Zhang, Y., Neto, J. M., Upton, D., Khanzada, U.K., Saeed, Bakhtiar I., Ahmed, H., Mather, Peter, Atkinson, R., Lazaridis, Pavlos, Vieira, M. F. Q. and Glover, Ian (2015) Radiometer Monitoring System for Partial Discharge Detection in Substation. In: International Union of Radio Science Atlantic Radio Science Conference, 18th - 22nd May 2015, Las Palmas, Gran Canaria.Metadata only available from this repository.
Progress on the development of an insulation defect detection and location system using a partial discharge (PD) wireless sensor network (WSN) will be presented. Such a PD WSN based on intensity only measurements has cost and scalability advantages over existing detection and location technologies based on time difference-of-arrival measurements such as described in (I. E. Portugues, P. J. Moore, I.A. Glover, IEEE Trans. on Power Delivery, 1, 2009, pp. 20–29). Figure 1 shows a hypothetical
deployment of the PD WSN in an electricity substation. The (red) pentagram denotes a PD source, yellow circles and triangles denote sensor nodes, and the yellow St George’s cross
denotes the data collection/processing node. Each node of the WSN is a broadband radiometer with a measurement band of 50–800 MHz, Figure 2. Three measurement sub-bands allow the radiometer to distinguish different forms of PD; in particular internal PD and corona discharge. WirelessHart has been selected as the network communications technology since this offers improved reliability over other standards (e.g. Zigbee) in harsh industrial environments. In the substation environment the path-loss index is both unknown and generally different for the path from the PD source to each sensor, so range cannot be estimated from a single power measurement. A simulated PD signal will therefore be periodically radiated from each node to calibrate path-loss index from that node to all other nodes. The authors’ (currently) favoured PD location method is based on a variation of path-loss inversion as follows: (i) assume a plausible path-loss index (e.g. n = 2), (ii) calculate the ratio of received power at any two nodes implying a locus of possible source locations, (iii) use intersecting loci from all measurement node pairs to establish an initial estimate of source location, (iv) use the initial source location to refine the estimate of n appropriate to each sensing node, (v) use pairs of nodes corresponding to paths with (nearly) equal n to calculate an improved estimate of source location, (vi) iterate as necessary to converge on a final location estimate. Proof-of-principle measurements using an artificial PD source and a sensor node in Fig. 2 in a laboratory environment are encouraging, Figure 3. These proof-of-principle results implement only steps (i) through (iii) of the algorithm
described above. Steps (iv) through (vi) of the algorithm will result in a final location accuracy at least as good as selecting the optimum path-loss index in Figure 3 and probably better than this. The error between estimated and actual PD source location selecting the optimum path-loss index is 1.4 m.
|Item Type:||Conference or Workshop Item (Paper)|
|Subjects:||T Technology > TK Electrical engineering. Electronics Nuclear engineering|
|Schools:||School of Computing and Engineering
School of Computing and Engineering > Systems Engineering Research Group
|Depositing User:||Ian Glover|
|Date Deposited:||29 Feb 2016 16:06|
|Last Modified:||02 Feb 2017 13:20|
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