Power factor

About: Power factor is a research topic. Over the lifetime, 60530 publications have been published within this topic receiving 768235 citations. The topic is also known as: electric power factor.

Space vector modulated three-phase to three-phase matrix converter with input power factor correction

Abstract: Analysis, design, and implementation of the space vector modulated three-phase to three-phase matrix converter with input power factor correction are presented. The majority of published research results on the matrix converter control are given an overview, and the one which employs simultaneous output-voltage and input-current space vector modulation, is systematically reviewed. The modulation algorithm is theoretically derived from the desired average transfer functions, using the indirect transfer function approach. The algorithm is verified through implementation of a 2 kVA experimental matrix converter driving a standard induction motor as a load. The switching frequency is 20 kHz. The modulator is implemented with a digital signal processor. The resultant output voltages and input currents are sinusoidal, practically without low-frequency harmonics. The input power factor is above 0.99 in the whole operating range.

Power Electronics and Ac Drives

Abstract: An integrated treatment of technological advances in power electronics Add this article to private library Remove from private library Submit corrections to this record View record in the new ADS and ac drives is presented. The topics include: power semiconductor devices, ac machines, phase-controlled converters and cycloconverters, voltage-fed inverter drives, current-fed inverter drives, slip powercontrolled drives, control of induction and synchronous machines, and microcomputer control. Both practical and theoretical aspects of the technology are addressed, and numerical examples are given. Bibtex entry for this abstract Preferred format for this abstract

A new mathematical model and control of a three-phase AC-DC voltage source converter

Abstract: A new mathematical model of the power circuit of a three-phase voltage source converter (VSC) was developed in the stationary and synchronous reference frames. The mathematical model was then used to analyze and synthesize the voltage and current control loops for the VSC. Analytical expressions were derived for calculating the gains and time constants of the current and voltage regulators. The mathematical model was used to control a 140-kW regenerative VSC. The synchronous reference-frame model was used to define feedforward signals in the current regulators to eliminate the cross coupling between the d and q phases. It allowed the reduction of the current control loops to first-order plants and improved their tracking capability. The bandwidths of the current and voltage-control loops were found to be approximately 20 and 60 times (respectively) smaller than the sampling frequency. All control algorithms were implemented in a digital signal processor. All results of the analysis were experimentally verified.

Direct power control of PWM converter without power source voltage sensors

Abstract: This paper proposes a novel control strategy of a pulsewidth modulation (PWM) converter with no power-source voltage sensors. The strategy has two main features to improve a total power factor and efficiency, taking harmonic components into account without detecting the voltage waveforms. One feature is a direct instantaneous power control technique for the converter, which has been developed to control the instantaneous active and reactive power directly by selecting the optimum switching state of the converter. The other feature is an estimation technique of the power-source voltages, which can be performed by calculating the active and reactive power for each switching state of the converter from the line currents. A digital-signal-processor-based experimental system was developed, and experimental tests were conducted to examine the controllability. As a result, it was confirmed that the total power factor and efficiency were more than 97% and 93% over the load power range from 200 to 1400 W, respectively. These results have proven the excellent performance of the proposed system.

Permanent Magnet Synchronous and Brushless DC Motor Drives

Abstract: PART I: Introduction to Permanent Magnets and Machines and Converters and Control Chapter 1 Permanent Magnets and Machines Permanent Magnets Arrangement of PMs Magnetization of PMs PM ac Machines Fundamentals of Synchronous Machines Fundamental Synchronous Machine Relationships Core Losses Resistive Losses Initial Machine Design Cogging Torque Basic Types of PMSMs Based on Flux Paths Vibration and Noise Chapter 2 Introduction to Inverters and Their Control Power Device DC Input Source DC to ac Power Conversion Real Power Reactive Power Need for Inverter Control Pulse Width Modulation Hysteresis Current Control Space Vector Modulation Inverter Switching Delay Input Power Factor Correction Circuit Four-Quadrant Operation Converter Requirements PART II: Permanent Magnet Synchronous Machines and Their Control Chapter 3 Dynamic Modeling of Permanent Magnet Synchronous Machines Real-Time Model of a Two-Phase PMSM Transformation to Rotor Reference Frames Three-Phase to Two-Phase Transformation Zero Sequence Inductance Derivation Power Equivalence Electromagnetic Torque Steady-State Torque Characteristics Models in Flux Linkages Equivalent Circuits Per Unit Model Dynamic Simulation Small-Signal Equations of the PMSM Evaluation of Control Characteristics of the PMSM Computation of Time Responses Space Phasor Model Chapter 4 Control Strategies for a Permanent Magnet Synchronous Machine Vector Control Derivation of Vector Control Drive System Schematic Control Strategies Chapter 5 Flux-Weakening Operation Maximum Speed Flux-Weakening Algorithm Direct Flux Weakening Parameter Sensitivity Model-Free (Parameter-Insensitive) Flux-Weakening Method Six-Step Voltage and Constant Back EMF Control Strategies for PMSM Direct Steady-State Evaluation Flux Weakening in SMPM and IPM Synchronous Machines Chapter 6 Design of Current and Speed Controllers Current Controller Speed Controller Chapter 7 Parameter Sensitivity and Compensation Introduction Parameter Compensation through Air Gap Power Feedback Control Parameter Compensation by Reactive Power Feedback Control Chapter 8 Rotor Position Estimation and Position Sensorless Control Current Model Adaptive Scheme Sensing by External Signal Injection Current Model-Based Injection Scheme Position Estimation Using PWM Carrier Components PART III: Permanent Magnet Brushless DC Machines and Their Control Chapter 9 PM Brushless DC Machine Modeling of PM Brushless DC Motor Normalized System Equations The PMBDCM Drive Scheme Dynamic Simulation Chapter 10 Commutation Torque Ripple and Phase Advancing Commutation Torque Ripple Phase Advancing Dynamic Modeling Chapter 11 Half-Wave PMBDCM Drives Split Supply Converter Topology C-Dump Topology Variable DC Link Converter Topology Variable Voltage Converter Topology with Buck-Boost Front-End Chapter 12 Design of Current and Speed Controllers Transfer Function of Machine and Load Inverter Transfer Function Transfer Functions of Current and Speed Controllers Current Feedback Speed Feedback Design of Controllers Chapter 13 Sensorless Control of PMBDCM Drive Current Sensing Position Estimation Chapter 14 Special Issues Torque Smoothing Parameter Sensitivity of the PMBDCM Drive Faults and Their Diagnosis Vibration and Noise