A pallet inspection system includes a conveyor to move a pallet that is to be inspected. The pallet includes a top deck and a bottom deck separated by spaced apart support blocks positioned therebetween, with nails being used to secure the top and bottom decks to the support blocks. Cameras are positioned to generate images of the pallet as the pallet is moved on the conveyor. A processor is coupled to the cameras and receives the images for processing. The processing includes executing a first algorithm on the images to tag the images having support blocks visible therein, and executing a second algorithm on the tagged images to detect nails having exposed tips.

A system and method for operating robotic pallet transportation carts and providing uniform spacing between pallets of goods, to improve the vertical alignment of the gaps between the pallets of a multilevel commercial warehouse rack. Indicators are positioned along a storage lane, such as on side walls of cart support rail structures, on the left and/or right sides with respect to the pallet transportation cart. The cart has one or more sensors (optical, magnetic and otherwise), such as on a side of the cart to detect the indicators on the side of the lane. The cart is programmed to count the indicators and lower the pallet of goods after sensing a selected indicator number. By spacing the indicators an appropriate distance apart, the pallets can be arranged to have vertically aligned gaps, even if there are minor variations in the length of pallets of goods.

The present disclosure provides a substrate treating apparatus capable of stably moving a substrate and discharging an ink at an accurate position. The substrate treating apparatus of the present disclosure comprises: a stage extending in a first direction and moving a substrate along the first direction; moving units disposed on both sides of the stage extending in the first direction, respectively, and configured to move the substrate in the first direction; and a control unit configured to align the substrate, wherein the moving unit includes a first gripper and a second gripper configured to adsorb one side and the other side of the substrate, respectively, after the first gripper adsorbs one side of the substrate, the control unit aligns the substrate, and after the substrate is aligned, the second gripper adsorbs the other side of the substrate and the substrate is moved in the first direction.

Production system for series production of in particular motor vehicles, includes a container storage area storing containers containing components for production, production shelves, remote from container storage area, from which workers remove components from containers. Transport for transporting containers from container storage area to production shelves. Transport has automated guided vehicle (AGV) on which transport shelf is situated and designed so containers are automatically delivered from transport shelf to production shelves in a conveying direction (delivery direction). Handling device situated on AGV, has a base body and a handling unit situated on base body. Handling unit removes containers from transport shelf in conveying direction and delivering containers to production shelf. Relative to base body, handling unit is linearly adjustable along first linear adjustment axis in conveying direction, along a second linear adjustment axis transverse to conveying direction, height-adjustable along a third adjustment axis, and rotatable about vertical fourth adjustment axis.

The present disclosure provides a warehouse robot control method and apparatus, a device and a readable storage medium. According to the method of the present disclosure, before a carrying task is executed, image data of a target storage location is acquired through an image acquisition apparatus, whether an execution condition of a carrying task is satisfied is determined according to the image data of the target storage location, and in a case that the execution condition of the carrying task is satisfied, that is, no danger may happen during execution of the carrying task by a carrying apparatus, the carrying apparatus is controlled to execute the carrying task. The occurrence of danger is avoided and the safety of warehouse robots is improved.

In a clamping device, the number of components for an article detection means is reduced. In a stacker, a tire is placed on the carry surface. The first gripping member and the second gripping member grip a side of tire placed on the carry surface and include an abutment surface having a bent portion and are capable of abutting with the side of tire. The first sensor and the second sensor include a light axis in a direction along the article. The controller moves the first gripping member and the second gripping member close to each other to the first position where the tire is not gripped. When the tire is detected with the first sensor and second sensor, the controller moves the first gripping member and the second gripping member close to each other to the second position where the tire is gripped.

The invention relates to a handling device and/or layer forming device (10) and a method for forming piece good layers. Piece goods (14, 14a) are conveyed on a horizontal conveying device (16) to a grouping station and/or layer forming station (12) comprising a manipulator (20). In a work cycle the manipulator (20) seizes at least one piece good (14, 14a) and moves it into a defined relative target position and/or target alignment, in particular with regard to a piece good layer to be formed.

The horizontal conveying device (16), which is arranged upstream of the grouping station and/or layer forming station (12) in the transport direction (18) of the piece goods (14, 14a), comprises at least one sensor device (24) for obtaining positional data and/or dimensional data and/or alignment data of the transported piece goods (14, 14a). Electronic output signals (26) are generated from the obtained data, which processed in a control device (28). The control device (28) controls the movements of the manipulator (20) within the movement range (22) for the purpose of the layer formation.

An object processing system is disclosed for dynamically providing the removal of objects from a trailer of a tractor trailer. The object processing system includes a load assessment system for assessing a load characteristic of a plurality of objects within the trailer and for providing load assessment data representative of the load characteristic, an object assessment system for assessing a relative position and relative environment of an object of the plurality of objects responsive to the load assessment data, and for providing object assessment data for the object, and a dynamic engagement system for dynamically engaging the objects within the trailer with either of at least two cooperatively operable programmable motion devices responsive to the object assessment data.

A robotic line kitting system is disclosed. In various embodiments, a signal associated with an unsafe condition is received via a communication interface. In response to the signal, a controlled operation to reduce a speed of movement of a robotic instrumentality is performed prior to a safety stop of the robotic instrumentality being triggered.

A goods picking apparatus includes a goods picking assembly, a sensor, and a depth determining module; the sensor is provided on the goods picking assembly and configured to collect a measurement signal when the goods picking assembly extends; the depth determining module is configured to determine a depth of a goods container according to the measurement signal; and the goods picking assembly is configured to pick or place the goods container according to the depth of the goods container, where the depth is a length of the goods container in an extension direction of the goods picking assembly during goods picking.