Methods and systems for sorting hides are provided. In particular, one or more embodiments comprise a tanning control system that enhances the traceability of hides by capturing and utilizing data related to the unloading, tanning, sorting, and packaging of hides. Furthermore, one or more embodiments enable the tanning control system to improve efficiency by sorting hides based, at least in part, on data generated during prior tanning processes. Additionally, one or more embodiments facilitate the tanning control system in customizing the sorting and packaging of hides based, at least in part, on one or more hide characteristics and/or customer specifications.

A control device for a conveyor device, comprises a control unit adapted to generate control signals for a conveyor device, a data interface adapted for signal transmission of control signals to the control unit, a first power interface adapted for power supply to the control unit, a connection interface adapted for establishing a signal control connection and a power supply connection between the control unit and a conveyor device located outside the control device. A second power interface is adapted to supply power to the control unit, the first interface being adapted to receive a power supply in the form of a power supply with a first voltage, the second interface being adapted to receive a power supply in the form of a power supply with a second voltage or, instead of the second voltage, with a third voltage whose level is different from the level of the second voltage.

A conveying system transports items, such as postal items, along a main conveying direction. A conveying route includes segments that are arranged one behind the other along the main conveying direction. The segments have conveyors arranged parallel to one another and the segments are offset relative to one another in a transverse direction. The conveyors are driven and activated individually by a control unit. The items are conveyed along the main conveying direction by transferring an item from a preceding segment to a following segment that is offset relative to the preceding segment and then transporting the item on the following segment. Items with small dimensions, which rest on just one conveyor can also be manipulated during the transportation.

A processing system is disclosed for processing objects. The processing system includes a perception system for providing perception data regarding an object, and a primary transport system for providing transport of the object along a primary direction toward a processing location that is identified based on the perception data.

There is provided a conveyor assembly for sorting merchandise items. In one form, the conveyor assembly includes: a merchandise identification module; sortation modules each comprising a multi-directional sorting portion with two sets of rollers, a first wing including a third set of rollers, a second wing including a fourth set of rollers, and a controller configured to receive an IP address; a first, disassembled state of the sortation modules; a second, assembled state of the sortation modules; a merchandise database; and a control circuit configured to receive identifying information about an unsorted merchandise item, assign a unique IP address to each sortation module corresponding to the position of the sortation module, determine a sortation destination for the unsorted merchandise item, determine the sortation module corresponding to the sortation destination; and instruct the controller of the corresponding sortation module to divert the unsorted merchandise item to the sortation destination.

A system for coordinated laser marking of mid-conveyance food includes a controller, multiple lasers, and one or more industrial components. The lasers are in network communication with the controller. The controller can send a first instruction set, having a first language, to a first laser, and a second instruction set, having a second language different from the first language, to a second laser, the first laser associated with a first conveyor of multiple conveyors, and the second laser associated with a second conveyor different from the first conveyor. During operation, the first laser applies a marking to a first product as the first product is conveyed along the first conveyor, based on the first instruction set. Also during operation, the second laser applies the marking to a second product as the second product is conveyed along the second conveyor, based on the second instruction set.

Transport of physical objects is controlled based on scanning of encoded images. In one approach, an encoded image on a physical object is scanned to obtain parameters. The parameters include specifications for a product to be made by a manufacturing process. One or more rules are generated using the parameters and then stored in a database. The database is queried to determine whether the product conforms to the one or more rules. For example, the query may include data regarding characteristics of the final product and/or the manufacturing process. In response to determining that the product conforms to the rules, the product is transported to a distribution facility.

A work process management system includes at least one work device and a tag type individual controller that is directly or indirectly attached to a work object to control the work device. Each of the work device includes a work-device-side communicator, a work part, and a work-device-side control part. The tag type individual controller includes an individual-controller-side storage in which a work content of a work process performed with the work device is stored, an individual-controller-side communicator, and an individual-controller-side calculation controller that transmits the work content of the work process performed with the work device in which a performance result is reflected to the work-device-side communicator, and additionally stores the received performance result in the individual-controller-side storage.

A cart having a wheel, a drive motor coupled to the wheel such that an output of the drive motor causes the wheel to rotate and propel the cart, a cart-computing device communicatively coupled to the drive motor, wherein the cart-computing device generates a control signal to adjust the operation of the drive motor, and a sensor module communicatively coupled to the cart-computing device. The sensor module, in a first mode, generates a signal and transmits the signal to the cart-computing device in response to a detected event. The sensor module, in a second mode, transmits a first communication signal in response to the first communication signal generated by the cart-computing device. The sensor module, in a third mode, receives a second communication signal in response to a source external to the cart transmitting the second communication signal to the cart.

The present invention provides an automated modular system and method for production of biopolymers including DNA and RNA. The system and method automates the complete production process for biopolymers. Modular equipment is provided for performing production steps with the individual modules arrange in a linear array. Each module includes a control system and can be rack mounted. One side of the array of modules provides connections for power, gas, vacuum and reagents and is accessible to technicians. On the other side of the array of modules a robotic transport system is provided for transporting materials between module interfaces. The elimination of the requirement for human intervention at multiple steps in the production process significantly decreases the costs of biopolymer production and reduces unnecessary complexity and sources of quality variation.