The invention relates to a device and a method for controlling a steep conveyor, comprising a control unit (15), a conveyor drive system (5) for driving a conveyor belt (2), and a sensor unit for determining a weight G.sub.1-n of the material to be conveyed (4) assigned to a predetermined section T.sub.1-n of the conveyor belt (2), wherein the sensor unit is adapted to transmit information about the weight to the control unit (15), wherein the control unit (15) is adapted to determine from the information about the weight G.sub.1-n a length L.sub.1-n assigned to the predetermined section T.sub.1-n in a steep conveyor region S of the conveyor belt (2) and to adjust a strain of a drive belt (2) of the conveyor drive system (5) based on the determined lengths L.sub.1-n assigned to the predetermined sections T.sub.1-n.

Wheel chock systems for use at loading docks and other locations are described herein. In some embodiments, the wheel chock systems can include a wheel chock assembly that is positionable in contact with a vehicle wheel to restrain the vehicle at a loading dock. The wheel chock assembly can include a sensor target, and a corresponding sensor can be mounted to, for example, an outer wall of the loading dock or a wheel chock storage cradle mounted to the outer wall. In operation, the sensor can emit a wireless signal (e.g., an electromagnetic signal) that is reflected off of the sensor target and received back by the sensor when the wheel chock has been positioned in a blocking relationship relative to the vehicle wheel to restrain the vehicle at the loading dock. The sensor can be operably connected to a loading dock signal system (e.g., a signal light system) that displays appropriate signals to loading dock personnel based on detection of proper wheel chock placement. In other embodiments, wheel chock systems can include other types of devices for wirelessly communicating wheel chock placement information to loading dock systems. Such device types can include, for example, Bluetooth, Wi-Fi, RFID, etc.

An optical fiber temperature distribution measurement system includes a temperature difference calculator configured to calculate a temperature difference between corresponding spatial resolution zones based on a first temperature distribution obtained by a return light from a first optical fiber part and a second temperature distribution obtained by a return light from a second optical fiber part, and an abnormality detector configured to calculate a temperature difference for evaluation for each spatial resolution zone, the temperature difference for evaluation being a sum of a temperature difference of each spatial resolution zone and a temperature difference of a spatial resolution zone adjacent thereto, and to determine that an abnormality has occurred in a roller near the spatial resolution zone when the calculated temperature difference for evaluation exceeds a reference value.

A shoe sorter is described. The shoe sorter can include a switch plate that supports movement of a shoe pin of a pusher shoe, a finger, and an actuation arm. In some examples, the finger can be configured to be moved in a first direction in response to a portion of the shoe pin contacting a portion of the finger. The actuation arm can be pivotably engaged to the finger so that a movement of the finger in the first direction can cause a movement of the actuation arm in a second direction. In this regard, the actuation arm in the second direction can cause a change in a signal outputted by the photoelectric sensor coupled to the shoe sorter. This change in the signal can be used by a processor to determine that the shoe pin is misaligned.

An apparatus and a method convey and sort articles. The apparatus contains a link conveyor, having link elements, pushing-off elements, drive elements, and a control device. The link conveyor runs along a belt-movement line and has along the belt-movement line the link elements which are arranged to follow one after the other and form a conveying surface for the articles. In each case one pushing-off element can be arranged on one of the link elements, above the conveying surface, and therefore the pushing-off element runs along the belt-movement line together with the link element, and the pushing-off element can be moved, and stopped, along a pushing-off-line, which is arranged transversely to the belt-movement line. The drive elements each drive one or more pushing-off elements individually, and therefore the operations of moving and stopping these pushing-off elements, which are arranged to follow one after the other, are independent of one another.

Shipment receiving systems and methods are disclosed. Invoice and store inventory management data is provided to an invoice processor for assigning expected destinations to lanes of a material transporter having and a plurality of outlet lanes that each have an indicator. A scanner determines a case identifier for each case which is routed accordingly. One or more notifications is provided to the indicator of one or more of the plurality of outlet lanes. Received shipment data enables reconciliation of upstream supply change management systems and downstream store inventory systems.

A transport device for transporting workpieces which preferably consist, at least in part, of wood, wood materials, plastics material, or the like, comprises, according to this application, a transport apparatus which is configured such that it can move along a first direction, and wherein the transport apparatus comprises a marking which comprises a pattern along the first direction.

A method for targeted detection and segregation of individual piece goods being conveyed in a conveying direction on an extensive conveying element. A position-determining device detects positional information of the piece good to be segregated. The piece good to be segregated is displaced transversely to the conveying device by a push element, which is moved transversely to the conveying direction into the conveying region of the piece goods. Before pushing of the piece good, the push element is now moved into a forward position that lies above the conveying element in the conveying region. The piece good is subsequently pushed by the push element over the conveying element by way of accelerating the push element out of the forward position in a push direction. The forward position is set by a control device depending on positional information concerning the piece good to be segregated on the conveying element.

A belt scraper having a scraper element to be brought into abutment with a belt. The scraper element is pivotably arranged with reference to a pivoting axis. A spring element generates a torque acting on the scraper element. A sensor for determining a pivoting angle of the scraper element is a contactless sensor with an index part and a detecting part for detecting the position of the index part. The index part is arranged, at a distance from the pivoting axis, on a movable element that is coupled to the scraper element.

Devices, systems, and methods for determining whether a container is empty in the context of robotic picking solutions. The system includes a plurality of sensors configured to gather container data regarding a container at a first location, wherein the container data includes at least two of weight data related to the container, depth data related to the container, and color sensor data related to the container, and a processor configured to execute instructions stored on a memory to provide a sensor fusion module configured to process the received container data to determine whether the container is empty.