Add to ORKGThe efficiency of electrical machines has global impact and its improvement passes through a good knowledge of the magnetic cores properties, namely the energy loss. One difficult aspect of the loss investigation in magnetic sheets concerns the appraisal of the material behavior at polarizations close to the saturation value Js, where most efficient rotating machines are made to work. In this communication such a behavior is experimentally assessed exploiting a novel magnetizing system, where non-oriented Fe-Si steel sheets can be characterized under alternating and rotational flux in the frequency range 2 Hz – 1 kHz up to the polarization value Jp≅0.98 Js
The prediction of core losses in a rotating electrical machine has been estimated by a numerical fin...
The prediction of core losses in a rotating electrical machine has been estimated by a numerical fin...
Magnetic energy losses have been measured in non-oriented Fe–Si laminations under alternating, ellip...
A three-phase magnetizer has been developed, by which non-oriented Fe–Si steel sheets can be charact...
Literature data on the energy loss behavior of steel sheets under rotating induction are restricted ...
Literature data on the energy loss behavior of steel sheets under rotating induction are restricted ...
Literature data on the energy loss behavior of steel sheets under rotating induction are restricted ...
Literature data on the energy loss behavior of steel sheets under rotating induction are restricted ...
Thin laminations of non-grain oriented (NO) electrical steels form the magnetic core of rotating ele...
Energy losses have been investigated as a function of magnetizing frequency (DC - 200 Hz) and peak p...
The Pulse Width Modulation (PWM) technique is commonly used to supply modern high-speed electrical m...
The Pulse Width Modulation (PWM) technique is commonly used to supply modern high-speed electrical m...
The concept of loss separation based on the Statistical Theory of Losses (STL) provides complete and...
The concept of loss separation based on the Statistical Theory of Losses (STL) provides complete and...
The properties of the lamination of rotating electrical machines made of non-grain oriented electric...
The prediction of core losses in a rotating electrical machine has been estimated by a numerical fin...
The prediction of core losses in a rotating electrical machine has been estimated by a numerical fin...
Magnetic energy losses have been measured in non-oriented Fe–Si laminations under alternating, ellip...
A three-phase magnetizer has been developed, by which non-oriented Fe–Si steel sheets can be charact...
Literature data on the energy loss behavior of steel sheets under rotating induction are restricted ...
Literature data on the energy loss behavior of steel sheets under rotating induction are restricted ...
Literature data on the energy loss behavior of steel sheets under rotating induction are restricted ...
Literature data on the energy loss behavior of steel sheets under rotating induction are restricted ...
Thin laminations of non-grain oriented (NO) electrical steels form the magnetic core of rotating ele...
Energy losses have been investigated as a function of magnetizing frequency (DC - 200 Hz) and peak p...
The Pulse Width Modulation (PWM) technique is commonly used to supply modern high-speed electrical m...
The Pulse Width Modulation (PWM) technique is commonly used to supply modern high-speed electrical m...
The concept of loss separation based on the Statistical Theory of Losses (STL) provides complete and...
The concept of loss separation based on the Statistical Theory of Losses (STL) provides complete and...
The properties of the lamination of rotating electrical machines made of non-grain oriented electric...
The prediction of core losses in a rotating electrical machine has been estimated by a numerical fin...
The prediction of core losses in a rotating electrical machine has been estimated by a numerical fin...
Magnetic energy losses have been measured in non-oriented Fe–Si laminations under alternating, ellip...