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A scalable architecture for power consumption monitoring in industrial production environments

A scalable architecture for power consumption monitoring in industrial production environments
A scalable architecture for power consumption monitoring in industrial production environments

Detailed knowledge about the electrical power consumption in industrial production environments is a prerequisite to reduce and optimize their power consumption. Today's industrial production sites are equipped with a variety of sensors that, inter alia, monitor electrical power consumption in detail. However, these environments often lack an automated data collation and analysis. We present a system architecture that integrates different sensors and analyzes and visualizes the power consumption of devices, machines, and production plants. It is designed with a focus on scalability to support production environments of various sizes and to handle varying loads. We argue that a scalable architecture in this context must meet requirements for fault tolerance, extensibility, real-time data processing, and resource efficiency. As a solution, we propose a microservice-based architecture augmented by big data and stream processing techniques. Applying the fog computing paradigm, parts of it are deployed in an elastic, central cloud while other parts run directly, decentralized in the production environment. A prototype implementation of this architecture presents solutions how different kinds of sensors can be integrated and their measurements can be continuously aggregated. In order to make analyzed data comprehensible, it features a single-page web application that provides different forms of data visualization. We deploy this pilot implementation in the data center of a medium-sized enterprise, where we successfully monitor the power consumption of 16 servers. Furthermore, we show the scalability of our architecture with 20,000 simulated sensors.

Big-Data, Microservices, Power-Consumption-Monitoring, Software-Architecture, Stream-Processing
124-133
IEEE
Henning, Soren
e09ef4ea-8a2f-4d11-903b-db51d6371fcb
Hasselbring, Wilhelm
ee89c5c9-a900-40b1-82c1-552268cd01bd
Möbius, Armin
ca1d8083-9e9e-4dfc-afe0-5d68d174c448
Henning, Soren
e09ef4ea-8a2f-4d11-903b-db51d6371fcb
Hasselbring, Wilhelm
ee89c5c9-a900-40b1-82c1-552268cd01bd
Möbius, Armin
ca1d8083-9e9e-4dfc-afe0-5d68d174c448

Henning, Soren, Hasselbring, Wilhelm and Möbius, Armin (2019) A scalable architecture for power consumption monitoring in industrial production environments. In 2019 IEEE International Conference on Fog Computing (ICFC). IEEE. pp. 124-133 . (doi:10.1109/ICFC.2019.00024).

Record type: Conference or Workshop Item (Paper)

Abstract

Detailed knowledge about the electrical power consumption in industrial production environments is a prerequisite to reduce and optimize their power consumption. Today's industrial production sites are equipped with a variety of sensors that, inter alia, monitor electrical power consumption in detail. However, these environments often lack an automated data collation and analysis. We present a system architecture that integrates different sensors and analyzes and visualizes the power consumption of devices, machines, and production plants. It is designed with a focus on scalability to support production environments of various sizes and to handle varying loads. We argue that a scalable architecture in this context must meet requirements for fault tolerance, extensibility, real-time data processing, and resource efficiency. As a solution, we propose a microservice-based architecture augmented by big data and stream processing techniques. Applying the fog computing paradigm, parts of it are deployed in an elastic, central cloud while other parts run directly, decentralized in the production environment. A prototype implementation of this architecture presents solutions how different kinds of sensors can be integrated and their measurements can be continuously aggregated. In order to make analyzed data comprehensible, it features a single-page web application that provides different forms of data visualization. We deploy this pilot implementation in the data center of a medium-sized enterprise, where we successfully monitor the power consumption of 16 servers. Furthermore, we show the scalability of our architecture with 20,000 simulated sensors.

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More information

e-pub ahead of print date: 2 September 2019
Venue - Dates: 1st IEEE International Conference on Fog Computing, ICFC 2019, , Prague, Czech Republic, 2019-06-24 - 2019-06-26
Keywords: Big-Data, Microservices, Power-Consumption-Monitoring, Software-Architecture, Stream-Processing
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Identifiers

Local EPrints ID: 488752
URI: http://eprints.soton.ac.uk/id/eprint/488752
DOI: doi:10.1109/ICFC.2019.00024
PURE UUID: ffaf376d-2553-43c7-ba12-cc0c56bf107f
ORCID for Wilhelm Hasselbring: ORCID iD orcid.org/0000-0001-6625-4335

Catalogue record

Date deposited: 05 Apr 2024 16:36
Last modified: 10 Apr 2024 02:15

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Contributors

Author: Soren Henning
Author: Wilhelm Hasselbring ORCID iD
Author: Armin Möbius

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