled with each of the first and second side frames. The lift member is pivotably coupled to the first side frame. The rack and pinion bogie includes a frame and pinion gears coupled with the frame. The pinion gears can be selectively coupled with a gear rack, such as at a shipyard. Also provided herein are methods of use of one or both of the bogies and associated equipment, such as for moving vessels within a shipyard.

A portable vehicle lift and methods of using the same are provided. The portable vehicle lift comprises a carriage, a head saddle, and a lift driver. The head saddle is movably connected to the carriage so that it is shiftable between a lowered position and a raised position. The lift driver supported on the carriage and configured to lift the head saddle.

Engine installation systems and related methods. An engine installation system includes an adapter cradle and a transport dolly. The adapter cradle is configured to support the engine, and the transport dolly is configured to be selectively and operatively coupled to the adapter cradle to support the adapter cradle to facilitate transporting the adapter cradle and the engine across a ground surface.

The adapter cradle is configured to be selectively coupled to each of the transport dolly and the vehicle. The adapter cradle is configured to pivot relative to the transport dolly or relative to the vehicle to transition between a transport configuration and an upright configuration. In examples, methods of installing an engine within an engine bay of a vehicle include positioning the engine beneath the engine bay, pivoting the engine relative to the vehicle, and lifting the engine into the engine bay.

An autonomous jack system. The system provides an autonomous jack housed in a storage condition under a vehicle. The autonomous jack having an extensible jack arm pivotably connected to a body with a motive source and lockable tracks to exit its storage condition and traverse uneven terrain and lock its track at a point there along. The system embodies placing lift points along the underside of a vehicle, each lift point associated with a wheel that may need to be lifted off a supporting surface. The lift point includes an identifier that may send an indication of the lift point to the autonomous jack having sensors to read the indication and navigate the supporting surface. The lift point is identified through a computer-implemented control panel operated by a user. The jack arm terminates in a hand dimensioned and adapted to operatively associate with the identified lift point.

An autonomous jack system. The system provides an autonomous jack housed in a storage condition under a vehicle. The autonomous jack having an extensible jack arm pivotably connected to a body with a motive source and lockable tracks to exit its storage condition and traverse uneven terrain and lock its track at a point there along. The system embodies placing lift points along the underside of a vehicle, each lift point associated with a wheel that may need to be lifted off a supporting surface. The lift point includes an identifier that may send an indication of the lift point to the autonomous jack having sensors to read the indication and navigate the supporting surface. The lift point is identified through a computer-implemented control panel operated by a user. The jack arm terminates in a hand dimensioned and adapted to operatively associate with the identified lift point.

Automated jackstand systems and methods deploy a jackstand to support a front end of a trailer parked at an automated loading dock. The jackstand prevents collapse of the trailer's landing gear and prevents upending of the trailer during loading and unloading. Advantageously, by deploying the jackstand automatically, presence of personnel in the yard where tractors and trailers are moving is not required.

Automated jackstand systems and methods deploy a jackstand to support a front end of a trailer parked at an automated loading dock. The jackstand prevents collapse of the trailer's landing gear and prevents upending of the trailer during loading and unloading. Advantageously, by deploying the jackstand automatically, presence of personnel in the yard where tractors and trailers are moving is not required.