Through most of my career, my work has involved calculation, modelling or simulation to estimate the performance characteristics of various electromagnetic devices.  At times, my work has also involved the design and/or testing of such devices.  In earlier years, most of my work related to rotating electrical machines, whereas most of my recent work related to power cables and transformers.  Particular areas of expertise include finite element modelling using a number of commercial software suites and the development of bespoke codes using platforms such as Matlab. 

Produced object-oriented Matlab models to simulate transient voltage and current waveforms in the conductors, sheaths, and sheath-voltage limiters of high-voltage cable systems. To determine the transient characteristics required for the cables in the Matlab models, I used 2D steady-state finite-element models together with additional Matlab code. 

Worked on checking the design of a proposed HVDC test supply for problems.  Mostly, this involved finite-element modelling with Comsol, either to estimate their circuit equivalent parameters, or to estimate the maximum field or temperature in each material.  Did some unofficial design work to make the preliminary arrangement drawings suitable for the modelling requested.

Worked on a project related to exploitation of the overload capability of transformers.  Used finite-element modelling to understand the impact of loading on the flux densities in a transformer core.  Proposed a simple method of estimating the fair price for overloading a transformer, based on the marginal cost of accelerated ageing with respect to load. 

More recently, I worked on a simplified thermal model for transformer temperatures that uses a circuit representationof both heat flow and oil flow. This avoids the need for geometric data that is usually unavailable; most of the required input data can be obtained from most type-test reports. 

Worked on the calculation of electrical losses in high voltage power cables of the type used to connect wind farms back to the onshore electricity transmission grid.  Developed a series of new analyticaland numerical models (in Excel and Matlab) capable of calculating losses in armoured AC cables. While the international standard for calculating continuous ratings of cables (IEC 60287) provides calculation methods for losses in most types of power cables, there are fundamental flaws in the methods defined for this type of cable; this has a significant impact on the cable sizing calculations done for offshore wind farms.  It was hoped that the improved models developed will reduce excessive conservatism in the sizing of such cables, and thus reduce their cost. Authored a paper describing our method and the problems with the armour-loss expression in the standard. 

Much of my recent work concerned modelling the electricallosses and cooling of power cables. Efforts to decarbonize the UK economy have greatly increased the need for such work. In addition to the need for new cables to connect offshore wind turbines to the national grid, there are rapid changes in the typical loading patterns on existing National Grid circuits; recent projects arose from both of these changes. 

Worked on modelling cooling of cables in tunnels. As direct application of 3D finite-element analysis to model long cable tunnels is impractical, they were used mostly to produce matrix data for use in 1D Matlab models.