Data are sent from an internal data processing system of an industrial plant to an external data processing system of the industrial plant by generating with an industrial edge device data packets from data related to an industrial machine, and generating therefrom signed data packets signed with a first digital signature. While the signed data packet are read, a user-defined data filter is applied, which lets either pass or rejects the signed data packets. The data packets that passed the user-defined data filter are then sent to the external data processing system.

In one embodiment, a condition monitoring circuit can include a circuit controller and a node. The node can include a gate controller, a node controller and one or more gates. The node can be configured to detachably couple to a bus of a monitoring system associated with an industrial machine. The circuit controller can be configured to identify an operating parameter associated with the industrial machine. The gate controller can be configured to transfer, via the one or more gates, one or more data packets including data characterizing the operating parameter from the bus in the monitoring system. The one or more gates can be configured to prevent transfer of an outgoing data packet to the bus via the node.

The invention includes a method for monitoring an automated plant having at least one field device, wherein a first cloud-capable database, having a first data configuration and containing field device related data including measured values, parameter values, identification data, and diagnostic status of the field device, wherein a second cloud-capable database having a second data configuration incompatible with the first data configuration, and wherein the first and the second data configurations define file formats of the data, the method comprises: retrieving at least a part of the data contained in the first database by means of a data conversion unit, especially an edge device or a gateway; converting the retrieved data into a format conforming to the second data configuration; and storing the converted data in the second database. The invention further includes a data conversion unit, which is embodied for executing the method of the invention.

An edge gateway system securely delivers and exposes data generated by and/or related to a process plant for consumption by external systems, and includes a field-facing component that sends, to an edge-facing component of the system, a collection of data types defined based on configurations of the process plant and represented using a syntax that is native to the one or more external systems. The field-facing component streams process plant-related content data indicated by one or more interest lists to the edge-facing component, where the streamed data is expressed using the collection of data types. Each interest list may include multiple types of data (e.g., control, I/O, diagnostic, device, historical, etc.) that collectively represent a particular named entity of the plant. Accordingly, the streamed data is securely delivered and exposed, via the edge-facing component, to the external systems.

An edge gateway system securely delivers and exposes data generated by and/or related to a process plant for consumption by external systems, and includes a field-facing component that sends, to an edge-facing component of the system, a collection of data types defined based on configurations of the process plant and represented using a syntax that is native to the one or more external systems. The field-facing component streams process plant-related content data indicated by one or more interest lists to the edge-facing component, where the streamed data is expressed using the collection of data types. Each interest list may include multiple types of data (e.g., control, I/O, diagnostic, device, historical, etc.) that collectively represent a particular named entity of the plant. Accordingly, the streamed data is securely delivered and exposed, via the edge-facing component, to the external systems.

Gateway device (100), adapted to couple a first network with a second network, comprising: a first network interface device (102) coupled by a first interface to a first network and having a second interface; a second network interface device (104) coupled by a first interface with the second network and having a second interface; a network coupling device (103) adapted to transmit in a first status no data from the second interface of the second network interface device (104) to the second interface of the first network interface device (102) on the physical layer and adapted to transmit in a second status data from the second interface of the first network interface device (102) to the second interface of the second network interface device (104); wherein said network coupling device (103) includes a switching device (126, 128) coupled to a conductor (130, 134) coupling the second interface of the first network interface device (102) and second network interface device (104); wherein the switching device (126, 128) is connected such to the conductor (130, 134) that the conductor can not transmit data in a first state of the switching device and that the conductor can transmit data in a second state of the switching device and wherein said switching device (126, 128) is controlled by a manual switch (127) operated by a user.

A scalable industrial data ingestion and analysis architecture integrates and collects data from multiple diverse sources at one or more industrial facilities. Data sources can include plant-level industrial devices and higher-level business systems. The data can be integrated and collected from multiple sources at an on-premise edge or gateway device, which sends the data to event queues on the cloud platform. The data queues orchestrate and store the data on cloud storage, and an analytics layer performs business analytics or other types of analysis on the stored data to produce various outcomes. Similar analytic platforms can also be implemented at the device level, and analytic functions can be scaled between the device level and higher levels in accordance with the scope of a given analytic function.

An aggregator is designed to form first data connections to field access devices. The field access devices are connected to different network segments of a field bus system. The aggregator forms a second data connection to a host computer. The aggregator receive first data traffic from the host computer via the second data connections and to forward the first data traffic, via the first data connections to a field access device of that network segment in which the particular field bus component, to which the first data traffic is directed, is situated. The aggregator is also designed to receive second data traffic from a field bus component in one of the network segments via at least one of the first data connections and to forward the second data traffic to at least one of the host computers via at least one of the second data connections.

A scalable industrial data ingestion and analysis architecture integrates and collects data from multiple diverse sources at one or more industrial facilities. Data sources can include plant-level industrial devices and higher-level business systems. The data can be integrated and collected from multiple sources at an on-premise edge or gateway device, which sends the data to event queues on the cloud platform. The data queues orchestrate and store the data on cloud storage, and an analytics layer performs business analytics or other types of analysis on the stored data to produce various outcomes. Similar analytic platforms can also be implemented at the device level, and analytic functions can be scaled between the device level and higher levels in accordance with the scope of a given analytic function.

A method includes receiving one or more data files that have one or more user-selected input parameters associated with one or more electrical devices in an industrial system, one or more output parameters associated with the electrical devices, one or more input/output parameter tags, a frequency or a condition associated with data transmission for each electrical device, or a combination thereof. The electrical devices may communicate via a first communication network based on the International Electrotechnical Commission 61850 standard, and the controller may communicate via a different communication network. The method also includes automatically programming the controller to control one or more operations of each electrical device based on the data files and transmitting the data files to a gateway device communicatively coupled to the controller along a backplane of a chassis system. The gateway device is automatically configured based on the one or more data files.