Abstract
Dynamic smart grid operations require that utilities that incorporate intermittent renewable energy resources provide creative and inclusive solutions to reduce and shift electrical demand. Commercial building HVAC systems have been used as a dispatchable load, but are limited by the lack of interoperability. Increased operability can be achieved using a secure and reliable interconnection device, which can provide direct bidirectional communications between the utility and the building automation system (BAS) controllers. This paper developed and tested a building automation intrusion detection system (BAIDS) that can provide a cyber-secure connection between public and private BAS networks. The BAIDS was used in a hardware-in-the-loop experiment that connected an actual photovoltaic array with a BAS control test bed and a building zone model. The BAIDS device allowed for critical control signals to pass from the public network directly to a fan controller in a BAS private network. At the same time, the BAIDS device provided intrusion detection monitoring to identify malicious activity. The network traffic was evaluated using an adaptive resonance theory (ART) artificial neural network. The ART algorithm was able to learn normal traffic activity on the private and public networks. The algorithm was then used to detect unauthorized attempts to access the interconnection device and a malicious cyber-physical attack on the BAS.
Highlights
Building infrastructure can support smart grid applications, including the integration of non-dispatchable renewable resources and resiliency measures
The building automation intrusion detection system (BAIDS) was used in a hardware-in-the-loop experiment
Fan control signals were sent from a nearby PV array data acquisition system on the public network, through the BAIDS interconnection device, and to the fan motor controller in the local building automation system (BAS) network
Summary
Building infrastructure can support smart grid applications, including the integration of non-dispatchable renewable resources and resiliency measures. As contributors to the smart grid, buildings can be managed intelligently to reduce the overall electrical demand permanently through energy efficiency measures, or at short timescales using demand response (DR) controls [1]. The open standard provides a non-proprietary interface for utility companies to send control signals to a building system with the intent of modifying electrical loads. The OpenADR architecture uses the open internet to connect the utility or Independent System Operator to a DR Automation Server (DRAS). The signal penetrates the BAS using an internet relay for the CLIR or through a web service client in the case of the gateway application [12]. The BAIDS can provide the added security necessary to create a fast and trustworthy connection between the utility and the commercial building control network
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