The present invention relates to a lifting system and method for lifting a vehicle, wherein the lifting system including one or more lifting devices and: a frame with a carrier configured for carrying the vehicle; a drive for driving the carrier in at least one of the ascent or descent of the carrier; and a controller including an indoor positioning system with a transponder, wherein the transponder is provided on or at the carrier such that the controller determines the location and the height of the carrier in at least one of the ascent or descent of the carrier.

The invention provides systems and devices for an easily replaceable bearing system for a gunner stand of a vehicle. The bearing system reduces vibration from the vehicle on the bearings, decreases wear and tear, and reduces audible rattling. The bearing system includes a shuttle having a backplate and protruding geometry. Biased members are removably attached to the protruding geometry and are configured to create tension on rails of a gunner stand, holding the bearing system within the rails.

The invention provides systems and devices for an easily replaceable bearing system for a gunner stand of a vehicle. The bearing system reduces vibration from the vehicle on the bearings, decreases wear and tear, and reduces audible rattling. The bearing system includes a shuttle having a backplate and protruding geometry. Biased members are removably attached to the protruding geometry and are configured to create tension on rails of a gunner stand, holding the bearing system within the rails.

According to one embodiment, there is taught herein a family of “branched” variants of the traditional scissor mechanism, in which each stage is formed from more than two arms, joined at their midpoints by a branched rivet. In one embodiment arms in adjacent stages are joined at their endpoints with joints that allow for rotation in a single plane. Each resulting mechanism has one degree of freedom in its motion. It deploys from a compact, collapsed state to an extended state. One embodiment is a grasping member that is mechanically coupled to a scissor mechanism so that when scissor mechanism is collapsed the grasping member is open. Then, when the scissor mechanism is extended the grasping member becomes closed.

According to one embodiment, there is taught herein a family of “branched” variants of the traditional scissor mechanism, in which each stage is formed from more than two arms, joined at their midpoints by a branched rivet. In one embodiment arms in adjacent stages are joined at their endpoints with joints that allow for rotation in a single plane. Each resulting mechanism has one degree of freedom in its motion. It deploys from a compact, collapsed state to an extended state. One embodiment is a grasping member that is mechanically coupled to a scissor mechanism so that when scissor mechanism is collapsed the grasping member is open. Then, when the scissor mechanism is extended the grasping member becomes closed.

A lift carrier (10) includes: a carrier frame that is inserted under a vehicle to be transported; a lifting mechanism that lifts and lowers the carrier frame to lift and lower the vehicle; and a carrier body configured to move the carrier frame. The carrier frame includes a rear end frame that includes a pair of arm fixing plates provided so as to protrude outward in a lateral direction of the vehicle from lower surfaces of the side members. The top plate is fixed to the rear end frame, fixes a plurality of rear end arms at such positions that the rear end arms are sandwiched between the top plate and the arm fixing plates, and fixes an upper end face of a lifting unit that is the lifting mechanism.

A vehicle lift assembly having an input shaft, a first ball screw coupled to rotate with the input shaft, a ball screw nut coupled to a first bracket and configured to selectively move a lifting member based on rotation of the first ball screw, and a power unit coupled to the input shaft, the power unit having a wireless transponder and configured to be selectively powered based on wireless signals received by the transponder from a remote device.

A vehicle lift assembly having an input shaft, a first ball screw coupled to rotate with the input shaft, a ball screw nut coupled to a first bracket and configured to selectively move a lifting member based on rotation of the first ball screw, and a power unit coupled to the input shaft, the power unit having a wireless transponder and configured to be selectively powered based on wireless signals received by the transponder from a remote device.

A three-level vehicle lift. The lift includes a four-post configuration in which each post includes a pair of vertically extending, side-by-side channels. Two platforms are provided. Each includes a carriage configured to engage a respective one of the channels in each post and a hydraulic actuator and lifting cable system disposed within the platform for lifting the platform. An actuation system having a single hydraulic pump is provided with a valve for selectively supplying hydraulic power to either an upper- or a lower-platform hydraulic circuit. The simplified lift and actuation system configuration reduces manufacturing, shipping, installation, and materials costs and complexities.

A three-level vehicle lift. The lift includes a four-post configuration in which each post includes a pair of vertically extending, side-by-side channels. Two platforms are provided. Each includes a carriage configured to engage a respective one of the channels in each post and a hydraulic actuator and lifting cable system disposed within the platform for lifting the platform. An actuation system having a single hydraulic pump is provided with a valve for selectively supplying hydraulic power to either an upper- or a lower-platform hydraulic circuit. The simplified lift and actuation system configuration reduces manufacturing, shipping, installation, and materials costs and complexities.