Submission Slide 1 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [Smart Grid: Faulted Circuit Indicator] Date Submitted: [March 7, 2011] Source: [David A. Howard, John Geiger] Company [On-Ramp Wireless, GE Energy Services] Address [10920 Via Frontera Suite 200, San Diego, CA USA] Voice:[+1(858) ], FAX: [+1(858) ], Re: [January 2011, IEEE k LECIM Task Group Call For Applications DCN: 0105] Abstract:[Wireless Faulted Circuit Indicator application] Purpose:[Response to k CFA, for use in generating application requirements] Notice:This document has been prepared to assist the IEEE P It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein. Release:The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P

Submission Faulted Circuit Indicator (FCI) Faulted circuit indicators were introduced in Germany in Since that time FCIs have been used to locate problems on medium voltage electrical distribution circuits throughout the world. Also known as ground fault indicators, earth fault indicators, short-circuit indicators, or simply fault indicators Used to improve power system reliability Can help identify problem areas of distribution system (fault localization) Slide 2

Submission FCI (continued) Slide 3 Schematic example of legacy FCI use in electric distribution

Submission FCI Benefits (traditional) Reduction of outage duration –Enables service crews to rapidly identify location of fault by patrolling area Improve system reliability Reduction of operating costs Slide 4

Submission FCI Benefits (wireless) New functionality possible with wireless solutions –Enable crews to be dispatch directly to the fault area –Locate momentary/transient faults –Coordinate automated reclosing schemes –Monitor load current, voltage, temperature, and events improved modeling of grid events, and reliability metrics –Change fault thresholds –Improved planning based on load data –Safety, e.g. Fire prevention Slide 5

Submission FCI Benefits (wireless with Time Sync) New functionality possible with single digit uS timing accuracy –Determine location of fault with ~100 meter accuracy –Pin-point location of momentary/transient faults –Increase distance between FCI in rural areas –Synchronized monitoring load current, voltage, temperature, and events –Improved modeling of grid events, and reliability metrics, Slide 6 Slide 6

Submission Slide 7 FCI Data Model UpLink Periodic/scheduled –Once per day –<100 octets –Average load, temperature, transient/momentary events statistics, battery status Event/asynchronous/unscheduled/alarm –50 (?) per FCI per year –<100 octets –Average load, temperature, transient/momentary events statistics, battery status

Submission FCI Data Model (continued) Downlink –Reliable transmission feedback (e.g. ACK) <10 octets; infrequent (see uplink) –Parameter changes (thresholds, etc.) <10 octets; infrequent –Firmware update Potentially 100’s of Kbytes; extremely rare Latency –10’s of seconds Slide 8

Submission Deployment Scenarios FCI –Above ground Elevated Pad mount cabinet –Below ground Access Point/Aggregator –Tower/shared space Slide 9

Submission FCI: above ground deployment (elevated) Slide 10

Submission FCI: above ground deployment pad mount cabinet, ~15-20dB path loss Slide 11

Submission FCI: below ground deployment vault/manhole ~ 15-30dB path loss Slide 12

Submission Access Point/Aggregator Slide 13 Tower Shared Space / High interference (10-15dB above thermal noise floor)

Submission Power requirements Faulted Circuit Indicator (10-20 yr service life) –Battery (e.g. Lithium Thionyl Chloride Li- SOCl2) –Power scavenging (e.g. inductive + super capacitor) Access Point/Aggregator –Mains powered, UPS/Generator backup Slide 14

Submission Market Size (distribution, estimate) USA 3M EU 3M Japan 614K World 10M Based on number of customers, customers per transformer (~10-15), and transformers per FCI (~5-10) Slide 15

Submission Application Requirements Low infrastructure costs –Point to multi-thousands of point communications –Address spectrum availability/cost issues Easily deployable –Minimal network complexity and number of active nodes –Access point/Standard network interface – IP –Standard device interface – Serial or IP Able to communicate to underground/enclosed assets Endpoint able to operate without primary power for many years –Small payload per day –Latency in seconds –Event time accurate to single digit uS Available embedded through OEM’s Slide 16