The invention relates to a conveyor arrangement (1) for conveying a conveyed material, comprising a motor-driven conveyor roller (100), comprising a roller body (10) mounted so as to be able to rotate about a roller axis (A), a drive unit (20) arranged inside the roller body (10), coupled mechanically to the roller body (10) and an axle element (16) and designed to generate a torque between the axle element (16) and the roller body (10), a sensor function unit (40) arranged inside the roller body (10) and designed to sense a conveyed material to be conveyed by the motor-driven conveyor roller (100), and a control unit (30) that is connected to the sensor function unit (40) in order to transmit signals, wherein the control unit (30) is designed to receive a sensor signal from the sensor function unit and to transmit a control signal to the drive unit (20) depending on the sensor signal, wherein the control signal contains data for driving the motor-driven conveyor roller, in a conveyor mode, with a characteristic profile that is predefined by the control signal.

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.

Systems and methods monitor a conveyor system to determine whether packages are at risk of falling off or jamming. Sensor(s), such as emitters, emit signals in a direction along a longitudinal length of the conveyor system, such as parallel to a flow of packages. Additional sensor(s), such as receivers, are arranged to receive the signals. In instances where the signals are received by the receivers, the packages may be properly positioned on the conveyor system and may not be at risk of falling off and/or jamming. However, if the signals are not received, this may be indicative of the packages being improperly positioned on the conveyor system. In such instances, the conveyor system may come to a stop, may slow in speed, and/or personnel may be instructed to reposition the packages on the conveyor system.

A logistics conveyer roller control system has a motor module, a driver module, a control module, and an HMI module. The driver module is electrically connected to the motor module. The driver module and the HMI module are electrically connected to the control module. The control module stores multiple control menus. The HMI module has a display unit to display the control menus. When the HMI module generates a selection signal, the control menu sets a corresponding control mode according to the selection signal, and controls the driver module to drive the motor module according to the control mode.

Provided is a method of controlling a conveyor for item transportation and an electronic apparatus therefor, the method including acquiring information associated with a plurality of destinations, identifying a weight for each of the plurality of destinations based on the acquired information, determining, in response to an item being identified, a destination among the plurality of destinations based on the identified weight, wherein the item is placed in the determined destination, and controlling the conveyor to transport the item to the determined destination.

A substrate conveying robot includes an arm, a substrate holding hand, a sensor board to which a sensor is electrically connected, and a control board on which a controller is mounted, the control board including a universal connector connectable to different types of the sensor boards.

Various embodiments disclosed herein provide for an improved accumulation conveyor and systems and methods for controlling a high rate, high density tunable accumulation conveyor. In one embodiment, an accumulation conveyor system determines whether an item detection variable associated with a second zone of a plurality of zones is satisfied, wherein the second zone is downstream of a first zone. The accumulation conveyor system determines whether at least one of two operational characteristic variables is satisfied. In an instance where both the item detection variable and at least one operational characteristic variable are satisfied, the accumulation conveyor system is configured to set a zone operating state associated with the first zone to inactive and send a command signal comprising the zone operating state associated with the first zone to a control module associated with the first zone. In another embodiment, an improved method for adjusting aggressiveness is disclosed. In another embodiment, a tunable release rate accumulation conveyor is disclosed. In still another embodiment, a tunable crowding accumulation conveyor is disclosed.

A method for operating a machine in a processing plant for containers, in particular beverage containers, wherein the containers are processed and/or transported by the machine, wherein at least one input signal and at least one output signal of the machine are acquired during the processing and/or the transport, wherein a self-identification model of the machine, which model reproduces at least one current operating point of the machine, is determined based on the at least one input signal and the at least one output signal, wherein at least one machine parameter of the machine and/or of a downstream machine is automatically configured or optimised using the self-identification model, and/or wherein a diagnosis of the machine is automatically carried out using the self-identification model.

Disclosed is a non-PLC-based conveyor controller that controls object transport on a conveyor through communication between controllers with embedded software includes a first controller-connector that performs transmission/reception of data and operation signals with a left non-PLC-based conveyor controller, a second controller-connector that performs transmission/reception of data and operation signals with a right non-PLC-based conveyor controller, an input section through which an object detection signal from a sensor for an object transported on the conveyor is input, an output section that outputs a motor driving signal for operating the conveyor, and a control section that when the object detection signal is input, transmits an entry prohibition signal to the right controller through the first controller-connector, transmits a progress signal to the right controller through the second controller-connector, and outputs the motor driving signal through the output section so that the object is transported to the conveyor controlled by the right controller.

A substrate work system including a work device configured to perform predetermined work on a substrate by use of an exchangeable work unit includes a storage section configured to store the work unit, a maintenance device configured to perform maintenance of the work unit, a conveyance device capable of conveying the work unit, a determination section configured to determine a maintenance time for the work unit used in the work device based on quality information on work quality of the predetermined work, and a control section configured to, when the determination section determines that a maintenance time arrives, cause the conveyance device, the work device, and the maintenance device to unload the work unit, convey the work unit to the work device to exchange with the work unit that has been used, and convey the used-up work unit to the maintenance device.