Wired Coworking – Project Completion: Technical Report and Results Explanatory Call
Technical Report and Results Explanatory Call
Already a member? Log in here
Related Articles
WiredWhite 2.0: How to manage my store.
In this article you will learn everything you need to know in order to use and manage your store tools in the most efficient and……...
Already a member? Log in here
How to create a course. The ABC of online courses.
Our platform upgrade offers our engineering and IT experts the possibility to create and sell your own online courses on our platform. In the following……...
Already a member? Log in here
Flux Barrier Design Method for Torque Ripple Reduction in Synchronous Reluctance Machines
Abstract—The current publication introduces the flux barrier design method and the concrete design of the synchronous reluctance machine with the reduced torque pulsations. The reviewed method provides the accelerated approach for designing of rotor flux barriers, based on Fast Fourier transforms and simple mathematical expressions. The proposed method has been utilized in the rotor design of synchronous reluctance machine and has shown desired results in reduced torque ripple. The innovative nonsymmetrical geometries for rotor flux barriers created on the basis of proposed flux barrier design method have been implemented and proved as beneficial. Keywords—Flux barriers; torque ripple reduction; FEM; synchronous reluctance machines.
Already a member? Log in here
Wired Coworking – Project Execution
Wired Coworking – Project Execution
Already a member? Log in here
Standstill Frequency Response Test for Obtaining Parameters of Six Phase Double Delta Salient-Pole Synchronous Machine on Example of Claw-Pole Alternator
The current publication introduces an approach for obtaining parameters of a six phase double delta salient-pole synchronous machine, based on the standstill frequency response test. The described approach was verified by measurements on a automotive claw-pole alternator, done in a laboratory on a test bench.
Already a member? Log in here
