LEADER 04414nam  2200949z- 450 
001 9910585938503321
005 20220812
035   $a(CKB)5600000000483097
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/91204
035   $a(oapen)doab91204
035   $a(EXLCZ)995600000000483097
100   $a20202208d2022      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aPerformance of Induction Machines
210   $aBasel$cMDPI - Multidisciplinary Digital Publishing Institute$d2022
215   $a1 online resource (222 p.)
311 08$a3-0365-4785-1 
311 08$a3-0365-4786-X 
330   $aInduction machines are one of the most important technical applications for both the industrial world and private use. Since their invention (achievements of Galileo Ferraris, Nikola Tesla, and Michal Doliwo-Dobrowolski), they have been widely used in different electrical drives and as generators, thanks to their features such as reliability, durability, low price, high efficiency, and resistance to failure. The methods for designing and using induction machines are similar to the methods used in other electric machines but have their own specificity. Many issues discussed here are based on the fundamental achievements of authors such as Nasar, Boldea, Yamamura, Tegopoulos, and Kriezis, who laid the foundations for the development of induction machines, which are still relevant today. The control algorithms are based on the achievements of Blaschke (field vector-oriented control) and Depenbrock or Takahashi (direct torque control), who created standards for the control of induction machines. Today's induction machines must meet very stringent requirements of reliability, high efficiency, and performance. Thanks to the application of highly efficient numerical algorithms, it is possible to design induction machines faster and at a lower cost. At the same time, progress in materials science and technology enables the development of new machine topologies. The main objective of this book is to contribute to the development of induction machines in all areas of their applications.
606   $aHistory of engineering & technology$2bicssc
606   $aTechnology: general issues$2bicssc
610   $aaccurate modelling
610   $aartificial neural network
610   $aartificial neural networks
610   $aautomatic train operation
610   $adynamic model
610   $aeffective parameters
610   $aelectrical machines
610   $aelectromagnetic models
610   $aend effect
610   $aenergy efficiency
610   $aevolutionary strategy
610   $afinite element analysis
610   $afinite element method
610   $afourth central moment
610   $ahomogeneity analysis
610   $aindirect rotor field-oriented control
610   $ainduction machine
610   $ainduction machine drives
610   $ainduction machines
610   $ainduction motor
610   $ainduction motors
610   $aLIM
610   $alinear induction motor
610   $alinear induction motors
610   $aMatlab/Simulink
610   $amechanical unbalance
610   $amodel selection
610   $amodel-based prediction
610   $amodelling of ring induction motors
610   $aMonte Carlo method
610   $amotor performance
610   $an/a
610   $aone broken rotor bar
610   $aoptimization
610   $aouter-race bearing fault
610   $apattern search
610   $arotor field-oriented angle error
610   $arotor winding
610   $asimulated annealing
610   $aslip frequency
610   $asoft magnetic material
610   $asolid rotor
610   $asquirrel-cage rotor
610   $astartup transient current
610   $astator winding
610   $athermal conductivity
610   $athermal modeling
610   $athree-phase induction motor
610   $atwo broken rotor bars
615  7$aHistory of engineering & technology
615  7$aTechnology: general issues
700   $aPalka$b Ryszard$4edt$01293866
702   $aPalka$b Ryszard$4oth
906   $aBOOK
912   $a9910585938503321
996   $aPerformance of Induction Machines$93022799
997   $aUNINA