A lift machine includes a base having a first end and a second end, a first assembly, and a second assembly. The first end has first and second pivot points defining a first lateral axis. The second end has third and fourth pivot points defining a second lateral axis. The first assembly is pivotably coupled to the first and second pivot points. The first assembly extends away from the base in a first direction such that first and second tractive elements are longitudinally offset from the first lateral axis and spaced from the first end of the base. The second assembly is pivotably coupled to the third and fourth pivot points. The second assembly extends away from the base in a second direction such that third and fourth tractive elements are longitudinally offset from the second lateral axis and spaced from the second end of the base.

A vehicle engagement structure for towing transport devices is disclosed, wherein a carrier is configured with respectively an engagement towage mechanism and a drive mechanism; more specifically, the engagement towage mechanism includes an external spiral transmission component and an internal spiral transmission component, the internal spiral transmission component is further mutually in spiral engagement with a spiral rod, and the top end of the spiral rod is sequentially installed with an up-and-down pedestal, a rotation seat, an engagement base and an engagement end applied to connect to a transport device; in addition, the drive mechanism is configured to control the up-and-down pedestal to vertically ascend or descend on the spiral rod, thereby facilitating the engagement end to adapt to the height of the transport device or topographic fluctuations and variations during movement.

A load lifting and carrying apparatus that has a base with a distal end designed to horizontally couple to a vehicle frame. A dividable vertical frame has a top and a bottom end, the bottom end coupled to a proximal end of the base and supported by a horizontal bracket support. The upper portion of the vertical frame is narrower than and designed to slide at least partly into the lower portion, at least one pair of holes aligned on the upper and lower portion and coupled by at least one bolt assembly. A vertically foldable cantilevering coplanar arm is coupled to a proximal and distal rotatable pully assembly, the middle portion of the coplanar arm assembly removably coupled to a support arm. A winch assembly mounted to the lower portion of the vertical frame is designed to pull a cable over the pulleys to provide a lifting force for towing.

A suspension and hub engagement towing facilitating assembly includes a receiver having a top side that removably receives a hub of a vehicle. A pair of catches is attached to the receiver at opposite ends thereof. The catches releasably receive tow bars such that the receiver is positioned between and liftable with the tow bars.

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.

The present invention discloses a positive azimuth towing guidance method for road rescue equipment based on license plate corner features. The method combines a structure of the road rescue equipment and characteristics of a positive azimuth towing operation. First, an image of an operation area is collected by installing a camera, and grayscale processing and Gaussian smooth filtering are performed on the image; corner detection is performed on the smoothed grayscale image, and preference is implemented according to corner strengths; hierarchical clustering is performed on the preferred corners; an effective corner set of license plate characters is sorted out to implement license plate locating; and then towing guidance is implemented according to a license plate locating result, to improve the rescue efficiency of the road rescue equipment. The guidance method provided in the present invention has good real-time performance, environmental adaptability and anti-interference ability, thereby effectively improving the rescue efficiency of the road rescue equipment.

A towing attachment is designed to facilitate the towing of bobtail trucks and similar vehicles. The towing attachment includes a tube, a hitch attachment body, a first mounting bracket, a second mounting bracket, a first locking mechanism, and a second locking mechanism. The tube is preferably a rectangular, tubular, structure that receives the first mounting bracket and the second mounting bracket. The hitch attachment body is an assembly that allows attachment onto the hitch feature of a bobtail truck or other similar vehicle. The first mounting bracket and the second mounting bracket allow engagement to a wheel lift of a towing vehicle. The first locking mechanism maintains the first mounting bracket in place along the tube. The second locking mechanism maintains the second mounting bracket in place along the tube.

A boom lift includes a base having a first end and an opposing second end, a turntable coupled to the base, a boom coupled to the turntable, an assembly pivotably coupled to the first end of the base, and a first actuator coupled to the first end of the base and the assembly. The assembly includes a tractive element. The assembly extends from the base such that the tractive element is longitudinally offset from and spaced forward of the first end and the opposing second end of the base.

A recovery system for recovering wrecked vehicles in difficult-to-access locations generally includes a frame, a front plate, a rear plate with a mounting system for mounting the recovery system to an operating vehicle, a guide shaft and guide wheel, a boom assembly, a horse head assembly mounted in a cable sleeve in a pivot end of the boom assembly, a winch, and a cable running from the winch over and along the boom and through the horse head assembly. The horse head assembly generally includes a clevis, a clevis pin, a sheave wheel, and a cable guide. The clevis preferably rotates within the cable sleeve with respect to the boom assembly, the cable guide preferably pivots on top of the boom assembly, and the sheave wheel and cable guide preferably freely rotate on the clevis pin and preferably translate along the clevis pin.

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.