The present invention relates to a flexible conveyor system. The system includes a supply conveyor module and a receiver conveyor module. A hitch mechanism is provided for pivotally coupling the supply conveyor module to the receiver conveyor module about a pivot axis so that the receiver conveyor module receives conveyed material from the supply conveyor module proximal to the pivot axis. Advantageously, the receiver conveyor module receives conveyed material from the supply conveyor module proximal to the pivot axis which impedes spillage between the adjacent conveyor modules on very tight corners.

A material processing unit includes a main frame and a pivot assembly pivotally mounted to the frame. The pivot assembly is movable between a first pivot position, where a portion of the pivot assembly extends below the main frame, to a second pivot position, where the pivot assembly is generally above the main frame. The pivot assembly includes a mount platform that is below the main frame when the pivot assembly is in the first pivot position. The pivot assembly includes a slewing bearing mounted on the mount platform. The pivot assembly also includes a carrier mechanism that is rotatably mounted to the slewing bearing. The carrier mechanism is configured to be rotated generally parallel to the mount platform via the slewing bearing. The material processing unit includes a discharge conveyor that is pivotally mounted to the carrier mechanism.

A conveyor belt unit (100) has a configuration-changing mechanism useful for switching between a ready-to-operate configuration and a not-ready-to-operate configuration. A specific embodiment uses a rotating joint element (150) with a thin material bridge (152) that defines a rotary axis. Used with a dynamic checkweigher, the conveyor belt unit has a carrier frame (110) and a belt body (130) connected to it. Rollers (132, 134) are arranged at the ends in transport direction (T) and contrary to the transport direction, with a conveyor belt (136) tensioned across the conveyor rollers. A motor drives the conveyor belt (136) by means of one of the rollers (132, 134). The configuration-changing mechanism is effective between the belt body and the carrier frame.

Conveyor elevation apparatus, systems and methods are provided. Some embodiments include a stmt having three frame sections. In some embodiments at least two of the frame sections comprise longitudinal supports joined by bracing.

A conveyor for transporting and elevating articles and a method and system for conveying articles up inclines is provided. The conveyor has a conveyor belt and a plurality of support elements extending outward from the article-conveying surface of the conveyor belt advancing upward along the incline. The conveyor may be positioned at an inclined angle relative to the horizontal ground, i.e., between about 5° and 85° or the conveyor can be substantially vertical, i.e., about 90° relative to the horizontal ground. The support elements prevent conveyed articles from sliding down the conveyor belt on the inclined conveyor and carry and hold articles on substantially vertical conveyors. The article-conveying surface of the conveyor belt may provide a low-friction retention surface to articles leaning away from the conveyor belt on the incline.

The present invention refers to a conveyor belt comprising a drive roller with a constant section cylinder and conical tip teeth, a mesh type drive belt, wherein said holes coincide with the teeth of the drive roller and a sliding plate, the drive belt being supported on the sliding plate. Wherein coupling between the drive belt and the teeth allows reducing longitudinal and transversal strain of the mesh type drive belt.

A towable conveyor for transporting and elevating articles and a method and system for towing a conveyor and conveying articles up inclines is provided. The conveyor system has an elevating carriage and a plurality of support elements for conveying articles up the conveyor. Specifically, the towable conveyor system comprises a conveyor having a support frame, a plurality of support elements, a drive end with a motor, and an idle end; an elevating carriage having a first end interconnected to the support frame of the conveyor, a second with two or more wheels, and a support member extending upwardly from the elevating carriage; a cable system for raising the conveyor into a position of use and for lowering the conveyor into a towing position; one or more locking mechanisms; and a hitch for connecting the conveyor to a rear end of a towing vehicle.

A method for operating a baler including an initial step of providing a cleaning system that includes a floor plate having a plurality of slots therein, at least one knife tray, at least one actuator operably connected to the at least one knife tray, and a controller operably connected to the at least one actuator. The method further includes the steps of determining whether the plurality of knives of the at least one knife tray is retracted, determining whether to conduct a knife tray cleanout procedure for cleaning the floor plate based upon at least one cleaning parameter, and conducting the knife tray cleanout procedure by actuating the at least one actuator for cycling the plurality of knives of the at least one knife tray for dislodging debris from the floor plate.

A robotic system having a movable gantry robot (10) for conducting construction operations. The gantry may have an expandable bridge (20) and articulated gantry support legs (34) as well as a support track system (60) holding a gantry robot (800) which may hold one or more implements and peripheral devices (806). The device can be moved by propulsion mechanisms, a controller, and one or more geo-positioned control devices to provide position information for the robotic gantry as it moves back and forth along a plurality of work sites (700). The robotic gantry is connected to a power supply system (236). The controller is automated, self-navigating, and activates, deactivates, and/or changes the operation of the propulsion mechanisms, and deploys, retracts, activates, deactivates, and/or changes the operation of one or more of the construction implements. The height of the frame may be adjusted by extending and rotating risers and booms to accommodate different building heights or sub-level heights at a worksite. A conveyor system is optimized for removing dirt from or delivering material to the robotic arm. This invention can be applied to automating construction jobs including surveying, land preparation, excavation, foundation, masonry, framing, and additive fabrication.

A lift gate apparatus includes a movable conveyor device and a bracket. The movable conveyor device is configured to transition between a conveying position and a ion-conveying position. The bracket configured to bridge a gap between the movable convey or device and a fixed conveyor device, wherein the bracket pivots and slides over the fixed conveyor device when the movable conveyor device is transitioned from the conveying position to the non-conveying position.