A mobility carrier apparatus for vehicles includes: a carrier to store a mobility, and the carrier is not exposed at ordinary times and withdrawn when it is desired to use the mobility, thereby improving the external design of a vehicle and convenience of the vehicle. In particular, the carrier slides along a pair of sliding rails so as to be withdrawn from or stored in a case of the mobility carrier apparatus, and the carrier is provided with a storage unit in which the mobility is loaded. The mobility is lifted upwards at the time of withdrawal of the carrier.

A mobility carrier apparatus for vehicles includes: a carrier to store a mobility, and the carrier is not exposed at ordinary times and withdrawn when it is desired to use the mobility, thereby improving the external design of a vehicle and convenience of the vehicle. In particular, the carrier slides along a pair of sliding rails so as to be withdrawn from or stored in a case of the mobility carrier apparatus, and the carrier is provided with a storage unit in which the mobility is loaded. The mobility is lifted upwards at the time of withdrawal of the carrier.

A wheel jack holder for a vehicle may include a holder base having at least one sliding member formed at each of first and second side portions of the holder base, whereby a wheel jack is configured for being placed on the holder base; and a pair of holder arms, each having a sliding rod formed at a first surface thereof, wherein the sliding rod is slidably inserted into a hole of the sliding member. The pair of holder arms may move away from each other when receiving force from the wheel jack to be fixed to a wheel rim of a wheel.

A scissors-type jack includes a jack body, a gear box, a motor and a battery pack. Upper ends of lower supporting arms of the jack body are respectively hinged to lower ends of upper supporting arms of the jack body through hinge shafts. The gear box includes a base, a housing, and first and second gears. The base is fixedly mounted with one hinge shaft. A gear transmission shaft of the first gear is rotatably arranged on the base and meshed with the second gear. The second gear is connected to a screw rod of the jack body. The motor is mounted on a side of the base, and a motor gear shaft penetrates through the base and is meshed with the first gear. The control board is disposed on an outer side of the battery pack and electrically connected to the battery pack and the motor.

A scissors-type jack includes a jack body, a gear box, a motor and a battery pack. Upper ends of lower supporting arms of the jack body are respectively hinged to lower ends of upper supporting arms of the jack body through hinge shafts. The gear box includes a base, a housing, and first and second gears. The base is fixedly mounted with one hinge shaft. A gear transmission shaft of the first gear is rotatably arranged on the base and meshed with the second gear. The second gear is connected to a screw rod of the jack body. The motor is mounted on a side of the base, and a motor gear shaft penetrates through the base and is meshed with the first gear. The control board is disposed on an outer side of the battery pack and electrically connected to the battery pack and the motor.

The present invention provides a double parallelogram vertical lifting device comprising a linkage mechanism and a pushing device. The linkage mechanism comprises a first shaft seat, a second shaft seat, a third shaft seat, an upper support unit movably coupled to the first shaft seat and the second shaft seat on both ends, and a lower support unit movably coupled to the second shaft seat and the third shaft seat on both ends. The upper support unit is provided with a first gear, and the lower support unit is provided with a second gear that meshes with the first gear. The pushing device has one end set on the upper support unit and the other end set on the lower support unit. The invention utilizes the interaction of the first gear and the second gear to generate a reaction force, which enables the lower support unit to cooperate with the upper support unit to move up and down synchronously, and achieves the effect of simple structure and large load capacity.

The present invention provides a double parallelogram vertical lifting device comprising a linkage mechanism and a pushing device. The linkage mechanism comprises a first shaft seat, a second shaft seat, a third shaft seat, an upper support unit movably coupled to the first shaft seat and the second shaft seat on both ends, and a lower support unit movably coupled to the second shaft seat and the third shaft seat on both ends. The upper support unit is provided with a first gear, and the lower support unit is provided with a second gear that meshes with the first gear. The pushing device has one end set on the upper support unit and the other end set on the lower support unit. The invention utilizes the interaction of the first gear and the second gear to generate a reaction force, which enables the lower support unit to cooperate with the upper support unit to move up and down synchronously, and achieves the effect of simple structure and large load capacity.

A stabilizing jack includes a base securable to a vehicle frame with a drive screw rotatably mounted to the base and a screw follower threadingly secured to the drive screw. A length adjustable lift leg is pivotally connected at an upper end to the screw follower. A stabilizing member is pivotally connected at a first end to the base inward from the screw follower. The lift leg is pivotally connected at an outer end to the stabilizing member. Downward extension of the lift leg through outward advancement of the screw follower on the screw and downward pivoting of the lift leg by the stabilizing member advances the foot into the ground to raise the vehicle frame relative to the suspension. The extended lift leg and stabilizing member form a triangle with the base providing resistance to lateral movement of the vehicle frame relative to the wheels and suspension.

A stabilizing jack includes a base securable to a vehicle frame with a drive screw rotatably mounted to the base and a screw follower threadingly secured to the drive screw. A length adjustable lift leg is pivotally connected at an upper end to the screw follower. A stabilizing member is pivotally connected at a first end to the base inward from the screw follower. The lift leg is pivotally connected at an outer end to the stabilizing member. Downward extension of the lift leg through outward advancement of the screw follower on the screw and downward pivoting of the lift leg by the stabilizing member advances the foot into the ground to raise the vehicle frame relative to the suspension. The extended lift leg and stabilizing member form a triangle with the base providing resistance to lateral movement of the vehicle frame relative to the wheels and suspension.

A cabinet lifting assembly for lifting overhead cabinets for installation includes a scissor lift that is positionable between a lifted position and a lowered position. The scissor lift includes a base, a top, a pair of scissors and a screw extending between the scissors. A fitting is coupled to the screw to be engaged by a chuck on a drill thereby facilitating the screw to be rotated in the first direction or the second direction. A panel is coupled to the top of the scissor lift. A support is coupled to the panel such to have an overhead cabinet positioned thereon thereby facilitating the scissor lift to lift and lower the overhead cabinet for installation.