An inclination compensating device for a carriage of a conveyor device for the horizontal transport of conveyed material, wherein a drive element is driven via the pivot drive, which drive element is fastened to an end of a pivot lever extending away from the inclination compensating element, which end is opposite the inclination compensating element, and which drive element has a drive axis arranged parallel or perpendicular to the pivot axis, wherein the drive element rolls on at least one guide, in particular extending equidistantly to the pivot axis, in particular in a force-locking or form-locking manner, which guide is mounted or formed on the holding frame.

A method and a central belt system for order-picking articles into order packages transported with a container conveyor, having a central belt which has a conveying direction toward the container conveyor, with the central belt having first and second belt areas in the transverse direction to the conveying direction, and having first and second article chutes associated with the first and second belt areas for ejecting articles into the first and second belt areas. The central belt system has a control in order to eject articles from the first article chutes during a first time window according to a first order and to eject articles from the second article chutes during a second time window according to a second order.

A system for aligning items, which includes a packaging box transfer device to transfer a packaging box accommodating items therein, a fixing device to fix, at a withdrawal position where the items are taken out of the packaging box, the packaging box transferred by the packaging box transfer device with its top open, a withdrawal device to move to a space in which the items are accommodated in the packaging box so as to suck and take out the items, an item transfer device to transfer the items taken out by the withdrawal device with the items placed on the item transfer device, a sensor mounted on the withdrawal device to detect directions of the items taken out by the withdrawal device, and a rotating device to rotate the items taken out by the withdrawal device with the items placed on the rotating device.

A metal casting system includes a master conveyor, a slave conveyor, a cutting device, and a control system. The master conveyor includes a first belt and a first motor, and the slave conveyor is separated from the master conveyor and includes a second belt and a second belt. The cutting device is between the master conveyor and the slave conveyor and selectively cuts a metal product that is conveyed by the master conveyor and the slave conveyor. The control system includes a sensor that detects ends of sections of the metal product as the sections of the metal product move in a downstream direction. The control system also includes a controller communicatively coupled with the sensor. The controller selectively controls at least one of the first motor or the second motor based on the detected ends from the sensor.

Various embodiments described herein relate to techniques for reinforcement learning based conveyoring control. In this regard, a conveyor system is configured to transport one or more objects via a conveyor belt. Furthermore, a vision system comprises one or more sensors configured to scan the one or more objects associated with the conveyor system. A processing device is configured to employ a machine learning model to determine object pose data associated with the one or more objects. The processing device is further configured to generate speed control data for the conveyor belt of the conveyor system based on a set of control policies associated with the object pose data.

An automated biological or chemical sample processing system includes a dock frame and at least one dock frame module. The dock frame includes at least one docking interface that operably couples and interfaces the dock frame with laboratory equipment. The dock frame defines a spine structure of the system alongside which a variable number of laboratory equipment are arrayed. The dock frame extends longitudinally and has a variable elongated configuration and longitudinal length. The at least one dock frame module includes the docking interface, where each module is interchangeable with another module, and has control features with a predetermined relationship to a reference datum of the dock frame module and with a reference datum of the dock frame so that the at least one dock frame module is interchangeably coupled in linear configuration with at least the other dock frame module to select the variable elongated configuration and longitudinal length.

Present embodiments relate to a tie plate orientation device. More specifically, but without limitation present embodiments relate to a tie plate orientation device that orients tie plates in a desired orientation for subsequent feeding, including an optional handheld magnetic device for manual assisted manipulation of the tie plates.

The invention relates to an accumulator device comprising an infeed conveyor with an endless conveying belt arranged for moving products in a first conveying direction, a substantially parallel outfeed conveyor with an endless conveying belt arranged for moving products in a second, opposing conveying direction, a transfer device provided in-between the infeed and outfeed conveyors, configured for transferring products from the infeed conveyor to the outfeed conveyor, the transfer device being moveable along the infeed and outfeed conveyors, wherein the transfer device comprises a first transfer element with first gripping means for horizontally engaging the products, a second transfer element, spaced-apart from the first transfer element, provided with second gripping means for horizontally engaging the products in cooperation with the first gripping means, wherein between the first and second circumference a transfer trajectory is defined, along which a distance between the first and second circumference, perpendicular to the transfer trajectory, is substantially constant and along which the first and second gripping means are arranged to be driven in a same transfer direction, such that a product can be gripped by the first and second gripping means at a gripping location on the infeed conveyor and transported along the transfer trajectory to a release location on the outfeed conveyor.

The present disclosure concerns a transport vehicle for handling a rotor blade mold for the production of a rotor blade of a wind power installation or a shell portion of a rotor blade of a wind power installation, adapted for use in a handling apparatus. The handling apparatus includes a first rail set for displacement of the transport vehicle in a first direction, and a second rail set for displacement of the transport vehicle in a second direction. In addition the transport vehicle includes a first wheel set including a plurality of wheels for movement on the first rail set, and a second wheel set including a plurality of wheels for movement on the second rail set.

A smart moving platform for transport of components in manufacturing includes a vehicle body, a transmission device, a conveying system, a detection device, a tag installation device, a control unit, and a tag reader. The conveying system conveys components. The detection device detects a location of the component and in a first predetermined area, the tag installation device installs and activates a tag on the component. The control unit writes component information to the activated tag and sets a predetermined period. The tag starts to count time elapsing, and the conveyor belt conveys the component to a second predetermined area. The tag reader reads the component information, the elapsed time, and a predetermined period of the tag. When the elapsed time matches the predetermined period, the conveying system sends the component to a third predetermined area.