A remotely adjustable automotive lift arm allows a user to position lift arms under the vehicle, extend them to the correct length, and position lifting pads to the correct location and height, all without requiring the user to bend over or kneel. The remotely adjustable automotive lift arm includes a telescopic arm, a screw jack assembly, a camera assembly, a gear assembly, and an input shaft. The telescopic arm includes two tubes with one being telescopically engaged to the other. The screw jack assembly is used to adjust the lifting pad height to achieve a level lift of a vehicle prior to the vehicle being lifted off the ground. The camera assembly provides a live image of the vehicle's undercarriage in order to precisely position the screw jack assembly. The input shaft can receive an input torque than can be transferred to the screw jack assembly by the gear assembly.

A remotely adjustable automotive lift arm allows a user to position lift arms under the vehicle, extend them to the correct length, and position lifting pads to the correct location and height, all without requiring the user to bend over or kneel. The remotely adjustable automotive lift arm includes a telescopic arm, a screw jack assembly, a camera assembly, a gear assembly, and an input shaft. The telescopic arm includes two tubes with one being telescopically engaged to the other. The screw jack assembly is used to adjust the lifting pad height to achieve a level lift of a vehicle prior to the vehicle being lifted off the ground. The camera assembly provides a live image of the vehicle's undercarriage in order to precisely position the screw jack assembly. The input shaft can receive an input torque than can be transferred to the screw jack assembly by the gear assembly.

A scissor jack kit to elevate each vehicle quadrant for maintenance including one scissor jack for each wheel. Each scissor jack includes a parallelepiped bottom base, a lower support base atop thereof, and mirror image first and second arms, each having top and bottom ends hinged at a central elbow. Each of proximal and distal ends of the bottom and top ends, respectively, pivotably couples to the respective lower and upper support base. An aperture in the central elbow receives a rotatable leadscrew therethrough having a socket with a hole which receives a hook of a jack speed crank handle to rotate the leadscrew to adjust the scissor jack height. Mount holes in the upper support base provide for chassis mounting. A groove in an axle mount body on the upper support base supports the axle proximal the respective wheel and has a cushioned lining thereon.

A portable aircraft maintenance stand includes a frame assembly and a deck. The frame assembly has a base portion and an upper portion. The deck is mounted to the upper portion of the frame assembly and includes a cantilevered portion. The deck also has a gap configured to receive an engine of an aircraft such that the deck at least partially wraps around the engine. The cantilevered portion of the deck is configured to be positioned vertically above a wing of the aircraft while the base portion of the frame assembly is positioned vertically below the wing.

The present disclosure provides a support system comprising a post, said post extending upward vertically from a pad and further comprising upper and lower ends, wherein said lower end is secured to a lower flange; and a joist flange secured to the post opposite the lower flange; wherein the lower flange is secured to the post via a frictional fit.

A bin tipper includes a vertical support column, a cam track adjacent to the vertical support column, a structural member mounted to and configured to translate along the vertical support column, and a gripper assembly including a gripper mount having gripper arms mounted thereon that are configured to receive and hold a collection bin. The cam track includes a proximal portion parallel to the vertical support column and a distal portion provided at an angle with respect to the vertical support column. A first end of the gripper mount is pivotally mounted to the structural member and a second end of the gripper mount includes a cam follower extending therefrom that is configured to move within the proximal and distal portions of the cam track. The gripper assembly lifts and inverts the collection bin based on a position of the cam follower of the gripper mount within the cam track.

A system includes a platform having an upper surface and defining a recess having a floor, the recess configured to seat a dish, and a movable securing frame that is movably connected with the platform, the frame including a lift support having an upper surface that is movable along a path from a first location that is beneath the floor of the recess, through the recess, to a second location that is coplanar with the upper surface of the platform. A motor configured to cause oscillation of the platform and the movable securing frame can be used. A method of using the system can include placing a dish above a recess defined by an upper surface of a platform, and lowering the frame with respect to the platform, thereby seating the dish within the recess.

A floor jack may include a base, and a threaded pillar threadingly coupled to the base. The threaded pillar may include a dome top surface. The floor jack may also include a pedestal. the pedestal may include concave portion, and the concave portion may include a mating curvature relative to the dome top surface of the threaded pillar.

A grinding mill for pulverizing material includes a platform having an upper surface and defining a recess having a floor, the recess configured to seat a dish in which the material is disposed, and a movable securing frame that is movably connected with the platform, the frame including a lift support having an upper surface that is movable along a path from a first location that is beneath the floor of the recess, through the recess, to a second location that is coplanar with the upper surface of the platform. A motor configured to cause oscillation of the platform and the movable securing frame can be used. A method of using the grinding mill can include placing a dish above a recess defined by an upper surface of a platform, and lowering the frame with respect to the platform, thereby seating the dish within the recess.

A carrying mobile robot includes a frame, a suspension system disposed at the bottom of the frame, and a lifting mechanism disposed on the frame. The suspension system includes two suspension mechanisms disposed on the left and right sides, each of which includes a supporting beam, a driving wheel, a connecting member and a first driven wheel. The first driven wheel and the driving wheel respectively support the front and rear ends of the supporting beam, and the connecting member is connected to the supporting beam and located between the driving wheel and the first driven wheels. The lifting mechanism includes a plurality of lifting members, a first driving system for driving the lifting member and a transmission system for transmitting the driving force of the first drive system to the lifting members.