PRINCIPLE OF DESIGN OF FOUR PHASE LOW POWER SWITCHED RELUCTANCE MACHINE AIMED TO THE MAXIMUM TORQUE PRODUCTION

Similar documents
Mathematical Modeling and Dynamic Simulation of a Class of Drive Systems with Permanent Magnet Synchronous Motors

the machine makes analytic calculation of rotor position impossible for a given flux linkage and current value.

A Simple Nonlinear Model of the Switched Reluctance Motor

Dr. N. Senthilnathan (HOD) G. Sabaresh (PG Scholar) Kongu Engineering College-Perundurai Dept. of EEE

International Journal of Advance Engineering and Research Development SIMULATION OF FIELD ORIENTED CONTROL OF PERMANENT MAGNET SYNCHRONOUS MOTOR

Fachgebiet Leistungselektronik und Elektrische Antriebstechnik. Test Examination: Mechatronics and Electrical Drives

DESIGN AND ANALYSIS OF AXIAL-FLUX CORELESS PERMANENT MAGNET DISK GENERATOR

Static Characteristics of Switched Reluctance Motor 6/4 By Finite Element Analysis

Implementation of Twelve-Sector based Direct Torque Control for Induction motor

SWITCHED reluctance motor (SRM) drives have been

Analytical Model for Sizing the Magnets of Permanent Magnet Synchronous Machines

3 d Calculate the product of the motor constant and the pole flux KΦ in this operating point. 2 e Calculate the torque.

Parameter Prediction and Modelling Methods for Traction Motor of Hybrid Electric Vehicle

Doubly salient reluctance machine or, as it is also called, switched reluctance machine. [Pyrhönen et al 2008]

Prediction of Electromagnetic Forces and Vibrations in SRMs Operating at Steady State and Transient Speeds

An Introduction to Electrical Machines. P. Di Barba, University of Pavia, Italy

Accurate Joule Loss Estimation for Rotating Machines: An Engineering Approach

A High Performance DTC Strategy for Torque Ripple Minimization Using duty ratio control for SRM Drive

Equal Pitch and Unequal Pitch:

Dynamic Modeling of Surface Mounted Permanent Synchronous Motor for Servo motor application

4 Finite Element Analysis of a three-phase PM synchronous machine

Guangjin Li, Javier Ojeda, Emmanuel Hoang, Mohamed Gabsi, Cederic Balpe. To cite this version:

PERFORMANCE ANALYSIS OF DIRECT TORQUE CONTROL OF 3-PHASE INDUCTION MOTOR

THE INFLUENCE OF THE ROTOR POLE SHAPE ON THE STATIC EFICIENCY OF THE SWITCHED RELUCTANCE MOTOR

Analysis of performance of single-phase reluctance linear motor

Sensorless Control for High-Speed BLDC Motors With Low Inductance and Nonideal Back EMF

THE main area of application of the switched reluctance motor

AXIAL FLUX INTERIOR PERMANENT MAGNET SYNCHRONOUS MOTOR WITH SINUSOIDALLY SHAPED MAGNETS

Measurement of Flux Linkage and Inductance Profile of SRM

Study and Characterization of the Limiting Thermal Phenomena in Low-Speed Permanent Magnet Synchronous Generators for Wind Energy

Sensorless Control of Two-phase Switched Reluctance Drive in the Whole Speed Range

Unified Torque Expressions of AC Machines. Qian Wu

Lecture 7: Synchronous Motor Drives

Multiphase operation of switched reluctance motor drives

Massachusetts Institute of Technology Department of Electrical Engineering and Computer Science Electric Machines

Analytical Calculation of Air Gap Magnetic Field Distribution in Vernier Motor

Optimal Design of PM Axial Field Motor Based on PM Radial Field Motor Data

Stepping Motors. Chapter 11 L E L F L D

Research on Control Method of Brushless DC Motor Based on Continuous Three-Phase Current

A Direct Torque Controlled Induction Motor with Variable Hysteresis Band

Design and analysis of Axial Flux Permanent Magnet Generator for Direct-Driven Wind Turbines

Third harmonic current injection into highly saturated multi-phase machines

Mathematical Modelling of Permanent Magnet Synchronous Motor with Rotor Frame of Reference

Sunita.Ch 1, M.V.Srikanth 2 1, 2 Department of Electrical and Electronics, Shri Vishnu engineering college for women, India

Finite Element Analysis of Hybrid Excitation Axial Flux Machine for Electric Cars

Review of Basic Electrical and Magnetic Circuit Concepts EE

Lesson 17: Synchronous Machines

Definition Application of electrical machines Electromagnetism: review Analogies between electric and magnetic circuits Faraday s Law Electromagnetic

Electric Machines I Three Phase Induction Motor. Dr. Firas Obeidat

Generators for wind power conversion

Proceedings of the 6th WSEAS/IASME Int. Conf. on Electric Power Systems, High Voltages, Electric Machines, Tenerife, Spain, December 16-18,

The magnetic fields of inset Permanent Magnet Synchronous Motor

Loss Minimization Design Using Magnetic Equivalent Circuit for a Permanent Magnet Synchronous Motor

IEEE Transactions on Applied Superconductivity. Copyright IEEE.

Power density improvement of three phase flux reversal machine with distributed winding

Sensorless Speed Control for PMSM Based On the DTC Method with Adaptive System R. Balachandar 1, S. Vinoth kumar 2, C. Vignesh 3

Reluctance Synchronous Machine with a Particular Cageless Segmental Rotor

Inductance profile estimation of high-speed Switched Reluctance Machine with rotor eccentricity

Torque Ripple Reduction Using Torque Compensation Effect of an Asymmetric Rotor Design in IPM Motor

1439. Numerical simulation of the magnetic field and electromagnetic vibration analysis of the AC permanent-magnet synchronous motor

Matlab-Simulink Modelling of 6/4 SRM with Static Data Produced Using Finite Element Method

Lecture 8: Sensorless Synchronous Motor Drives

Offline Parameter Identification of an Induction Machine Supplied by Impressed Stator Voltages

Revision Guide for Chapter 15

1. Introduction. (Received 21 December 2012; accepted 28 February 2013)

Torque Performance and Permanent Magnet Arrangement for Interior Permanent Magnet Synchronous Motor

Independent Control of Speed and Torque in a Vector Controlled Induction Motor Drive using Predictive Current Controller and SVPWM

Torque Ripple Reduction Method with Minimized Current RMS Value for SRM Based on Mathematical Model of Magnetization Characteristic

AC Induction Motor Stator Resistance Estimation Algorithm

Simulation Results of a Switched Reluctance Motor Based on Finite Element Method and Fuzzy Logic Control

Research on Permanent Magnet Linear Synchronous Motor Control System Simulation *

Sensorless Field Oriented Control of Permanent Magnet Synchronous Motor

Loss analysis of a 1 MW class HTS synchronous motor

Motor-CAD combined electromagnetic and thermal model (January 2015)

Control of Wind Turbine Generators. James Cale Guest Lecturer EE 566, Fall Semester 2014 Colorado State University

Electromagnetics and Electric Machines Stefan Holst, CD-adapco

ECE 325 Electric Energy System Components 7- Synchronous Machines. Instructor: Kai Sun Fall 2015

University of Jordan Faculty of Engineering & Technology Electric Power Engineering Department

STAR-CCM+ and SPEED for electric machine cooling analysis

ISSN: (Online) Volume 2, Issue 2, February 2014 International Journal of Advance Research in Computer Science and Management Studies

Chapter 14. Reluctance Drives: Stepper-Motor and Switched- Reluctance Drives

EXPERIMENTAL COMPARISON OF LAMINATION MATERIAL CASE OF SWITCHING FLUX SYNCHRONOUS MACHINE WITH HYBRID EXCITATION

Permanent Magnet Wind Generator Technology for Battery Charging Wind Energy Systems

A simple model based control of self excited induction generators over a wide speed range

Preliminary Sizing Design of a 1 MW Low Duty Cycle Switched Reluctance Generator for Aerospace Applications

Modelling of Closed Loop Speed Control for Pmsm Drive

Step Motor Modeling. Step Motor Modeling K. Craig 1

PARAMETER SENSITIVITY ANALYSIS OF AN INDUCTION MOTOR

Design of the Forced Water Cooling System for a Claw Pole Transverse Flux Permanent Magnet Synchronous Motor

EXAMINATION OF RADIAL FORCE WITH FINITE ELEMENT METHOD IN SWITCHED RELUCTANCE MOTOR

MATLAB SIMULINK Based DQ Modeling and Dynamic Characteristics of Three Phase Self Excited Induction Generator

By: B. Fahimi. Department of Electrical & Computer Engineering University of Missouri-Rolla Tel: (573) Fax: (573) EML:

PROBLEMS - chapter 3 *

PCIM Europe 2011, May 2011, Nuremberg, Germany Paper 160

Mini-project report. Modelling and control of a variablespeed subsea tidal turbine equipped with permanent magnet synchronous generator.

Analysis of Idle Power and Iron Loss Reduction in an Interior PM Automotive Alternator

Analysis of Anti-Notch Method to the Reduction of the Cogging Torque in Permanent Magnet Synchronous Generator

Project 1: Analysis of an induction machine using a FEM based software EJ Design of Electrical Machines

DEVELOPMENT OF DIRECT TORQUE CONTROL MODELWITH USING SVI FOR THREE PHASE INDUCTION MOTOR

MODELING AND HIGH-PERFORMANCE CONTROL OF ELECTRIC MACHINES

Transcription:

Journal of ELECTRICAL ENGINEERING, VOL. 55, NO. 5-6, 24, 138 143 PRINCIPLE OF DESIGN OF FOUR PHASE LOW POWER SWITCHED RELUCTANCE MACHINE AIMED TO THE MAXIMUM TORQUE PRODUCTION Martin Lipták This paper deals with the design of a low-power four-phase SRM optimized to maximum torque performance. The design is made from the point of view of the space available for motor location. The outer dimensions such as outer stator diameter and effective length of iron are input values. The influence of operational parameters as well as the rest of geometrical dimensions upon motor performance is discussed. Some of the geometrical topologies of this SRM type are investigated by various speeds. The moment of switching is aimed to maximum torque production. The operation of the motor as well as motor converter and control strategy are described. K e y w o r d s: SRM design, torque production, one-pulse operation, chopping operation 1 INTRODUCTION The concept of a switched reluctance motor (SRM) was established in 1838 [1] but the motor could not be fully realized until the era of modern power electronic started. Since the 196s began its quick development and therefore in only last decades SRM is applied practically. The first commercial application of SRM in Europe and the US is described in [1, 2]. Following works also deal with the design of SRM with some various approaches. A procedure for the design of SRM based on output equations similar to those of conventional AC machines is described in [3]. There is given a selection of values and their verification, and a criterion to evaluate the operational limit is developed. An electromagnetic design for the high voltage and power SRM (5 MW, 9 V) including losses, efficiency and temperature computation was made in [4]. In [5] optimization of motor performances is carried out according to pole tooth width change. The system of 5 hp fuel-lube pump with SRM is described in [6]. It contains the design of the machine, power inverter, control circuit with both hardware and software part. In [7] a high torque density and high efficiency SRM is designed and built for vehicle propulsion. For optimization of the magnetic circuit for high density, the finite element method (FEM) was carried out. Much attention was paid to lowering the acoustic noise and increasing the overload capability. This paper deals with the design of a low power 4 phase SRM. The aim is to replace a universal motor used in home appliances by a SRM with the same outer dimensions. Therefore the design is made from the point of view of the space that is available for motor location. The outer dimensions such as outer stator diameter and effective length of iron are given values and the influence of operational parameters upon motor performance is observed. C D B r Fig. 1. Arcs of the stator β s and rotor β r flux linkage s magnetic field energy W f A A = f(i) B D magnetic field coenergy W phase current C poles Fig. 2. Display of magnetic field energy and coenergy The motor has salient poles both on the rotor and the stator. The field winding is on the stator and there is no winding on the rotor. The whole developed torque is reluctance only. SRM works with rotor position feedback University of Žilina in Žilina, Faculty of Electrical Engineering, Moyzesová 2, SK-1 26 Žilina, E-mail: Martin.Liptak@kete.utc.sk ISSN 1335-3632 c 24 FEI STU

Journal of ELECTRICAL ENGINEERING VOL. 55, NO. 5-6, 24 139.6 L (H).4 i =1A 2 W (J) i =15A 6 t (Nm) 4 i =15A 1 3.2 i =15A.5 i =1A 2 1 i =1A 1 2 ( ) 1 2 ( ) 1 2 ( ) Fig. 3. Phase inductance, coenergy and static torque vs rotor position of SRM with β s/β r = 2 /2 by various current 6 s ( ) 5 4 2 1 s + r = 6 A 1 2 4 5 6 r ( ) Fig. 4. Feasible triangle for 4-phase 8/6 SRM B C Unaligned position: When interpolar axis of the rotor is aligned with the stator poles of phase, the phase is in unaligned position (phase C in Fig. 1). The phase inductance is on minimum (L min ) and when it is displaced to either side, there appears a torque that tends to displace it towards the next aligned position. Effective torque zone: It is the angle through which one phase can produce torque comparable to the rated torque. It is also comparable to the lesser pole arc of two overlapping poles. Pole arcs: These are the widths of stator or rotor poles marked as β s and β r (Fig. 1 and Fig. 3). 16 3 TORQUE PRODUCTION AND COMPUTATION L max L min 12 8 4 2 2 2 s ( ) r ( ) 25 25 2 4 The torque in each of motor phases is created towards growing inductance. The poles of the rotor try to get aligned position. Each of the phase currents must be switched in line with areas of growing inductance (see Fig. 8). According to Fig. 2, the magnetic field coenergy W can be expressed as follows: 1 2 3 4 5 6 7 8 9 1 phase current (A) Fig. 5. L max/l min for various pole measurements and on continuous status. Rotor position sensing can be made by some optical sensor or electronically. The comparison of electronic position sensing and direct sensing is in [6]. In the next chapter some needed terms of SRM operation will be explained that will be used in this paper. 2 IMPORTANT TERMS Aligned position: When any pair of rotor poles is exactly aligned with the stator poles of the given phase, then the phase is said to be in the aligned position (in Fig. 1 it is the phase marked with A). The phase inductance is on maximum (L max ) and the phase produces no torque until it is displaced to either of sides. W = i1 ψdi (1) where ψ is the flux linkage of one phase. Then the instantaneous value of torque produced by one phase t is as follows: [ ] W t = (2) θ i=const where θ is the rotor position. Phase inductance, coenergy and the torque have been computed by the finite element method (FEM). They have been carried out as two-dimensional tables of static values L, W and t that are depending on the current as well as on rotor position. These values are graphically expressed for one of the investigated SRM in Fig. 3. Then the dynamic simulation in Matlab application has been performed to find the phase current as follows: [ di ( dt = U dc R + dl ) ] 1 dθ ω i L (3)

14 M. Lipták: PRINCIPLE OF DESIGN OF FOUR-PHASE LOW-POWER SWITCHED RELUCTANCE MACHINE AIMED TO... where U dc is the supply voltage, R and L is phase resistance and inductance, respectively, and ω is the angular speed of the rotor. The instantaneous value of inductance has been determined by two-dimensional interpolation from the mentioned two-dimensional table of inductance values for a known current i as well as rotor position θ. Therefore, besides i a new value of L is determined in each step of simulation. Similarly as L also the instantaneous value of torque produced by one phase has been determined from the two-dimensional table of static torque values. The overall produced torque has been given as an average value of the sum of all phase torques. When the number of phases and the outer dimensions of motor are given, the torque value depends on: rotor diameter, supply voltage and the parameters typical in SRM as follows: pole size, turn-on and turn-off angle. The influence of all these parameters on the torque production will be discussed in next chapter. 4 DESIGN OF GEOMETRICAL DIMENSIONS In this chapter the reasons for choosing the geometrical dimensions is shown and the influence of their variation is roughly given. Outer dimensions: The outer diameter of the stator and the effective length of iron has been chosen as 9 mm and 44 mm, respectively, because these are dimensions of a universal motor produced for some home applications, such as vacuum cleaners. Number of stator and rotor poles: In general, the stator has two or more poles per phase in order to balance the radial forces produced by each phase [2]. The most suitable type of four-phase SRM is topology 8/6 that means the motor winding. Two stator poles of one phase are located in opposite sides of stator and their windings are connected in series (it can be in parallel too). Rotor diameter: It is known that the torque rises with rotor diameter but enough space for phase winding on stator poles must be kept. According to [1] when saturation of the magnetic circuit is negligible, the torque produced by one phase can be simplified as follows: t = 1 dl i2 2 dθ. (4) The condition that saturation of the magnetic circuit is negligible is sufficiently valid at higher speeds of the motor. According to (4) it can be said that the saliency ratio of aligned and unaligned inductances (L max /L min ) is proportional to the developed torque. The rotor diameter has been chosen to 56 mm (Fig. 1), which is the biggest value that still makes possible to put the appropriate phase winding on the stator pole. It has been found by means of the above-mentioned method of torque computation that by decreasing the rotor diameter from 56 mm to 48 mm the ratio L max /L min decreases by 14.9 % and, hence, the average torque decreases, too. Similarly, if the number of rotor poles were higher than 6 at the same number of stator poles, the poles would be narrower and L max and, hence, (L max /L min ) would me smaller. Number of turns and wire cross-section: The crosssection of wire has been chosen to.45 mm 2. Then the maximum number of turns we can put into the given stator interpolar space is 1. That means 2 turns of each phase. The number of turns is adequate to the magnetomotive force and then also the torque produced by the phase. A higher number of turns means a smaller wire cross-section and then lower current loading. Therefore, these values should be chosen according to requirements of the used application. The value 1 turns per pole has been roughly chosen according to the mentioned universal motor. The phase resistance is 1.32 Ω at temperature 75 C. Length of air gap δ : This value should be chosen as small as possible because the whole magnetic circuit is magnetized from the stator side. That is why every increase of δ contributes to reduction of the efficiency of electromagnetic energy conversion. A higher δ brings about a lower phase inductance and, hence, impedance, and the motor draws a considerably higher magnetizing current and more input power from the power supply. The δ has been chosen to.2 mm, which is a sufficiently small value, but it is difficult to manufacture. It has been found that by rising of δ the change of torque is only negligible or the torque slowly decreases but the winding losses rapidly increase because of a higher magnetizing current. The width of stator and rotor arcs: The width of poles β s and β r can be chosen according to feasible triangle (Lawrenson, 198), which is shown in Fig. 4. By means of FEM, the static parameters for one phase have been established for five combinations of β s and β r and the influence of these pole sizes on the developed torque was explored. In Fig. 5 there is shown the ratio L max /L min vs current for these β s and β r combinations. Figure 6 shows the phase inductance for SRM with β s /β r = 2 /2 (which equals to point A in Fig. 4) in dependence on current and rotor position. In this picture the remarkable effect is seen of saturation on rising the current in aligned rotor position (see values of L at θ = ). In this way all geometrical dimensions are determined and now our interest will be focused on the converter topology and control strategy. 5 THE CONVERTER TOPOLOGY AND CONTROL STRATEGY There are many converter topologies for SRM operation, which are analyzed in [2], and it depends on specific application which topology will be used. An asymmetric converter circuit (Fig. 7) has been used to control the

Journal of ELECTRICAL ENGINEERING VOL. 55, NO. 5-6, 24 141 5 L A L without saturation effect L max L A L max 4 L (mh) U DC L min +U max U DC L min +U max 2 i * A -U max i max -U max 1 i A i A 2 4 6 2 8 1 1 I (A) 12 14 Fig. 6. Phase inductance variation of SRM T A T max on min off i max T max T A on min off i max im Fig. 9. Simulated operational waveforms of one from SRM phases ( β s = β r = 2, a) by chopping at 5 rpm, b) by one-pulse operation at 2 rpm T 1 D 2 U DC D 2 T 1 Phase A Fig. 7. Asymmetric power converter for SRM phase 6 T av (Nm) 4 3 2 1 25 25 2 2 4 2 2 s ( ) r ( ) 4 8 12 16 2 n (rpm) unaligned position voltage current inductance torque aligned position inductance Fig. 1. Average developed torque of all motor phases min = ( on conduction angle off max = ( P del (W) 2 s ( ) r ( ) 2 2 25 25 Fig. 8. Schematic waveforms of 4 phase 8/6 SRM 1 2 phase supply because of its simple topology. The influence of control strategy upon the developed torque can be investigated. Converter operation: When the rotor of given phase reaches turn-on angle θ on, the power switches T 1 and T 2 are on. At this moment the supply voltage U dc is applied to the phase as it is seen in Fig. 8. When the operating speed is high enough, the growing back-emf causes that the current will start to decrease. By reaching turn-off angle θ off the switches are off and the freewheel diodes D 1 and D 2 take the phase current, which quickly decreases because the phase voltage is U dc. In that condition the motor is supplied by +U dc along the whole conduction angle (θ on θ off ) and this mode is called one-pulse operation (see Fig. 9b). 2 4 4 8 12 16 2 n (rpm) Fig. 11. Power transferred from stator to rotor through air gap If the current achieves the value that is set as a required (reference) value i A (see Fig. 9a), one from the power switches is left on and another is switched off or on with some hysteresis according to whether the current is greater or less than i A. The phase voltage is or +U dc. This mode is called chopping current regulation. i A At a higher operating speed it is not possible to achieve current because of high back-emf. Both operations,

142 M. Lipták: PRINCIPLE OF DESIGN OF FOUR-PHASE LOW-POWER SWITCHED RELUCTANCE MACHINE AIMED TO... chopping current regulation as well as one-pulse operation, have been used in simulations depending on motor parameters and speed. The task of control strategy is to define θ on and θ off angles with aim of developing the maximum torque. This is the topic of the next sub-chapters. This control strategy is applied to computation of all the next waveforms (Figs.9, 1, 11). 5.1 The choice of conduction angles by chopping operation In Fig. 9a some simulated phase waveforms can be seen: inductance, current, voltage and developed torque for SRM with β s = β r = 2 and speed 5 rpm. These conditions represent chopping converter operation. The choice of θ on determines the profile and values of current and developed torque. It is important to choose the θ on in such a way that the current should have a maximum value in the beginning of the torque zone, which is an unaligned position. Then the voltage must be applied to phase at θ on in time before the unaligned rotor position?min. It is said that the motor works with advanced conduction angle and θ on has negative polarity (see Tab. 2). At SRM 8/6 with 6 poles on the rotor, the angle between two of pole axes is 36/6 = 6, which is also the value of period of phase current. Therefore the angle between aligned and next unaligned rotor position is 6/2 =. When the value of θ min angle is marked as, the value of θ max is as it is seen in Fig. 8. The θ off angle should be chosen as follows: At the angle of maximum inductance θ max the current should have a minimum value compared with the reference current. From the observations it can be said: Motoring torque developed at the phase current fall-down (θ off θ max ) must be higher than the total generating torque (θ max θ i and θ on θ min ). Generating torque appears at some periods of rotor position and its value is only negligible in comparison with the motoring torque. By this operation, SRM is able to obtain a multiple torque than a similar asynchronous or synchronous motor, but the following must be kept: Sufficient cooling is supported because of high winding losses. Motor works in interrupted operation and should not work in permanent operation. Reference current is limited to the value with which the coil temperature does not exceed the allowed value. Table 1. Maximum average torque (Nm) for various SRM and operating speed β s, β r n = 1 rpm 2 5 1 15 2 2, 2 3.571 3.538 3.42 2.17 1.262.962 25, 25 4.874 4.838 4.619 1.751 1.41.544 2, 3.523 3.46 3.28 1.457.88.465, 4.749 4.68 4.399 1.91.492.2715 2, 4 3.52 3.45 3.22.543.331.184 Table 2. θ on angle ( ) corresponding to the torque values in Tab. 1 β s, β r n = 1 rpm 2 5 1 15 2 2, 2 7 14 14 25, 25 1 2 6 1 15 14 2, 1 2 5 1 15 14, 1 2 7 12 14 14 2, 4 1 2 9 1 14 14 Table 3. θ off angle ( ) corresponding to the torque values in Tab. 1 β s, β r n = 1 rpm 2 5 1 15 2 2, 2 29 28 25 22 17 15 25, 25 28 27 25 2 15 15 2, 27 24 25 2 15 15, 27 26 25 18 15 15 2, 4 2 2 2 16 15 15 5.2 The choice of conduction angles by one-pulse operation This operation occurs when the current does not achieve the reference value i A because of high speed (Fig. 9b), because the back-emf has a higher value than the supply voltage. This will happen in every SRM above a certain speed (which is called base speed in [1]). The current waveform depends only on U DC value, magnetic circuit and conduction angle. In general, the same rules are valid at θ on and θ off angles optimization as by chopping. The advanced angle should be bigger to get a higher current while the inductance is small enough. In one period of phase current the supply voltage achieves 3 specific values as it is seen in Fig. 9b: 1. +U DC in interval of conduction angle (θ on θ off ) 2. U DC in interval when the current is carried by freewheeling diodes (θ off θ i ) 3., when the stored energy is quite exhausted and there is no current in the phase (θ i θ on ) By optimization of angles it has been found that the conduction angle and the interval of leading of freewheeling diodes occupies the whole period of phase current while the width of interval (θ i θ on ) is as small as possible. This interval is intentionally enlarged in Fig. 9b to make the picture more instructive. The waveform of the supply voltage is nearly square with values from +U DC to U DC. 6 RESULTS Motor operation has been investigated for speeds from 1 to 2 rpm for SRM with various pole arcs as it is seen in Tabs. 1 to 3. The supply voltage U dc has

Journal of ELECTRICAL ENGINEERING VOL. 55, NO. 5-6, 24 143 been chosen to 24 V dc and the reference current has been limited to 1 A. The 24 V is a chosen value in the range from 27.5 to 325 V. These voltages mean the lowest and the highest value of typical rectified 1 phase ac voltage from a main supply 2 V/5 Hz respectively. The load value has a negative and the capacity of the filtering capacitor has a positive influence on the value of average dc-bus voltage U dc. There is shown the developed torque and θ on and θ off optimized to get a maximum torque in Tabs. 1 to 3. In the tables the values printed in bold letters mean one-pulse operation. In Figs. 1 and 11 there are graphically demonstrated the results of torque as well as proportional air-gap power P δ = ωt av. It can be seen in Tab. 2 that almost all θ on angles are in advanced angle because of their negative signs. 6.1 Low speed operation increasing the U dc voltagwhich would lead to an increase of the drive size and cost. It must be noted that various converter types or control strategies can have some influence on the whole drive performances and the design of SRM should deal with other practical performances such as motor losses and efficiency and torque ripple. These have not been discussed in this paper but must be observed so that the motor could be really used in practice and replace other types of motors. Acknowledgement This work was supported by Science and Technology Assistance Agency under the contract No. APVT- 2-3962 and Grant No. 23 SP 51/28 9 /28 9 5. As it is seen from the results in Fig. 1, in the range from to 5 rpm, the torque of the investigated magnetic circuit topologies is limited by the motor current and its value is constant. The current is limited by chopping of dc voltage by means of presented control strategy. It is clear form Fig. 1 that the SRM 8/6 topologies with larger effective torque zone (β s /β r = 25/25 and / ) produce the torque 4.8 Nm that is 37 % higher value than in other cases. Therefore the topologies with larger effective torque zone produce higher torque because they have widest conduction angle and draw more input power from power supply. These two topologies have the value of effective torque zone according to [2] 25 and, respectively, while the others have it in value 2. 6.2 High speed operation The situation is changed in high-speed operation. The motor topology, which is still working in chopping operation, can produce more torque. The most favourable topology seems to be that with β s /β r = 2/2 (Fig. 1). This one works roughly with a constant output power in speed range from 6 to 2 rpm. This topology can draw one works roughly with a constant output power in speed range from 6 to 2 rpm. This topology can draw more current also in one-pulse operation because of lower phase inductance and lower produced back-emf. 7 CONCLUSION For a maximum developed torque, an unsuitable type of SRM is that with β s /β r = 2/4 which produces a high back-emf and has also a low torque zone. Other topologies can be more or less applicable. From Fig. 1 it is obvious that one with β s /β r = 25 /25 can achieve the highest torque at low speeds and β s /β r = 2 /2 at higher speeds and it is a question of application where the motor should be used. Some increase of the output power can be possible by additional filtering and then by References [1] MILLER, T. J. E. : Brushless Permanent-Magnet and Reluctance Motor Drives, Clarendon press, Oxford, 1989. [2] MILLER, T. J. E. : Switched Reluctance Motors and their Control, Magna Physics, Oxford, 1992. [3] KRISHNAN, R. ARUMUGAN, R. LINDSAY, J. F. : Design Procedure for Switched-Reluctance Motors, Industry Applications, IEEE Transactions on 24 No. 3 (1988). [4] MILES, A. R. : Design of a 5 MW, 9 V Switched Reluctance Motor, Energy Conversion, IEEE Transactions on 6 No. 3 (1991). [5] FAIZ, J. FINCH, J. W. : Aspects of Design Optimisation for Switched Reluctance Motors Energy Conversion,, IEEE Transactions on 8 No. 4 (1993). [6] FERREIRA, C. A. JONES, S. R. DRAGER, B. T. HEG- LUND, W. S. : Design and Implementation of a Five-hp, Switched Reluctance, Fuel-Lube, Pump Motor Drive for a Gas Turbine Engine, Power Electronics, IEEE Transactions on 1 No. 1 (1995). [7] RAHMAN, K. M. SCHULZ, S. E. : Design of High-Efficiency and High-Torque-Density Switched Reluctance Motor for Vehicle Propulsion, Industry Applications, IEEE Transactions on, 38 No. 6 (22). [8] LIPTÁK, M. HRABOVCOVÁV. RAFAJDUS, P. : Application of Switched Reluctance Motor in Domestic Appliances, EDPE international conference, High Tatras, Slovakia, 23. [9] RAFAJDUS, P. : Performances Investigation and Parameters Identification of a Switched Reluctance Machine, thesis, ŽU in Žilina, EF, KETE, 22. (in Slovak) [1] HRABOVCOVÁ, V. JANOUŠEK, L. RAFAJDUS, P. LIČKO, M. : Modern Electrical Machines, EDIS, ŽU in Žilina, 21. (in Slovak) Received 1 December 23 Martin Lipták (Ing) was born in Žilina, in 1979, graduated in electrical engineering from the University of Žilina, Slovakia in 22, where he is currently pursuing the PhD degree. He is a research assistant at the Department of Power Electronics. His research interests include switched reluctance machines in motoring and generating operation.