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Accelerating safety-certified motor control designs (Rev. A) Designing High-Performance and Power-Efficient Motor Control Systems White Paper (Rev. A) Hercules™ Microcontrollers: Real-time MCUs for safety-critical products Brushed DC Motor Drives All TI End-Equipment SolutionsThe 3-phase AC induction motor (ACIM) control reference design is based on Kinetis® V series MCUs and provides an example for 3-phase sensorless ACIM control solutions. The reference solution features Field Oriented vector Control (FOC) of rotor speed without need of any speed or position sensor, which improves reliability and cost of final design. The ACIM control reference solution is available for Kinetis KV3x and KV4x MCUs. Both MCUs are based on ARM® Cortex®-M4 cores running at 120 MHz on KV3x and 168MHz on KV4x. The KV3x features comprehensive analog integration that provides a high-performance solution for typical ACIM control applications with variable speed. The KV4x MCU represents high-performance solution offering exceptional precision, sensing and control for some of the most demanding applications in motor and power control.

The AC Motor Controller can control a standard 3-phased motor. There is a wide range of 3-phased AC motors and many different types of set-ups, so the motor controller can be used for many different applications. The motor controller has a simple array of control functions including forward, reverse and stop and variable speed.It has a position sensor mounted on it and can measure the position and thus move the motor to a dynamic position. This position is determined via a channel on the lighting desk. The motor will follow the channel and stop when it reaches the desired position. The AC Motor Controller is also available in a edition. Contents of the AC Motor Controller: 1 AC Motor Controller 370W 1 Limit switch bypass 1 Emergency switch bypass 2.0kg / 4.41 lbs 34.5 x 10.5 x 12.5 cm / 13.58 x 4.13 x 4.92 inches 210-250 Vac 47-63 Hz 3-phase 230 VAC, frequency regulation, 16 Khz switch frequency DMX 512 1990 + DMX 512A / 4-6 channels

5 pole XLR, in & link 2 channel tacho impulse maker. Potentiometer input 1-10k ohm 2.0 kg / 4.4 Lbs 345 x 105 x 125 mm/ 13,6 x 4,1 x 4,9 Inch Pricing and purchase options For info and quotations Drop us a line ➤ Find out how to access preview-only content ChapterAdvances in Electrical Engineering and Automation Volume 139 of the series Advances in Intelligent and Soft Computing pp 369-373Design and Implementation of Induction Motor Control * Final gross prices may vary according to local VAT. This thesis details design and implementation of three phase induction motor control system. The system is Atmega128 based 3-phase induction motor control. The controller drives the motor through a pulse-width modulated inverter which utilizes space vector modulation for the generation of its waveforms. The controller is implemented using Atmega128 microcontroller which connected to PC through HyperTerminal for monitoring purposes. It is used to drive a 3-hp motor with load.

The experimental results presented favorably compare speed transients between data taken from the 3-hp motor and data from a MATLAB simulation based on an analysis of the entire system. The motor fault status and normal status is also displayed. At the last we derived three phase induction motor successfully and the speed is controlled well. Share this content on Facebook Share this content on Twitter Share this content on LinkedIn Design and Implementation of Induction Motor Control Advances in Electrical Engineering and Automation Advances in Intelligent and Soft Computing Springer-Verlag GmbH Berlin Heidelberg Oil, Gas & Geosciences 1 AC Motor Controller 2200W 360-460 V AC / 47-63 Hz, 3 phase incl. null & earth 3-phase 400V AC, frequency regulation, 16 KHz switch frequency 2 kg ( 4.4 Lbs) 345 x 105 x 125 mm / 13,6 x 4.1 x 4,9 Inch Advances in Industrial Control Sensorless AC Electric Motor Control Robust Advanced Design Techniques and Applications

Glumineau, Alain, de Leon Morales, Jesus Explains how partial system knowledge can be avoided by making electric motor control robust Provides specific detailed treatment of the observability problem for trajectories of specific hard-to-measure system parameters Details genuine experimental results rather than being confined to simulations Included format: EPUB, PDF ebooks can be used on all reading devices Download immediately after purchase Free shipping for individuals worldwide Usually dispatched within 3 to 5 business days. This monograph shows the reader how to avoid the burdens of sensor cost, reduced internal physical space, and system complexity in the control of AC motors. Many applications fields—electric vehicles, wind- and wave-energy converters and robotics, among them—will benefit.Sensorless AC Electric Motor Control describes the elimination of physical sensors and their replacement with observers, i.e., software sensors.

Robustness is introduced to overcome problems associated with the unavoidable imperfection of knowledge of machine parameters—resistance, inertia, and so on—encountered in real systems. The details of a large number of speed- and/or position-sensorless ideas for different types of permanent-magnet synchronous motors and induction motors are presented along with several novel observer designs for electrical machines. Control strategies are developed using high-order, sliding-mode and quasi-continuous-sliding-mode techniques and two types of observer–controller schemes based on backstepping and sliding-mode techniques are described. Experimental results validate the performance of these observer and controller configurations with test trajectories of significance in difficult sensorless-AC-machine problems.Control engineers working with AC motors in a variety of industrial environments will find the space-and-cost-saving ideas detailed in Sensorless AC Electric Motor Control of much interest.

Academic researchers and graduate students from electrical, mechanical and control-engineering backgrounds will be able to see how advanced theoretical control can be applied in meaningful real systems. Alain Glumineau received the PhD degree in Automatic Control  in 1981 from  the school of Mechanical Engineering, Nantes University,  France. Since 1982 he has been with the IRCCyN Laboratory (http://www.irccyn.ec-nantes.fr) in Ecole Centrale de Nantes, France,  as Associate Professor then Full Professor. Alain Glumineau's current interests concern theoretical issues in nonlinear control with applications mainly to electric and pneumatic systems. Jesús de León Morales received the Ph.D. degree in Automatic Control from Claude Bernard Lyon 1 University, France, in 1992. Since 1993, he is a Professor of Electrical Engineering at Universidad Autonoma de Nuevo Leon, Mexico. He is currently working on applications of control theory, electrical machines, nonlinear observers and power systems.