A storage environment monitoring device is capable of measuring and/or monitoring various parameters of an environment inside a storage area, such as airflow, temperature, and humidity, to increase the storage quality of semiconductor components stored in the storage area. The storage environment monitoring device is capable of measuring and/or monitoring the parameters of the environment inside the storage area without having to open an enclosure that is storing the semiconductor components in the storage area. This reduces exposure of the semiconductor components to contamination and other environmental factors. In addition, the storage environment monitoring device may perform automatic measurements inside the storage area based on usage schedules of the semiconductor components that are to be stored in the storage area, which decreases downtime of the storage area and/or the semiconductor components, and increases productivity in a semiconductor processing environment in which the semiconductor components are used.

An example method includes receiving task identification information indicative of a manufacturing task to be performed on a workpiece, wherein the workpiece transfer system comprises a rail and a plurality of arms coupled to the rail, wherein each arm comprises (i) a plurality of arm linkages coupled at respective joints, (ii) an arm controller in communication with the supervisory controller, and (iii) respective joint controllers in communication with the arm controller and configured to actuate respective rotary actuators at the respective joints to move the plurality of arm linkages relative to each other: retrieving a motion plan corresponding to the manufacturing task and the workpiece: sending command signals to respective arm controllers to communicate respective command signals to the respective joint controllers and execute the motion plan; and once the final desired configuration is achieved, commanding the respective arm controllers to lock the respective joints.

A component mounting line control system controls a component mounting line. The component mounting line includes a component mounting device and a board retrieving unit. The component mounting line control system includes an acquirer and a controller. The acquirer acquires information from the board retrieving unit. The controller controls the component mounting device based on the information acquired by the acquirer. The controller lengthens a time taken for a manufacturing process in the component mounting device in a case where the acquirer acquires first warning information, which indicates that a board accommodation limit is about to be reached, from the board retrieving unit.

The invention relates to a conveying device for conveying objects comprising a plurality of conveyor segments, each conveyor segment having a control unit for controlling the conveyor drive, and a bus communication, wherein each control unit is connected to the bus communication. Each control unit has a microprocessor for processing control signals, a first electronic memory connected to the microprocessor, in which a first control configuration is stored, and a second electronic memory in which a second control configuration is stored. The microprocessor is adapted to control the conveyor drive in a first operating mode with the control configuration stored in the first memory, to load the second control configuration from the second memory into the first memory when a configuration change command is received, and to control the conveyor drive in a first operating mode with the control configuration stored in the first memory.

A transport system for linear movements includes at least two sensors configured to determine a position of one or more carriers along a carrier track. Each of the sensors are interconnected with each other and arranged in a daisy-chained manner along the carrier track. The sensors create a position sensor bus configured to transmit a digital position sensor signal. The transport system further includes a motion controller connected to the sensor bus and configured to control at least one position of the carriers along the carrier track.

Systems, methods, and machine-executable coded instruction sets for controlling the movement of transporting devices and/or operations conducted at various workstations are disclosed. In particular, the disclosure provides methods, systems and computer-readable media for controlling the movement of transporting devices configured for fullyand/or partly automated handling of goods and/or controlling operations conducted at various workstations.

Methods for simultaneously producing different products on a single production line are disclosed. The method may be used to produce different fluent products and other types of products including assembled products. In some cases, the method includes providing a plurality of articles which are components of the products to be produced. The method further involves providing a track system and a plurality of vehicles for the articles. At least some of the vehicles may be independently routable around the track system. The method further includes simultaneously sending one article-loaded vehicle to a unit operation station where a step in the production of a product is performed and another article-loaded vehicle to a unit operation station where a step in the production of a different product is performed.

A system and method for producing products based upon demand are disclosed. In some cases, the products include containers and the contents therein. The containers are disposed on vehicles and are independently routable along a track system and are deliverable to at least one unit operation station. A control system: receives demand for finished products; determines a route for vehicles based upon the status of one or more unit operation stations; and causes a vehicle to progress along a determined route to create one or more of the demanded finished products. The system may be used to produce the same fluent products, different fluent products, and other types of products including assembled products.

A system and method for independently routing container-located vehicles to create different finished products are disclosed. The vehicles are independently routable along a track system to deliver the containers to at least one unit operation station. At least some of the vehicles have a unique route associated therewith that is assigned by a control system to facilitate simultaneous production of different finished products.

A monitoring system has a vehicle and a monitoring device. The vehicle is movable along a predetermined route, and the monitoring device is mounted to the vehicle. The monitoring device has a sensor configured to monitor an environmental parameter and a controller communicatively coupled to the sensor. The controller is configured to record the monitored environmental parameter along the predetermined route as data points associated with time tags, record position information, and associate the position information with corresponding time tags. The number of time tags associated with the position information is less than the number of time tags associated with the monitored environmental parameter. A server is configured to receive and display a visualized presentation of the recorded monitored environmental parameter and the recorded position information.