Before high voltage plant fails there is generally a period when degradation of the insulation system occurs, this may be a number of years. The key to improving the assessment of the equipment condition and life expectancy lies in identifying and characterising the stages of degradation. It is widely recognised that the degradation phase, irrespective of the cause, results in small sparks being generated at the site(s) of degradation. These electric sparks are generally referred to as partial discharges(PD). The characteristics of the sparks are influenced by the materials and stresses at the fault site. Improvement in their detection and characterisation will provide information on the location, nature, form and extent of degradation.The current detection process is severely compromised in practical on-site testing. These PD pulses are extremely small and hence, irrespective of the particular strategy being applied to detect them(electrical or acoustic), detection equipment must be very sensitive. In the field, this makes it prone to the influence or external interference or 'noise' from the surrounding environment and electrical/mechanical infrastructure. At best, this results in data corruption and compromises the efficiency of the condition assessment. At worst, it stops the technique from being of any use as the 'noise' signal exceeds the level of partial discharge activity.To solve the problems associated with noise a number of methods have been tried such as: screening and filtering, the application of analogue band-pass filtering, matched filters, polarity discrimination circuitry, time-windowed methods and digital filters. Each of these is, however, applicable to only certain types of noiseIn a recent study the author compared the matched filter, the traditional filter and the Discrete Wavelet Transform (DWT) in PD measurement denoising and has proven DWT provides the best solution in practical measurement when strong noise is in presence. Furthermore, DWT is the only method which allows reconstruction of the PD pulse.Having evolved from the Fourier Transform(FT), WT is particularly designed to analyse transient, irregular and non-periodic signals. Ideally, if a wavelet can be selected to match the PD pulse shape, the PD pulse could be extracted from any strong noise signals. Though the WT generates more information than the FT, it is inherently more complex than the FT and involves procedures dependent on the shape of the signals to be extracted from noisy data, the record length and the sampling rate. Dr. Zhou in the Insulation Diagnostics Group at the GCU was the first to study the optimal selection of the most appropriate wavelets, the optimal number of levels and level-dependent thresholding algorithm for automatic PD pulse extraction from electrically noisy environments using DWT. This innovative work has been proved to be effective in a number of measurement platforms. However, the application of DWT still requires significant experience at the moment when pulses of different shapes exist. The proposed research is to build on the experience and success already gained at GCU and to develop a methodology which allows the DWT to be applied to various PD measurement systems irrespective of their mechanism and bandwidth for PD data denoising and PD pulse reconstruction and classification.The outcome of the proposed research will be algorithms which can identify all types of transient pulses contained in data under analysis and present them separately in time domain. This would allow the identification and classification of various PD activities from PD measurements and production of phi-q-n diagrams which, in conjunction with pulse shapes, provides significantly improved means for plant diagnosis.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

This proposal involves collaborative research between academics at Glasgow Caledonian University (GCU) and the University of Strathclyde (UoS). The primary aim of the project is to apply a cross-disciplinary approach to address the problem of acquiring essential information for diagnostics of on-line condition monitoring of cable insulation on the basis of partial discharge (PD) activity. This will be achieved by developing modern data mining techniques to acquire knowledge directly from on-line, data rich, condition monitoring systems. Analysis of on-line information from applied systems will be supported and validated through extensive, dedicated experiments carried out both in the laboratory environment as well as in practical power distribution systems. Failures in the power distribution network are costly to the operators and they are also a serious issue for consumers, who experience power cuts and disruption to their business and social activities during repairs. If techniques for establishing scientifically the condition of cable insulation and its performance are not developed, similar disruption and excessive cost can result from unnecessary replacement of cable assets on the basis of planned maintenance based purely on age. This proposed research programme will build on three areas in which the investigators have internationally recognised expertise: firstly, measuring and discriminating signal characteristics from high power plant, secondly, determining degradation in oil/paper insulation systems and, thirdly, applying software to determine knowledge entrained in raw data. This programme of research will significantly benefit from the knowledge gained from two recently funded EPSRC projects at GCU and UoS (EP/D048133 and GR/86760) as well as recently completed industrially funded projects. In addition to the academic strengths of the proposers, a very substantial industrial contribution is being provided by EDF Energy: a 30,000 direct cash injection and strong in-kind contribution, i.e. cable samples, unlimited access to data from its on-line condition monitoring systems and to fault/condition reports from its replacement programme as well as access to practical expertise of its staff. Further support from Cable manufacturing company Prysmian Cables and Systems Limited (20,000 in kind), Dow Chemical and PD based condition monitoring equipment provider IPEC Ltd (8,000 in-kind) will ensure breadth of validity of the research and broaden the scope of the project by investigating a range of plant types and set-ups and to ensure more general applicability of the research.

The project aims to identify the challenges facing the future security of the UK nuclear energy sector and coastal energy supply in the NW region as a result of changing patterns of temperature and rainfall, sea-level rise and storms. In particular, we will determine the threats posed to future energy generation and the distribution network by flooding and erosion, changing patterns of coastal sedimentation, water temperature and the distribution of plants and animals in the coastal zone. As well as having important consequences for the operation of coastal power stations, these climate change impacts also affect the neighbouring coastline as well as the coastal waters. As a result, communities need to be made aware of these future threats, and to be brought into discussions that decide the future of energy supply in the UK. To support this, the project will first build a computer model of the coast that can operate at scales of 25-100 km and that can predict coastal changes for estuaries, gravel beaches, sandy beaches and dunes, and cliffs made up of both hard and soft rock. The coupled outputs from this integrated model will be converted into maps of future flooding, erosion, sedimentation, water quality and habitats that are the result of climate change projections to the 2020s, 2050s and 2080s and, over longer periods of time, our best understanding of long-term coastal change to 2100, 2200 and 2500 AD. These maps can then be consulted and overlain using a computer-based geographic information system as a decision-support tool to assist in drawing-up coastal management plans, looking at the different threats that we face and the options to address their overall impact on coastal energy supply. The aim is to identify how the coastal power stations, substations and distribution grid can adapt to future climate change impacts and thus become more resilient, thus securing our energy needs as we move into a low-carbon future.

FlexNet has been set the goal of researching the future form of the electricity network. This is a great challenge because electricity networks are formed from long lifetime equipment that will often be in place for more than 50 years and which costs a great deal to replace. Much of the UK network was constructed in the 1960s and 1970s and falls due for replacement soon. This is both an opportunity and a threat. The plans for replacement must stand the test of time or future generations will face a large bill for making changes. We are at a point where the future of electricity generation is uncertain. We know that low-carbon energy is the objective but the network required to support offshore wind is very different from the network to support domestic-scale fuel cells. The key will be to plan, design and build networks that are sufficiently flexible to meet several quite different scenarios. There are limits to the flexibility though. First, flexibility generally requires more investment for which electricity consumers ultimately pay. Second, electrical networks are major projects that impact local communities and those communities' have important views on what technology is acceptable. Third, flexibility calls for a far greater level of real-time control of the network which poses challenges in analysis and implementation. FlexNet will research the technologies to provide flexibility, the market mechanisms through which investment is encouraged efficiently and the way in which public attitudes might shape what can be done. FlexNet is a consortium of universities, electrical network operators, equipment manufacturers and NGOs. The seven universities combine expertise in electrical engineering, economics and social science. The consortium builds on the work of its predecessor, FutureNet.