A movable modular truck toolbox mounting lift system for lifting and repositioning a modular accessory (e.g., toolbox, container, cooler, platform) of a vehicle (e.g., truck, UTV) to enable access to the modular accessory without requiring an entry into the vehicle, a vehicle storage area, or a truck bed. The system has driver side and passenger side support plates pivotably connected to a pair of arms, which are in turn pivotably connected to each other to and upon movement (extension) of one arm pair, the modular assembly transits up and backward within the storage area. The system may be operated via actuators and/or motors to rotate the arms and lift/reposition the modular accessory. The modular accessory may be a toolbox, cabinetry toolbox, or a tray for receiving a plurality of modular accessories. A method of installing and using the system to lift and reposition a modular accessory in a vehicle.

Provided are an adjusting base and a self-driven robot. The flexible base includes: a chassis, a carrying plate and an adjusting mechanism. The bottom of the chassis is provided with at least one second driven wheel and at least two driving wheels. The bottom of the carrying plate is provided with at least a first driven wheel. The adjusting mechanism is configured to connect to the carrying plate and the chassis or connect to the carrying plate and the second driven wheel. When the ground is uneven, the adjusting mechanism is configured to dynamically adjust the second driven wheel in such a manner that the first driven wheel, the second driven wheel and the driving wheels are in contact with the ground.

A self-contained truck-mounted brick laying machine (2) is described. A truck (1) supports the brick laying machine (2) which is mounted on a frame (3) on the truck chassis. The frame (3) supports packs or pallets of bricks (52, 53) placed on a platform (51). A transfer robot can then pick up an individual brick and move it to, or between either a saw (46) or a router (47) or a carousel (48). The carousel is located coaxially with a tower (10), at the base of the tower (10). The carousel (48) transfers the brick via the tower (10) to an articulated (folding about horizontal axis (16)) telescoping boom comprising first boom element in the form of telescopic boom (12, 14) and second boom element in the form of telescopic stick (15, 17, 18, 19, 20). The bricks are moved along the folding telescoping boom by linearly moving shuttles, to reach a brick laying and adhesive applying head (32). The brick laying and adhesive applying head (32) mounts to element (20) of the stick, about an axis (33) which is disposed horizontally. The poise of the brick laying and adhesive applying head (32) about the axis (33) is adjusted and is set in use so that the base (811) of a clevis (813) of the robotic arm (36) mounts about a horizontal axis, and the tracker component (130) is disposed uppermost on the brick laying and 110,111 adhesive applying head (32). The brick laying and adhesive applying head (32) applies adhesive to the brick and has a robot that lays the brick. Vision and laser scanning and tracking systems are provided to allow the measurement of as-built slabs, bricks, the monitoring and adjustment of the process and the monitoring of safety zones. The first, or any course of bricks can have the bricks pre machined by the router module (47) so that the top of the course is level once laid.

An automated guided vehicle (AGV) that is configured to operate with a navigation and guidance system includes a base frame structure that supports a material handling apparatus. Casters may be attached at peripheral portions of the base frame structure to movably support the base frame structure away from a ground surface. Drive wheel assemblies may be disposed between two of the casters and configured to propel and steer the AGV. A suspension system may have intersecting swing arms that are pivotally mounted at the base frame structure and independently attach at each of the drive wheel assemblies. The suspension system biases the drive wheel assemblies against the ground surface to maintain friction of the drive wheel assemblies against the ground surface, such as for traversing sloped or uneven surfaces.

An automated guided vehicle (AGV) that is configured to operate with a navigation and guidance system includes a base frame structure that supports a material handling apparatus. Casters may be attached at peripheral portions of the base frame structure to movably support the base frame structure away from a ground surface. Drive wheel assemblies may be disposed between two of the casters and configured to propel and steer the AGV. A suspension system may have intersecting swing arms that are pivotally mounted at the base frame structure and independently attach at each of the drive wheel assemblies. The suspension system biases the drive wheel assemblies against the ground surface to maintain friction of the drive wheel assemblies against the ground surface, such as for traversing sloped or uneven surfaces.

A multi-panel deck side extender system including a deck rail assembly and a deck side extender assembly. The deck rail assembly includes a rail extending in a vehicle longitudinal direction and a bracket connected to the rail. The rail is secured to a sidewall of the pickup truck. The deck side extender assembly pivotally connects to the bracket. The deck side extender assembly is slidably displaceable in the vehicle longitudinal direction with respect to the rail. The deck side extender assembly is pivotally displaceable between a lowered position and a raised position. In the lowered position the deck side extender assembly is positioned below the upper surface sidewall in a vehicle vertical direction and adjacent the interior surface of the sidewall in a vehicle lateral direction. In the raised position the deck side extender assembly is positioned above the upper surface of the sidewall in the vehicle vertical direction.

The invention is an apparatus and method for lifting objects onto the bed of a pick-up truck. The device includes (1) a rack assembly, (2) a swing arm assembly, and (3) at least one hydraulic arm. The invention can be optimized and adapted to fit on a standard pick up truck or a flat bed truck.

The invention is an apparatus and method for lifting objects onto the bed of a pick-up truck. The device includes (1) a rack assembly, (2) a swing arm assembly, and (3) at least one hydraulic arm. The invention can be optimized and adapted to fit on a standard pick up truck or a flat bed truck.

A method and an arrangement for optimizing load position in relation to a transportation vehicle, comprising a platform arranged to the transportation vehicle for receiving a load; an actuating device for moving the platform in relation to the transportation vehicle; a sensing device configured to generate a vehicle sensing signal and/or a non-vehicle sensing signal; a controlling device configured to receive at least one of the vehicle sensing signal and the non-vehicle sensing signal; generate controlling commands based on the received at least one of the vehicle sensing signal and the non-vehicle sensing signal; and transmit the controlling commands to the actuating device; wherein the actuating device is configured to receive the controlling commands and to move the platform in relation to the transportation vehicle based on the controlling commands.

Embodiments of the present invention include a method and system for blending multi-component granular compositions such as proppant used in hydraulic fracturing in well drilling. The system includes the control and management of an on-site storage system for each of the components, regulating the delivery of specified quantities of each component to a well site, and coordinating the flow of materials into and out of the blender.