A step stool or ladder includes a latch that engages a cross member to prevent a step from disengaging from the cross member. The curved end of the latch has a tail that provides additional weight to the end of the latch that engages the cross member and allows for decreased tolerances in manufacturing the latch. The other end of the latch has a knob that extends through an opening in the step so that the latch is accessible and to give visual cues to the user. The knob also maintains the latch in its position in the opening in the step. A bent out portion of the latch midsection serves to limit the amount of travel between the knob and the bent portion. The latch rotates on the portion of the latch between the bent portion and travel limiter and the knob attached to the latch.

A winch utility includes a main body, the main body including a shell, the shell defining an enclosure; an electric motor mounted to and contained within at least a portion of the shell; a controller attached to an inner part of the shell and in electronic communication with the electric motor; and a bobbin coupled to the electric motor; and a cable coupled to the bobbin at a bobbin end, the cable defining a terminal end distal to the bobbin end, the cable arranged to be coiled around the bobbin by rotation of the electric motor, wherein the terminal end of the cable is arranged outside of the shell, wherein the controller is configured to instruct the electric motor.

A winch utility includes a main body, the main body including a shell, the shell defining an enclosure; an electric motor mounted to and contained within at least a portion of the shell; a controller attached to an inner part of the shell and in electronic communication with the electric motor; and a bobbin coupled to the electric motor; and a cable coupled to the bobbin at a bobbin end, the cable defining a terminal end distal to the bobbin end, the cable arranged to be coiled around the bobbin by rotation of the electric motor, wherein the terminal end of the cable is arranged outside of the shell, wherein the controller is configured to instruct the electric motor.

A motorized ladder assembly for ascending and descending from a height safely. The motorized ladder assembly includes an A-shaped frame having a front member and a rear member forming the A-shape. Each front member and the rear member having a pair of parallel rails. The main step is horizontally bridged between the pair of rails of the front member and mounted to a track of a drive mechanism configured for ascending and descending the main step between a top end and a bottom end of the front member. A platform having a base and an upstanding pair of handrails that extends from the ends of the base. The base can be coupled to the main step, such as the base and the main step are coplanar. The pair of handrails run parallel and adjacent to the pair of rails of the front member.

A winch utility includes a shelf connected to a main body, the main body comprising a shell, the shell defining a cable port; an electric motor mounted to the shell; a controller attached to an inner part of the shell and in electronic communication with the electric motor; a bobbin coupled to the electric motor; and a cable coupled to the bobbin at a bobbin end, the cable defining a terminal end distal to the bobbin end, the cable arranged to be coiled around the bobbin by rotation of the electric motor, wherein at least a portion of the cable is arranged within the cable port and wherein the terminal end of the cable is arranged outside of the shell, wherein the controller instructs the electric motor, and wherein motion of the electric motor causes the cable to become one of: coiled around the bobbin and uncoiled from the bobbin.

A winch utility includes a shelf connected to a main body, the main body comprising a shell, the shell defining a cable port; an electric motor mounted to the shell; a controller attached to an inner part of the shell and in electronic communication with the electric motor; a bobbin coupled to the electric motor; and a cable coupled to the bobbin at a bobbin end, the cable defining a terminal end distal to the bobbin end, the cable arranged to be coiled around the bobbin by rotation of the electric motor, wherein at least a portion of the cable is arranged within the cable port and wherein the terminal end of the cable is arranged outside of the shell, wherein the controller instructs the electric motor, and wherein motion of the electric motor causes the cable to become one of: coiled around the bobbin and uncoiled from the bobbin.

A fork for an industrial vehicle such as a forklift, and a method of making the same. The fork includes an elongate body portion, a toe portion, and, optionally, a heel portion. The elongate body portion may be formed in any length and coupled to the toe portion (and optionally, to the heel portion) to form a fork.

A fork for an industrial vehicle such as a forklift, and a method of making the same. The fork includes an elongate body portion, a toe portion, and, optionally, a heel portion. The elongate body portion may be formed in any length and coupled to the toe portion (and optionally, to the heel portion) to form a fork.

An extendable hunting stand includes a post assembly and a platform assembly. The post assembly includes multiple posts, and includes an outer post having an upper end defining an opening, an inner post telescopically arranged within the outer post. The inner post is configured to extend through the opening at the upper end of the outer post. The platform assembly is movable between a lower end and an upper end of the inner post. A lifting assembly automatically moves the platform assembly along the inner post between the lower end and the upper end of the inner post.

An extendable hunting stand includes a post assembly and a platform assembly. The post assembly includes multiple posts, and includes an outer post having an upper end defining an opening, an inner post telescopically arranged within the outer post. The inner post is configured to extend through the opening at the upper end of the outer post. The platform assembly is movable between a lower end and an upper end of the inner post. A lifting assembly automatically moves the platform assembly along the inner post between the lower end and the upper end of the inner post.