An iron-loss model for laminated ferromagnetic cores of electrical machines is presented and applied to estimate the core losses of an induction machine with finite-element analysis. Skin effect in the cross section of the core lamination is modelled using a set of sinusoidal basis functions while locally considering both the hysteretic material properties and the excess field caused by domain wall motion. After spatial and time discretisation, a single non-linear equation system is obtained. An accurate vector Preisach model, the differential reluctivity tensor and the Newton–Raphson method guarantee excellent convergence of the iteration procedure. Results from the model correspond well to iron-loss data obtained by measurements
The aim of this work is to propose a new approach for the iron losses prediction, in soft magnetic m...
As the major electricity consumer, electrical machines play a key role for global energy savings. Ma...
This study investigates an advanced finite-element (FE) technique for the evaluation of rotational i...
An iron-loss model for laminated ferromagnetic cores of electrical machines is presented and applied...
A new implementation of an iron-loss model for laminated magnetic cores in the MATLAB / Simulink env...
© 2018 IEEE. A new implementation of an iron-loss model for laminated magnetic cores in the MATLAB/S...
A model of core losses, in which the hysteresis coefficients are variable with the frequency and ind...
A procedure is described for identifying a mathematical model of core losses in ferromagnetic steel ...
This paper presents a method for the estimation of core losses in electrical machine laminations exp...
This paper proposes a model for the computation of iron losses in steel laminations accounting simul...
Iron core loss is the major loss in electrical machines. It performs up to 25% of total machine loss...
In electrical machines, iron losses are essential for electromagnetic and thermal designs and analys...
One potential problem associated with the high electrical frequency in high-speed electrical machine...
International audienceIn this paper, an analytical approach allowing the prediction of iron-core los...
Two new models for specific power losses in cold-rolled motor lamination steel are described togethe...
The aim of this work is to propose a new approach for the iron losses prediction, in soft magnetic m...
As the major electricity consumer, electrical machines play a key role for global energy savings. Ma...
This study investigates an advanced finite-element (FE) technique for the evaluation of rotational i...
An iron-loss model for laminated ferromagnetic cores of electrical machines is presented and applied...
A new implementation of an iron-loss model for laminated magnetic cores in the MATLAB / Simulink env...
© 2018 IEEE. A new implementation of an iron-loss model for laminated magnetic cores in the MATLAB/S...
A model of core losses, in which the hysteresis coefficients are variable with the frequency and ind...
A procedure is described for identifying a mathematical model of core losses in ferromagnetic steel ...
This paper presents a method for the estimation of core losses in electrical machine laminations exp...
This paper proposes a model for the computation of iron losses in steel laminations accounting simul...
Iron core loss is the major loss in electrical machines. It performs up to 25% of total machine loss...
In electrical machines, iron losses are essential for electromagnetic and thermal designs and analys...
One potential problem associated with the high electrical frequency in high-speed electrical machine...
International audienceIn this paper, an analytical approach allowing the prediction of iron-core los...
Two new models for specific power losses in cold-rolled motor lamination steel are described togethe...
The aim of this work is to propose a new approach for the iron losses prediction, in soft magnetic m...
As the major electricity consumer, electrical machines play a key role for global energy savings. Ma...
This study investigates an advanced finite-element (FE) technique for the evaluation of rotational i...