A device includes a device input, an output connector configured to connect to a current loop, and current loop transmitter circuitry. The current loop transmitter circuitry receives, via the device input, an input from a dry contact switch, and translates a state of the dry contact switch to a current loop current. The current loop transmitter circuitry transmits the current loop current via the output connector through the current loop.

The invention relates to an industrial process controller comprising at least three field devices coupled to one another by means of a data link, with the field devices controlling and/or monitoring an industrial process, wherein the field devices are configured to store a block chain, wherein the block chain comprises a plurality of blocks, and wherein the blocks store use data. The process controller is characterized in that the field devices are configured to delete one or more blocks from the block chain and to adapt the block chain to the change caused by the deletion.

A wireless emergency stop system includes a machine safety device connected to a machine stop circuit for stopping operation of a machine when the machine stop circuit is activated. The machine safety device includes a wireless communication interface. The system also includes a mobile device controller configured to control operation of the machine, and a safety stop device. The safety stop device includes a wireless communication interface for wireless communication with the machine safety device, and an emergency stop switch configured to, when activated, transmit an emergency stop signal to the machine safety device to trigger an emergency stop of the machine. The mobile device controller is configured to link with the safety stop device via short-range wireless communication.

Methods of and apparatus controlling change-out inventory of an automated analyzer apparatus. The inventory control methods include receiving change-out inventory status from automated analyzer apparatus at a server, receiving an estimate of the planned workload over a specific time period at the server, analyzing with a decisioning module of the server first data of the change-out inventory status and second data of the planned workload over the specified time period, and producing a work plan itinerary as an output from the decisioning module. The work plan itinerary provides sequence instructions or commands for an operator (person and/or robotic mechanism) to follow for changing out of change-out inventory items. Inventory control apparatus configured to carry out the methods are provided, as are other aspects.

The present disclosure relates to a control system for selectively controlling a vehicle, ensuring high integrity of decisions taken by the control system when controlling the vehicle. The present disclosure also relates to a corresponding computer implemented method and to a computer program product.

An I/O server service interfaces with multiple containerized controller services each implementing the same control routine to control the same portion of the same plant. The I/O server service may provide the same controller inputs to each of the containerized controller services (e.g., representing measurements obtained by field devices and transmitted by the field devices to the I/O server service). Each containerized controller service executes the same control routine to generate a set of controller outputs. The I/O server service receives each set of controller outputs and forwards an “active” set to the appropriate field devices. The I/O server service may utilize a quality-of-service metric to determine which controller outputs and/or I/O channel is “active.” The I/O server service and other services, such as an orchestrator service, may continuously evaluate performance and resource utilization in the control system, and may dynamically activate and deactivate controller services as appropriate.

A software defined (SD) process control system (SDCS) includes a method executed by a discovery service for inferring information regarding a physical or logical asset of a process plant. The method includes obtaining an announcement indicative of a presence of a physical or logical asset of the process plant. The method also includes obtaining, from a context dictionary, one or more parameters retrievable from the physical or logical asset or one or more services associated with the physical or logical asset that were not indicated in the announcement. Furthermore, the method includes storing a record of the discovered physical or logical asset in a discovered item data store. The record includes an indication of the identity of the physical or logical asset and the one or more parameters or one or more services associated with the physical or logical asset that were not indicated in the announcement.

A valve driver system for driving a plurality of valves of a valve manifold. The system includes a plurality of valve drivers, wherein each valve driver is configured to drive a zone of one or more valves of the manifold; and, a power board that separately powers the respective valve drivers such that the valve drivers are powered separately with a separate power source that can individually power the valve driver. A multiple safety zone valve driver system for driving a plurality of valves of a valve manifold. The system includes a plurality of valve drivers; a first safe PM output; and a second safe PM output. The first and second safe PM outputs are configured such that in response to a first type of safety event the first PM output shuts off power to the first one or more valve drivers and the second PM output maintains power to the second one or more valve drivers. A zoning adapter for adapting logical addresses of valve drivers to physical addresses of valves of a valve manifold. A conversion portion converts logical addresses to physical addresses of the valves in the different zones of the valve manifold with a spacing in one or more portions of the logical addresses.

Embodiments of the disclosure provide a method for operating a combined cycle power plant (CCPP). The method may include creating a variant control profile for the CCPP for a power plant model of the CCPP. The method may include modifying the variant control profile in response to the variant control profile not reducing the fuel consumption or meeting the quality threshold. The method may also include adjusting the CCPP to use the variant control profile in response to the variant control profile reducing the fuel consumption and meeting the quality threshold. Using the variant control profile adjusts a turbine section inlet temperature schedule or an exhaust temperature schedule for the CCPP.

An industrial safety architecture integrates employee identity and enterprise-level security policy into plant-floor functional safety systems, allowing control and safety systems on the plant floor to regulate safe interactions with hazardous controlled machinery based on user identity or role. The architecture leverages existing employee identity and security policy data maintained on the corporate level of an industrial enterprise to manage identity- and/or role-based control and safety on the plant level. Safety authority systems at both the corporate level and the plant level of the industrial enterprise obtain employee and security policy data from corporate-level systems and provides this data in as SIL-rated manner to industrial control and safety systems on the plant floor, where the identity and security policy information is used by functional safety systems to control access to industrial systems as a function of user identity, role, certifications, or other qualifications.