Your search keyword '"electromechanical system"' showing total 250 results

1. New Opportunities in Real-Time Diagnostics of Induction Machines.

Author

Baraškova, Tatjana, Kudelina, Karolina, and Shirokova, Veroonika

Subjects

*FREQUENCY changers, *REMOTE control, *FREQUENCY standards, *RELIABILITY in engineering, *PHYSICAL constants, *DYNAMIC models, *INDUCTION motors, *INDUCTION machinery

Abstract

This manuscript addresses the critical challenges in achieving high-accuracy remote control of electromechanical systems, given their inherent nonlinearities and dynamic complexities. Traditional diagnostics often suffer from data inaccuracies and limitations in analytical techniques. The focus is on enhancing the dynamic model accuracy for remote induction motor control in both closed- and open-loop speed control systems, which is essential for real-time process monitoring. The proposed solution includes real-time measurements of input and output physical quantities to mitigate inaccuracies in traditional diagnostic methods. The manuscript discusses theoretical aspects of nonlinear torque formation in induction drives and introduces a dynamic model employing vector control and speed control schemes alongside standard frequency control methods. These approaches optimize frequency converter settings to enhance system performance under varying nonlinear conditions. Additionally, the manuscript explores methods to analyze dynamic, systematic errors arising from frequency converter inertial properties, thereby improving electromechanical equipment condition diagnostics. By addressing these challenges, the manuscript significantly advances the field, offering a promising future with enhanced dynamic model accuracy, real-time monitoring techniques, and advanced control methods to optimize system reliability and performance. [ABSTRACT FROM AUTHOR]

Published

2024

2. Self-Sensing Electromechanical System Integrated with the Embedded Displacement Sensor.

Author

Wang, Shuxian, Liu, Shiyou, Su, Zuqiang, Liu, Linlin, and Tang, Zhi

Subjects

*INTELLIGENT control systems, *MEASUREMENT errors, *DETECTORS

Abstract

Conventionally, the electromechanical system requires the installation of auxiliary displacement sensors and only the amount on the drive part and motion end, which increases volume, cost, and measurement error in the system. This paper presents an integrated measurement method with a sensing head, which takes the equal division characteristics of mechanical structures as part of the sensor, thus, the so-called self-sensing system. Moreover, the displacement is measured by counting the time pulses. The sensing head is integrated with the entire electromechanical system, including the driving, transmitting, and moving parts. Thus, the integration of the sensing part is greatly improved. Taking the rotary table as a special example, and the sensing head embedded into each part of the system, displacement information is obtained by the common processing system and fused by the adaptive weighted average method. The results of the experiment show that the fusion precision of each component is higher than only the motor position information as the feedback. The proposed method is a practical self-sensing technology with significant volume reduction and intelligent control benefits in the industry, especially suitable for extremely small and narrow spaces. [ABSTRACT FROM AUTHOR]

Published

2024

3. A two‐phase features extraction approach for BRB based fault diagnosis of electromechanical system.

Author

Zhang, Zhenjie, Liu, Wenchao, Xiao, Gang, Xu, Xiaobin, Li, Meng, Cheng, Zhenbo, Zhang, Yuanming, Xu, Wenming, and Chang, Leilei

Subjects

*FEATURE extraction, *FAULT diagnosis, *PRINCIPAL components analysis, *WEIGHTED graphs, *TIME series analysis, *COMPLEX variables

Abstract

Summary Belief rule base (BRB) is an effective nonlinear relationship modeling approach. It has been widely used in the fault diagnosis of electromechanical systems. To improve the performance of the BRB‐based diagnostic model, a two‐phase features extraction approach called CNPCA based on complex network (CN) and principal component analysis (PCA) is proposed in this paper. In the first phase, the weighted visibility graph method is applied to transform the time series data of monitored variables into complex networks. Then the statistical attributes of the constructed networks are extracted as the initial features. In the second phase, the PCA method is used to process the initial features and the principal component features are obtained. After that, the CNPCA‐BRB diagnostic model for the electromechanical system is constructed. The experimental results of the elevator fault diagnosis show that the constructed diagnostic model outperforms better than the classical ones. It demonstrates that the CNPCA approach can ensure the integrity of fault information in the features and improve the separability of the fault features. [ABSTRACT FROM AUTHOR]

Published

2024

4. Measuring power consumption efficiency of an electromechanical system within a long-term period by fuzzy DEA and TOPSIS for sustainability.

Author

Wang, Yu-Jie

Subjects

*TOPSIS method, *DATA envelopment analysis, *CONSUMPTION (Economics), *FUZZY numbers, *DIESEL multiple units, *LINEAR programming

Abstract

To realize and handle power consumption details of sustainability, power consumption efficiency measurement for an electromechanical system within a long-term period is critical. Practically, data envelopment analysis (DEA) is useful to measure power consumption efficiency of an electromechanical system for yielding relative efficiencies of peer decision-making units (DMUs). Generally, traditional DEA scarcely considered undesirable outputs, and thus Hwang et al. developed DEA with linear programming to measure DMUs with undesirable outputs. Based on above, inputs, desirable outputs, and undesirable outputs of DMUs in this paper are assumed into triangular fuzzy numbers for grasping data uncertainty and obtaining more messages. Since inputs and outputs of DMUs in Hwang et al.'s were shown by crisp values, DMUs with fuzzy inputs and outputs were unable to be measured. Due to Kao and Liu's fuzzy efficiency measures in DEA, Hwang et al.'s is modified into fuzzy DEA to measure DMUs. In fuzzy DEA, DMUs composed of triangular fuzzy numbers are easily yielded their fuzzy efficiency values and then the efficiency values of fuzzy DMUs are rationally judged by corresponding judgement rules. With fuzzy DEA, efficient DMUs are clearly discriminated from inefficient ones, and then efficient DMUs are evaluated by fuzzy technique for order preference by similarity to ideal solution (fuzzy TOPSIS) to find the optimal DMU. According to fuzzy DEA and TOPSIS, the power consumption efficiency of an electromechanical system within a long-term period for sustainability are rationally measured and evaluated. [ABSTRACT FROM AUTHOR]

Published

2024

5. Neural networks-based adaptive fault-tolerant control for a class of nonstrict-feedback nonlinear systems with actuator faults and input delay.

Author

Kharrat, Mohamed and Alhazmi, Hadil

Subjects

ADAPTIVE control systems, NONLINEAR systems, FAULT-tolerant control systems, BACKSTEPPING control method, RADIAL basis functions, ACTUATORS, PSYCHOLOGICAL feedback

Abstract

This paper addresses the challenge of adaptive control for nonstrict-feedback nonlinear systems that involve input delay, actuator faults, and external disturbance. To deal with the complexities arising from input delay and unknown functions, we have incorporated Pade approximation and radial basis function neural networks, respectively. An adaptive controller has been developed by utilizing the Lyapunov stability theorem and the backstepping approach. The suggested method guarantees that the tracking error converges to a compact neighborhood that contains the origin and that every signal in the closed-loop system is semi-globally uniformly ultimately bounded. To demonstrate the efficacy of the proposed method, an electromechanical system application example, and a numerical example are provided. Additionally, comparative analysis was conducted between the Pade approximation proposed in this paper and the auxiliary systems in the existing method. Furthermore, error assessment criteria have been employed to substantiate the effectiveness of the proposed method by comparing it with existing results. [ABSTRACT FROM AUTHOR]

Published

2024

6. Neural networks-based adaptive fault-tolerant control for a class of nonstrict-feedback nonlinear systems with actuator faults and input delay

Author

Mohamed Kharrat and Hadil Alhazmi

Subjects

backstepping method, actuator faults, nonlinear systems, input delay, electromechanical system, Mathematics, QA1-939

Abstract

This paper addresses the challenge of adaptive control for nonstrict-feedback nonlinear systems that involve input delay, actuator faults, and external disturbance. To deal with the complexities arising from input delay and unknown functions, we have incorporated Pade approximation and radial basis function neural networks, respectively. An adaptive controller has been developed by utilizing the Lyapunov stability theorem and the backstepping approach. The suggested method guarantees that the tracking error converges to a compact neighborhood that contains the origin and that every signal in the closed-loop system is semi-globally uniformly ultimately bounded. To demonstrate the efficacy of the proposed method, an electromechanical system application example, and a numerical example are provided. Additionally, comparative analysis was conducted between the Pade approximation proposed in this paper and the auxiliary systems in the existing method. Furthermore, error assessment criteria have been employed to substantiate the effectiveness of the proposed method by comparing it with existing results.

Published

2024

7. Comparison of Magnetostrictive-Actuated Semi-Active Control Methods Based on Synchronized Switching.

Author

Li, An, Kobayashi, Yuusuke, Hara, Yushin, Otsuka, Keisuke, and Makihara, Kanjuro

Subjects

SWITCHING circuits, ACTUATORS

Abstract

Three distinct synchronized switching circuits based on a magnetostrictive actuator are compared in this paper to examine their control mechanisms and circuit characteristics. These circuits include a semi-active shunt circuit, a semi-active current inversion and amplification circuit, and a semi-active automatic current inversion and amplification circuit. Each circuit type employs an additional electronic switch. The synchronized switching method enables the rational control of the circuit current generated by the magnetostrictive actuator to fulfill any desired control strategy. Simulation and experimental results on a 10-bay truss structure reveal that the three circuits can effectively adjust the polarity of the induced current as needed. The three circuits are then compared to thoroughly analyze their unique characteristics and explain their respective advantages and dis-advantages. Using the comparison results, various options available for control circuit design are demonstrated. [ABSTRACT FROM AUTHOR]

Published

2024

8. CONSTRUCTION OF THE MATHEMATICAL MODEL OF MAGNETIC TRANSMISSION FOR AN AUTONOMOUS WIND POWER PLANT.

Author

Kovalenko, Mykhailo, Kovalenko, Iryna, Tkachuk, Ihor, Reutskyi, Mykola, Harford, Aaron, and Zhuk, Serhiy

Subjects

WIND power plants, ELECTRIC generators, PERMANENT magnet generators, MATHEMATICAL models, WIND speed, MAGNETIC moments

Abstract

The object of research is electromagnetic and mechanical processes in magnetic transmission for an autonomous wind power plant of small power. The use of magnetic transmission as part of an autonomous wind power plant makes it possible to improve the reliability and efficiency of such a system. In the current work, a study of magnetic transmission as part of an autonomous wind power plant was carried out to investigate the parameters and characteristics of magnetic transmission. This paper reports the construction of a numerical simulation mathematical model of a magnetic reducer operating as part of an autonomous wind power plant with a permanent magnet generator. The model takes into account discrete structure of internal and external rotors and modulator; changes in model parameters when input parameters change. It also takes into account losses, change of load angle and electromagnetic moment; the effect of changing the generator load. The built model of the magnetic reducer system differs in that the change in the generator load leads to a shift of the operating point on the mechanical characteristics of the rotor of the wind power plant (WPP). The model also works in the opposite direction: changes in wind parameters affect power, voltage, current, and electromagnetic moment. With the help of the model built, the parameters and characteristics of not only the magnetic reducer but also other components of the system were investigated. The efficiency at the output of the electric generator was determined, which is ≈75 % at a load of 2.0 kW. The magnetic transmission moment at a wind speed of 7.8 m/s for the high-speed rotor is 0.91 N∙m, and the low-speed rotor is 7.8 N∙m, which corresponds to a transmission ratio of 8.6. This expands opportunities for exploratory research. [ABSTRACT FROM AUTHOR]

Published

2024

9. Nonlinear dynamics of two electromechanical arms acting discontinuously on a balloon under the action of a sinusoidal excitation

Author

Armel Loic Ambassa Ebanda, Murielle Vanessa Tchakui, and Paul Woafo

Subjects

Electromechanical system, Discontinuity, Viscoelasticity, Multi-periodicity, Chaos, Compression, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Compression systems based electromechanical actuators require a good understanding of their dynamics for a better performance. This paper deals with the study of the nonlinear dynamics of an electromechanical system with two rotating arms subjected to a sinusoidal excitation for fluid compression purposes. The physical model integrating two balloons to be compressed by the arms alternately is presented and the mathematical equations traducing their dynamics are established. We emphasize on the influence of some control parameters namely the supply voltage, the discontinuity position and the viscoelastic ratio on the behaviour of the angular displacement of the arms. The study is also done by neglecting the inductance in the electrical part of the system. It is obtained that while the arms exhibit periodic motion during regular movement, compression of the balloons induces a shift to multi-periodic or chaotic dynamics, occasionally reverting to periodicity. Experimental and numerical simulation results demonstrate good agreement, with the R-system approximating more experimental outcomes than the RL-system. These findings hold significant implications for various environmental applications utilizing pump technology.

Published

2024

10. New Opportunities in Real-Time Diagnostics of Induction Machines

Author

Tatjana Baraškova, Karolina Kudelina, and Veroonika Shirokova

Subjects

condition monitoring, electromechanical system, induction motors, remote control, real-time monitoring, Technology

Abstract

This manuscript addresses the critical challenges in achieving high-accuracy remote control of electromechanical systems, given their inherent nonlinearities and dynamic complexities. Traditional diagnostics often suffer from data inaccuracies and limitations in analytical techniques. The focus is on enhancing the dynamic model accuracy for remote induction motor control in both closed- and open-loop speed control systems, which is essential for real-time process monitoring. The proposed solution includes real-time measurements of input and output physical quantities to mitigate inaccuracies in traditional diagnostic methods. The manuscript discusses theoretical aspects of nonlinear torque formation in induction drives and introduces a dynamic model employing vector control and speed control schemes alongside standard frequency control methods. These approaches optimize frequency converter settings to enhance system performance under varying nonlinear conditions. Additionally, the manuscript explores methods to analyze dynamic, systematic errors arising from frequency converter inertial properties, thereby improving electromechanical equipment condition diagnostics. By addressing these challenges, the manuscript significantly advances the field, offering a promising future with enhanced dynamic model accuracy, real-time monitoring techniques, and advanced control methods to optimize system reliability and performance.

Published

2024

11. Self-Sensing Electromechanical System Integrated with the Embedded Displacement Sensor

Author

Shuxian Wang, Shiyou Liu, Zuqiang Su, Linlin Liu, and Zhi Tang

Subjects

self-sensing, position detection, electromechanical system, integration, embedded, Chemical technology, TP1-1185

Abstract

Conventionally, the electromechanical system requires the installation of auxiliary displacement sensors and only the amount on the drive part and motion end, which increases volume, cost, and measurement error in the system. This paper presents an integrated measurement method with a sensing head, which takes the equal division characteristics of mechanical structures as part of the sensor, thus, the so-called self-sensing system. Moreover, the displacement is measured by counting the time pulses. The sensing head is integrated with the entire electromechanical system, including the driving, transmitting, and moving parts. Thus, the integration of the sensing part is greatly improved. Taking the rotary table as a special example, and the sensing head embedded into each part of the system, displacement information is obtained by the common processing system and fused by the adaptive weighted average method. The results of the experiment show that the fusion precision of each component is higher than only the motor position information as the feedback. The proposed method is a practical self-sensing technology with significant volume reduction and intelligent control benefits in the industry, especially suitable for extremely small and narrow spaces.

Published

2024

12. A unified methodology for the power efficiency analysis of physical systems.

Author

Tebaldi, Davide and Zanasi, Roberto

Subjects

*ELECTRIC motors, *ELECTRIC fields, *PLANETARY gearing, *LINEAR systems, *NONLINEAR systems, *HYDRAULIC drive

Abstract

In this paper, the problem of power efficiency evaluation for n -ports physical systems is investigated. The efficiency analysis that we perform highlights the necessary and sufficient conditions for the system to be passive, and outlines the guidelines for the efficiency maps computation. After addressing the problem from a formal point of view, the analysis is deepened for the case of two-ports linear and nonlinear physical systems, and for the cases of three and four-ports linear systems. The efficiency analysis and the computation of the efficiency maps are addressed as a function of the power variables characterizing all the energetic ports of the considered systems. Furthermore, the salient properties of the efficiency are highlighted and discussed. The theoretical analysis which is developed is then applied to some physical systems of interest for industries and engineers working in the electromechanical, hydraulic and automotive fields: a DC electric motor driving an hydraulic pump for the two-ports systems class, a single-stage planetary gear set for the three-ports systems class, and a Ravigneaux planetary gear set for the four-ports systems class. • Power efficiency modeling and efficiency maps computation for physical systems. • Interchangeable efficiency maps computed on the different systems energetic ports. • Highlighting of intrinsic properties and of a design parameter for two-ports systems. • Efficiency maps computation and intrinsic characteristics of planetary gear sets. [ABSTRACT FROM AUTHOR]

Published

2024

13. Adaptive finite time command filtered backstepping control design for a class of uncertain full state constrained strict‐feedback nonlinear systems.

Author

Soukkou, Yassine, Tadjine, Mohamed, and Nibouche, Mokhtar

Subjects

*ADAPTIVE control systems, *BACKSTEPPING control method, *NONLINEAR systems, *LYAPUNOV stability, *STABILITY theory, *LYAPUNOV functions, *PSYCHOLOGICAL feedback

Abstract

This article investigates an adaptive finite time command filtered backstepping control design for a class of uncertain full state constrained strict‐feedback nonlinear systems. The proposed adaptive control strategy is constructed by combining the barrier Lyapunov functions (BLFs), the adaptive command filtered backstepping control method and the finite time control theory. The BLFs are utilized to overcome the violation of the full state constraints. The proposed adaptive control approach is introduced to avoid the problem of the explosion of complexity and the compensating signals are designed to eliminate the influence of the filtering errors caused by the command filters. Moreover, based on the Lyapunov stability theory, it is proved that all the signals of the closed‐loop system are practical finite time stable and the full state constraints are not violated. To verify the efficiency of the proposed adaptive control scheme, simulation results are provided for electromechanical system. [ABSTRACT FROM AUTHOR]

Published

2023

14. Method for Defining Parameters of Electromechanical System Model as Part of Digital Twin of Rolling Mill.

Author

Gasiyarov, Vadim R., Radionov, Andrey A., Loginov, Boris M., Zinchenko, Mark A., Gasiyarova, Olga A., Karandaev, Alexander S., and Khramshin, Vadim R.

Subjects

DIGITAL twins, ROLLING-mills, DIGITAL control systems, TORQUE control, DIGITAL footprint, MASS transfer coefficients

Abstract

Creating digital twins of industrial equipment requires the development of adequate virtual models, and the calculation of their parameters is a complex scientific and practical problem. To configure and digitally commission automated drives, two-mass electromechanical system models are used. A promising area in which to implement such models is the development of digital shadows, namely drive position observers. Connecting virtual models for online data exchange predetermines the tightening of requirements for their parameter calculation accuracy. Therefore, developing accessible techniques for calculating electromechanical system coordinates is an urgent problem. These parameters are most accurately defined by experiments. The contribution of this paper is the proposition of a method for defining the two-mass system model parameters using the oscillograms obtained in the operating and emergency modes. The method is developed for the horizontal stand drives of a plate mill 5000 and is supported by numerical examples. The technique is universal and comprises calculating the rotating mass inertia torques, elastic stiffness and oscillation damping coefficients, and the time constants of the motor air gap torque control loop. The obtained results have been applied to the development of the elastic torque observer of the rolling stand's electromechanical system. A satisfactory coordinate recovery accuracy has been approved for both open and closed angular gaps in mechanical joints. Recommendations are given for the use of the method in developing process parameter control algorithms based on automated drive position observers. This contributes to the development of the theory and practice of building digital control systems and the implementation of the Industry 4.0 concept in industrial companies. [ABSTRACT FROM AUTHOR]

Published

2023

15. Comparison of Magnetostrictive-Actuated Semi-Active Control Methods Based on Synchronized Switching

Author

An Li, Yuusuke Kobayashi, Yushin Hara, Keisuke Otsuka, and Kanjuro Makihara

Subjects

electromechanical system, magnetostrictive actuator, semi-active vibration control, switching control, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Three distinct synchronized switching circuits based on a magnetostrictive actuator are compared in this paper to examine their control mechanisms and circuit characteristics. These circuits include a semi-active shunt circuit, a semi-active current inversion and amplification circuit, and a semi-active automatic current inversion and amplification circuit. Each circuit type employs an additional electronic switch. The synchronized switching method enables the rational control of the circuit current generated by the magnetostrictive actuator to fulfill any desired control strategy. Simulation and experimental results on a 10-bay truss structure reveal that the three circuits can effectively adjust the polarity of the induced current as needed. The three circuits are then compared to thoroughly analyze their unique characteristics and explain their respective advantages and dis-advantages. Using the comparison results, various options available for control circuit design are demonstrated.

Published

2024

16. PARAMETER OPTIMIZATION OF ELECTROMECHANICAL SYSTEM NETWORK INFORMATION PROCESSING BASED ON SUPPORT VECTOR MACHINE.

Author

Xiangyu Feng

Subjects

*ELECTROMECHANICAL devices, *SUPPORT vector machines, *PARAMETER estimation, *INFORMATION processing, *PARTICLE swarm optimization

Abstract

The management effectiveness and quality of electromechanical system information management are closely related to the safety production and financial advantages of businesses as it is the core of production management and safety management. This paper develops and establishes the electromechanical system information network from the perspective of electromechanical equipment management and recognizes the significance of parameter optimization in order to actively develop and establish the electromechanical equipment management information system network. Following an analysis of the benefits of the electromechanical equipment management information system network, the equipment management network structure and its connective equipment relationship system are built. Support Vector Machine (SVM) has demonstrated good performance in recent years in the research of electromechanical systems in tackling the classification problem of electromechanical equipment condition monitoring. This paper develops a simulation experiment to evaluate the performance of SVM in processing information from an electromechanical system network, optimizes the SVM's parameters using Particle Swarm Optimization (PSO), and examines the fault signals sent by the electromechanical system network in various time domains. The findings demonstrate that: (1) The SVM-based electromechanical system is capable of analyzing vibration signals by reducing noise, analyzing their frequency spectrum, and analyzing their axis trajectory. (2) The system is capable of identifying undiscovered defects, optimizing the classifier's parameters in accordance with sample characteristics, and assessing the system's efficacy. The main strategies and techniques for establishing company equipment information management are examined in this paper. The network of electromechanical equipment information management system may be built and used to effectively raise the calibre and degree of company equipment management. [ABSTRACT FROM AUTHOR]

Published

2023

17. Electromechanical System of Floating Wave Power Plant.

Author

Dar'enkov, A. B., Malyarov, D. A., Plekhov, A. S., and Kryukov, E. V.

Abstract

The basic electromechanical system of a floating wave power plant has been developed. Besides generating electricity, the power plant protects coastal structure or individual objects in the open sea. The formation of torque at the shaft of the power station is analyzed. The relationship between the capacitance of the energy store and the volume of the reservoir in the energy concentrator is considered. Models of the system components are developed. The relationship between the power of the electromechanical system's components and the rated power of the power station is determined, for the given operating conditions. [ABSTRACT FROM AUTHOR]

Published

2023

18. Neural-Networks-Based Adaptive Fault-Tolerant Control of Nonlinear Systems With Actuator Faults and Input Quantization

Author

Mohamed Kharrat, Moez Krichen, Loay Alkhalifa, and Karim Gasmi

Subjects

Adaptive control, nonlinear systems, Lyapunov function, actuator faults, quantization, electromechanical system, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In this work, the neural networks-based adaptive fault-tolerant control problem for nonlinear systems with actuator faults and input quantization is investigated. To approximate the nonlinear functions in the control system, radial basis function neural networks (RBFNN) are introduced. Additionally, an adaptive fault-tolerant controller is presented for nonlinear systems to compensate for the effects of input quantization and actuator fault using the backstepping approach and Lyapunov stability theory. It is demonstrated that with the proposed control strategy, all signals in the closed-loop system are semi-globally uniformly ultimately bounded and the tracking error converges to an arbitrarily small area of origin. The simulation results of an electromechanical system are shown to verify the validity of the control approach.

Published

2023

19. Development and study of a microprocessor automatic control system for a mono-switch tie type with a linear inductive electric motor and a discrete speed controller

Author

S. G. Buriakovskyi, L. V. Asmolova, An. S. Maslii, Ar. S. Maslii, and I. V. Obruch

Subjects

electric drive with linear inductive electric motor, electromechanical system, control system, discrete pid speed controller, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Introduction. The article is devoted to the development of the microprocessor automatic control system for a gearless controlled electric drive of a mono-switch tie based on a linear inductor electric motor. This solution provides control the position of the switch point, to carry out the transfer process with a smooth drive of shanks to the frame rail, to protect electric motor elements from overloads. Goal. development and study of the behavior of microprocessor automatic control system for mono-switch tie type with linear inductive electric motor and discrete PID speed controller which coefficients are adjusted according to Chin-Hrons-Reswick method to meet modern traffic safety requirements and improve operational reliability factors. Methodology. On the basis of electric drive theory, a kinematic line of a mono-switch tie type with nonlinear friction characteristic is presented. Using differential equation theory and Laplace transformation, a mathematic description of a linear inductor electric motor has been made. Using the z-transform method, a difference equation for describing a discrete PID speed controller is obtained, the coefficients of which are derived using the Chin-Hrons-Reswick method. A simulation mathematical model of the electric drive mono-switch tie type as the microprocessor automatic control system with linear inductive electric motor and discrete PID speed controller and nonlinear friction characteristic was built in MATLAB. Results. Simulation modelling of a mathematical model of the microprocessor automatic control system of the electric drive mono-switch tie type with the linear inductive electric motor and discrete PID speed controller and nonlinear friction characteristic have been developed and performed. Studies of dynamics of switch point movement have shown that, a drive time of less than 0.7 s at a constant speed motor armature of 0.2 and 0.3 m/s provides to meet modern requirements for railway switch points. The application of discrete PID speed controller has shown improved dynamics of switch point. Originality. First for the electric drive of the mono-switch tie type with linear inductive electric motor a mathematical model of the discrete PID speed controller and nonlinear friction characteristic as an object of speed control of switch point movement, has been developed. Practical value. Mathematical model of a railway track switch of the mono-switch tie type with linear inductive electric motor and discrete PID speed controller has been developed to carry out the control of the position of the switch point, process with a smooth drive them to the frame rail, to protect electric motor elements from overloads.

Published

2022

20. Adaptive neural control for nonlinear systems with sensor fault and input nonlinearities.

Author

Bali, Arun, Singh, Uday Pratap, and Kumar, Rahul

Subjects

*ADAPTIVE control systems, *NONLINEAR systems, *BACKSTEPPING control method, *RADIAL basis functions, *LYAPUNOV stability, *STABILITY theory

Abstract

In this work, the problem of adaptive neural control for nonlinear systems with input nonlinearities and sensor fault in non-strict feedback form is addressed. Input saturation and dead-zone exist in the nonlinear system simultaneously. The impact of external disturbances and sensor fault in nonlinear systems is considered. To approximate the unknown functions in the system, radial basis function neural networks are used. An adaptive neural controller is developed by using the approximation ability of the neural networks and the backstepping method. Based on Lyapunov stability theory, the proposed control method ensures that all signals in the closed-loop system are semi-globally uniformly ultimately bounded and that the output of the system follows the reference signal within a bounded error. Finally, to demonstrate the effectiveness of the proposed control method, one numerical example and a real-life example about an electromechanical system are provided. [ABSTRACT FROM AUTHOR]

Published

2023

21. Dynamics of the Rotating Arm of an Electromechanical System Subjected to the Action of Circularly Placed Magnets: Numerical Study and Experiment.

Author

Kouam Tagne, R., Woafo, P., and Awrejcewicz, J.

Subjects

*MAGNETIC torque, *MAGNETS, *PERMANENT magnets, *ROTATIONAL motion, *LYAPUNOV exponents, *BIFURCATION diagrams

Abstract

This paper considers the experimental and numerical study of an electromechanical arm powered by a DC motor and subjected to the action of permanent magnets. The magnetic torques arise from permanent magnets mounted at the free end of the arm and along a circle. The electrical subsystem is powered by two forms of input signal (DC and AC voltage sources). For each case, we determine the condition for complete rotation of the mechanical arm versus the parameters of the system such as the arm length, the number of magnets, and the frequency of the external signal. The nonlinear dynamics of the system is examined by means of time-histories, bifurcation diagrams, Lyapunov exponents and phase portraits. Chaotic and periodic dynamics are detected numerically and confirmed experimentally. [ABSTRACT FROM AUTHOR]

Published

2023

22. DYNAMIC ANALYSIS OF A MECHATRONIC DRIVE SYSTEM WITH AN INDUCTION MOTOR.

Author

YONGDI CAO and XIAOHONG LIU

Subjects

INDUCTION motors, INDUSTRIAL efficiency, VECTOR control, CELESTIAL reference systems, PERMEABILITY

Abstract

The paper presents research findings in the modelling and optimization of dynamic parameters of mechatronic systems with an induction motor. A mathematical model was developed to analyze currents in dynamic states of squirrel-cage rotors in the case of a line-to-line fault. The findings were verified experimentally using calculations for a 1.5 kW three-phase induction motor. The equations for a stationary 0x, 0y coordinate system relating to the stator were derived. The set of design variables selected in the optimization process contained parameters describing design features of the gear shafts and control units settings. [ABSTRACT FROM AUTHOR]

Published

2023

23. Adjustable Vibration Exciter Based on Unbalanced Motors.

Author

Osadchyy, Volodymyr, Nazarova, Olena, Hutsol, Taras, Glowacki, Szymon, Mudryk, Krzysztof, Bryś, Andrzej, Rud, Anatolii, Tulej, Weronika, and Sojak, Mariusz

Subjects

*CLOSED loop systems, *ELECTRIC drives, *VIBRATION (Mechanics), *POWER resources, *FREQUENCIES of oscillating systems

Abstract

In European industry, such as metallurgical, mining and processing, construction, food, and chemical, vibration exciters are used, which indicates their wide and, in some cases, unique technological capabilities. The most common are electromagnetic and unbalanced vibration exciters. The advantages of electromagnetic vibration exciters include the ability to control the amplitude of the vibration by changing the electrical power supplied; the disadvantages are high material consumption. However, unbalanced vibration exciters have low energy efficiency, which is associated with difficult start-up conditions and with an overestimated mechanical power of the vibration exciter in relation to the power required by the technology itself, which is due to the need to minimize the effect of the technological load on the operating mode of the vibrating unit. Adjusting the amplitude of the disturbing force of unbalanced vibration exciters, regardless of the vibration frequency, will make it possible to reduce the installed power of the unit by passing the resonant frequency with a minimum disturbing force and compensating for the effect of the process load by means of a closed-loop electric drive. In the course of the study, an analytical description of the interaction of the rotating unbalances located on a common movable platform was obtained. On the basis of these analytical dependencies, a mathematical model was developed that takes into account the dynamic characteristics of a frequency-controlled asynchronous electric drive of a closed-loop control system for the mutual arrangement of rotating unbalances. The simulation results confirmed the possibility of using the specified electric drive to control the oscillation amplitude directly in the process of operation of a four-unbalanced vibration exciter. A physical experiment was carried out to determine the transient processes of changing the angular velocity of an induction motor with an abrupt change in the frequency converter setting. On the basis of this experiment, the previously created mathematical model was refined in terms of describing the dynamic parameters of the electric drive. The proposed structure of the control system, the performance of which has been confirmed by mathematical modeling, makes it possible to implement an adjustable four-unbalanced vibration exciter using single commercially available asynchronous vibrators. [ABSTRACT FROM AUTHOR]

Published

2023

24. Development and Practical Implementation of Digital Observer for Elastic Torque of Rolling Mill Electromechanical System.

Author

Gasiyarov, Vadim R., Radionov, Andrey A., Loginov, Boris M., Karandaev, Alexander S., Gasiyarova, Olga A., and Khramshin, Vadim R.

Subjects

ROLLING-mills, ELECTRIC drives, DIGITAL footprint, BRAKE systems, ELECTRIC torque motors, NANOELECTROMECHANICAL systems

Abstract

The strategic initiative aimed at building "digital metallurgy" implies the introduction of diagnostic monitoring systems to trace the technical condition of critical production units. This problem is relevant for rolling mills, which provide the output and determine the quality of products of metallurgical companies. Making up monitoring systems requires the development of digital shadows and coordinate observers, the direct measurement of which is either impossible or associated with numerous difficulties. These coordinates include the spindle torque applied by the spring-transmitting torque from the motor to the rolling stand rolls. The development and research are conducted by the example of the electromechanical systems of the horizontal stand at the plate mill 5000. The stand electric drive characteristics are given, and the emergency modes that cause mechanical equipment breakdowns are analyzed that. The relevance of analyzing transient torque processes in emergency modes has been accentuated. The paper points to the shortcomings of the system for elastic torque direct measurement, including low durability due to the harsh operating conditions of precision sensors. It also highlights the need to install the measuring equipment after each spindle. The disadvantage of the previously developed observer is the function of calculating the electric drive speed derivative. This causes a decrease in noise immunity and signal recovery accuracy. The contribution of this paper is building a digital elastic torque observer that has advantages over conventional technical solutions, based on the theoretical and experimental studies. The technique for virtual observer adjustment was developed and tested in the Matlab-Simulink software package. For the first time, a comprehensive analysis was conducted for spindle elastic torques in emergency modes that caused equipment damage. An algorithm was developed for an emergency shutdown of a stand electric drive in the worst-case mode of strip retraction between work and backup rolls, due to the overlap of the strip on the roll. Further, the algorithm was tested experimentally. The criteria for diagnosing pre-emergencies was then justified. An adaptive motor-braking rate controller was developed. The developed observer and emergency braking system are in operation at the mill 5000. Long experimental research proved the efficiency of dynamic load monitoring and the reduction in the number of equipment breakdowns. [ABSTRACT FROM AUTHOR]

Published

2023

25. Predictive Maintenance of Electromechanical Systems Using Deep Learning Algorithms: Review.

Author

Abood, Azhar M., Nasser, Ahmed R., and Al-Khazraji, Huthaifa

Subjects

ELECTROMECHANICAL devices, DEEP learning, COMPUTER algorithms

Abstract

Predictive Maintenance (PM) is a major part of smart manufacturing in the fourth industrial revolution. The classical fault diagnosis approach for complex systems such as an electromechanical system is not effective. Taking the advantage of the successful implementations of PM together with Deep Learning (DL) methods replaces the conventional diagnosis methods with modern diagnosis methods. This study intends to aid experts, engineers, and technicians in different electromechanical systems in comprehending how the PM used DL methods to find the multi-fault diagnosis. In this direction, this paper presents a comprehensive review of recent works of DL techniques that are applied to PM for electromechanical systems by classifying the research according to equipment, fault, parameters, and method. To perform the review, 30 papers that are published in proceedings and journals are reviewed within a time window between the years 2016 to 2022. In the context of the electromechanical system, it is observed that motors are the most equipment selected for PM. Moreover, stator winding faults are found to be less selected than bearing for diagnosis of the unhealthy status of the motor. In terms of DL methods, the study reveals that AE, LSTM, and CNN are mostly used. In addition, poorly mixed models of DL methods are also noticed. Finally, finding the optimal design variable of the DL architecture was not widely explored. [ABSTRACT FROM AUTHOR]

Published

2022

26. Method for Defining Parameters of Electromechanical System Model as Part of Digital Twin of Rolling Mill

Author

Vadim R. Gasiyarov, Andrey A. Radionov, Boris M. Loginov, Mark A. Zinchenko, Olga A. Gasiyarova, Alexander S. Karandaev, and Vadim R. Khramshin

Subjects

digital twin, rolling mill, electromechanical system, position observer, two-mass model, parameters, Production capacity. Manufacturing capacity, T58.7-58.8

Abstract

Creating digital twins of industrial equipment requires the development of adequate virtual models, and the calculation of their parameters is a complex scientific and practical problem. To configure and digitally commission automated drives, two-mass electromechanical system models are used. A promising area in which to implement such models is the development of digital shadows, namely drive position observers. Connecting virtual models for online data exchange predetermines the tightening of requirements for their parameter calculation accuracy. Therefore, developing accessible techniques for calculating electromechanical system coordinates is an urgent problem. These parameters are most accurately defined by experiments. The contribution of this paper is the proposition of a method for defining the two-mass system model parameters using the oscillograms obtained in the operating and emergency modes. The method is developed for the horizontal stand drives of a plate mill 5000 and is supported by numerical examples. The technique is universal and comprises calculating the rotating mass inertia torques, elastic stiffness and oscillation damping coefficients, and the time constants of the motor air gap torque control loop. The obtained results have been applied to the development of the elastic torque observer of the rolling stand’s electromechanical system. A satisfactory coordinate recovery accuracy has been approved for both open and closed angular gaps in mechanical joints. Recommendations are given for the use of the method in developing process parameter control algorithms based on automated drive position observers. This contributes to the development of the theory and practice of building digital control systems and the implementation of the Industry 4.0 concept in industrial companies.

Published

2023

27. A survey of mechanical antennas applied for low-frequency transmitting

Author

Yong Cui, Chen Wang, Xiao Song, Ming Wu, Qianyun Zhang, Haiwen Yuan, and Zhihong Yuan

Subjects

Telecommunication engineering, Electromechanical System, Mechanical systems, Science

Abstract

Summary: The mechanical antenna (MA) is a new type of low-frequency (LF) transmitting antenna that generates an alternating electromagnetic (EM) signal through the mechanical movement of electric charges or magnetic dipoles, which is an interdisciplinary field including not only antennas but also electromagnetics, materials science, and dynamics. This principle of signaling makes it possible to break the constraints on physical dimensions decided by the wavelength of the traditional antenna so as to achieve LF communications with a smaller size and to provide a novel solution for long-range, underwater, and underground communications, navigation over the horizon, and geological exploring. Therefore, MA has become a research hotspot in the field of LF communications in recent 5 years, and this work proposed a survey on this topic of MA applied for LF transmitting. Firstly, we briefly review traditional low-frequency transmitting antennas and summarize the defect; then we introduce research progress of different implementation schemes for MA, comparing the signaling performance, advantages, and disadvantages of each scheme. Furthermore, we discuss the experiment setup, results, and related technology for MA including signal modulation methods. Finally, we explore prospects for future research about MA. This work presents a comprehensive and critical survey of small LF transmitters based on MA to help the readers to understand and identify the background, status, and challenges of research in this field.

Published

2023

28. Robust adaptive dynamic surface control scheme for a class of single‐input and single‐output uncertain nonlinear systems in strict‐feedback form.

Author

Soukkou, Yassine, Tadjine, Mohamed, Nibouche, Mokhtar, and Zhu, Quanmin

Subjects

*UNCERTAIN systems, *NONLINEAR systems, *LYAPUNOV stability, *ADAPTIVE control systems, *ROBUST control, *PSYCHOLOGICAL feedback, *STABILITY theory

Abstract

Summary: This article presents a robust adaptive dynamic surface control using σ‐modification adaptation laws for a class of single‐input and single‐output (SISO) uncertain nonlinear systems in strict‐feedback form with parametric uncertainties and external disturbances. The proposed scheme is developed by employing dynamic surface control based robust adaptive control technique. The key features of the approach are that, first, the problem of explosion of complexity inherent in the conventional adaptive backstepping control method is avoided, second, the proposed approach of σ‐modification adaptation laws gives fast and accurate parameter estimation performance, and, third, the closed‐loop signals of the system are proven to be uniformly ultimately bounded (UUB) by using the Lyapunov stability theory. We show the effectiveness of our approach by simulating an electromechanical system. [ABSTRACT FROM AUTHOR]

Published

2022

29. Development and study of a microprocessor automatic control system for a mono-switch tie type with a linear inductive electric motor and a discrete speed controller.

Author

Buriakovskyi, S. G., Asmolova, L. V., Maslii, An. S., Maslii, Ar. S., and Obruch, I. V.

Subjects

AUTOMATIC control systems, ELECTRIC motors, LINEAR control systems, ELECTRIC inductors, PID controllers, MICROPROCESSORS

Abstract

Introduction. The article is devoted to the development of the microprocessor automatic control system for a gearless controlled electric drive of a mono-switch tie based on a linear inductor electric motor. This solution provides control the position of the switch point, to carry out the transfer process with a smooth drive of shanks to the frame rail, to protect electric motor elements from overloads. Goal. Development and study of the behavior of microprocessor automatic control system for mono-switch tie type with linear inductive electric motor and discrete PID speed controller which coefficients are adjusted according to Chien-Hrones-Reswick method to meet modern traffic safety requirements and improve operational reliability factors. Methodology. On the basis of electric drive theory, a kinematic line of a mono-switch tie type with nonlinear friction characteristic is presented. Using differential equation theory and Laplace transformation, a mathematic description of a linear inductor electric motor has been made. Using the z-transform method, a difference equation for describing a discrete PID speed controller is obtained, the coefficients of which are derived using the Chien-Hrones-Reswick method. A simulation mathematical model of the electric drive mono-switch tie type as the microprocessor automatic control system with linear inductive electric motor and discrete PID speed controller and nonlinear friction characteristic was built in MATLAB. Results. Simulation modelling of a mathematical model of the microprocessor automatic control system of the electric drive mono-switch tie type with the linear inductive electric motor and discrete PID speed controller and nonlinear friction characteristic have been developed and performed. Studies of dynamics of switch point movement have shown that, a drive time of less than 0.7 s at a constant speed motor armature of 0.2 and 0.3 m/s provides to meet modern requirements for railway switch points. The application of discrete PID speed controller has shown improved dynamics of switch point. Originality. First for the electric drive of the mono-switch tie type with linear inductive electric motor a mathematical model of the discrete PID speed controller and nonlinear friction characteristic as an object of speed control of switch point movement, has been developed. Practical value. Mathematical model of a railway track switch of the mono-switch tie type with linear inductive electric motor and discrete PID speed controller has been developed to carry out the control of the position of the switch point, process with a smooth drive them to the frame rail, to protect electric motor elements from overloads. [ABSTRACT FROM AUTHOR]

Published

2022

30. A Novel Self-Actuated Linear Drive for Long-Range-of-Motion Electromechanical Systems.

Author

Dooley, Mason and Shen, Xiangrong

Subjects

MECHANICAL efficiency, RANGE of motion of joints, GENERATING functions, ACTUATORS, BELT drives, LUBRICATION & lubricants

Abstract

Obtaining powered linear movement over a long range of motion is a common yet challenging task, as the majority of linear actuators have limited ranges of motion as determined by their functioning mechanisms. In this paper, the authors present a novel belt-based self-actuated linear drive (B-SALD), in which a self-powered moving platform slides on a slotted track with essentially unlimited range of motion (only limited by the length of the track). Unlike the traditional rack-and-pinion mechanism, the B-SALD system uses a double-sided timing belt as the power-transmitting element. With the teeth on its inner surface, the belt interacts with a timing pulley for its own circulation; with the teeth on its outer surface, the belt interacts with a linear rail with parallel slots and drives the translation of the moving platform. The unique functioning mechanism generates multiple distinct advantages: no lubrication is required; the slotted track is simple and inexpensive to manufacture; and it provides an inherent compliance to buffer shock loading. With the experiments conducted on a preliminary prototype, it has been demonstrated that the B-SALD is able to provide accurate positioning and continuous motion control, an overall mechanical efficiency of 70% over the majority of the load range, and the capability of generating large force output in the desired manner. [ABSTRACT FROM AUTHOR]

Published

2022

31. Design and real-time implementation of a robust fractional second-order sliding mode control for an electromechanical system comprising uncertainties and disturbances

Author

Necdet Sinan Özbek

Subjects

Fractional-order control, Robustness, High-order sliding mode control, Electromechanical system, Experimental application, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The present article evaluates the design, analysis, and implementation of a novel fractional second-order sliding mode control scheme for an uncertain second-order system. The developed controller comprises a fractional-order proportional integral derivative sliding surface. The closed-loop stability analysis is performed by using the Lyapunov theorem. The proposed equivalent and switching control signals have been mathematically evaluated at various scenarios comprising uncertainties and disturbances. Several simulations are investigated by including model uncertainties, measurement noises, and disturbances. In addition, various real-time experiments are conducted with different operating conditions. To this end, a real-time reduced-order approximated model of an electromechanical system is constructed. The controller performance has been compared with a number of control techniques to illustrate the promising features of the proposed fractional-order controller. It can be reported that the transient response of the system, control signals applicability, and disturbance rejection capability are quite satisfactory when compared to recently presented control schemes. As a consequence, it is evident that the control scheme has the ability to reduce the chattering phenomenon and increase the system’s robustness.

Published

2022

32. Electromechanical System of Floating Wave Power Plant

Author

Dar’enkov, A. B., Malyarov, D. A., Plekhov, A. S., and Kryukov, E. V.

Published

2023

33. PID sliding surface-based adaptive dynamic second-order fault-tolerant sliding mode control design and experimental application to an electromechanical system.

Author

Aydin, Merve Nilay and Coban, Ramazan

Subjects

*SLIDING mode control, *ELECTROMECHANICAL devices, *EXPERIMENTAL design, *CLOSED loop systems

Abstract

In this paper, an adaptive dynamic PID sliding surface-based second-order fault-tolerant sliding mode controller for speed control of an electromechanical system is proposed. The paper aims to show how to utilise the robust properties of second-order adaptive dynamic sliding mode control on the problem of structural damage fault. Structural damage fault is apparently studied less than faults of actuator and sensor. Because of this reason, this study focuses on the structural damage fault. In order to solve the chattering which is the main problem of first-order/ traditional SMC, second-order controller is designed. The Lyapunov theorem is used for affirming the design and stability of the closed-loop system. Experimental results show that the control system with the proposed controller is easily implemented. Also, the proposed fault-tolerant controller, concerning parametric uncertainties and disturbances, acquire suitable tracking performance and shows more robustness than the traditional SMC. [ABSTRACT FROM AUTHOR]

Published

2022

34. Diagnostics of Combined Mechanical and Electrical Faults of an Electromechanical System for Steady and Ramp-Up Speeds.

Author

Gangsar, Purushottam, Chouksey, Manoj, Parey, Anand, and Ali, Zheeshan

Abstract

Purpose: This study presents the diagnosis of combined or multiple mechanical and electrical faults in an electromechanical system based on support vector machine (SVM). Methods: Time and continuous wavelet transform (CWT)-based features have been extracted from vibration and current signals acquired from ten combined fault conditions from an experimental test rig. Then, SVM algorithm based methodology has been developed for diagnosis the fault conditions. Results: Results show that the combination of vibration and current signal improves the performance of the diagnosis especially at high-load condition in comparison to vibration or current signal alone. The diagnosis is found to be effective with both time domain and CWT features; however, it is slightly better with the CWT features in comparison to time domain-based features. Conclusion: The performance of the diagnosis is found to be better at higher load with both time domain and CWT features. Moreover, the present methodology does not perform well with ramp-up speed conditions. [ABSTRACT FROM AUTHOR]

Published

2022

35. Attractor based performance characterization and reliability evolution for electromechanical systems.

Author

Chen, Wen-Bin, Li, Xiao-Yang, and Kang, Rui

Subjects

*EQUATIONS of state, *PHYSICAL mobility, *MOTIVATION (Psychology), *EQUATIONS

Abstract

[Display omitted] • Attractor based performance and reliability modeling of EMSs are proposed. • Physical relationship between EMS reliability and design parameters is constructed. • Attractor based reliability models can be quickly transferred to multi-type EMSs. • Collinear phenomena on the Poincaré section during BLDCM degradation is discovered. • A universal framework of performance and reliability modeling of EMSs is provided. Electromechanical systems (EMS) possess multi-type, fast-iteration, and customized characteristics in modern industry and are usually required for high reliability. To meet the reliability requirements of EMSs, it is essential to identify the physical relationship between the design parameters and reliability of EMSs, i.e., the physical reduction and holistic ability of reliability. However, current reliability models based on physical principles are costly and highly specific, making them lose the transferability to other EMSs and resulting in high computational and time costs when applied to multi-type EMSs. Nevertheless, current reliability models with transferability often lack clear physical reduction and holistic ability, which limits their ability to elucidate the reliability mechanisms in EMSs. Motivated by the above issue, an attractor based performance characterization and reliability evolution modeling method for EMSs is proposed. Firstly, we construct operational state equations of EMSs based on physical principles, discover the attractor as a universal characteristic in EMS operational states, and conduct attractor modeling to characterize EMS performance under constant and periodic external forces. Then, the attractor based reliability evolution modeling is conducted, including attractor based margin, degradation, and measurement equations of EMSs. Two typical EMSs including BLDCMs and resonant circuits are used for the case study, and their attractor based reliability equations physically related to the physical properties, functional thresholds, degradation, and uncertainties are established, revealing the combination of the physical reduction and holistic ability with the transferability of reliability. This work also provides a universal framework for EMS reliability modeling and is conducive to exploring the universality of EMS reliability. [ABSTRACT FROM AUTHOR]

Published

2025

36. Mathematical modelling of transients in the electric drive of the turnout of the mono-sleeper type with switched-inductor motor

Author

S. G. Buriakovskyi, A. S. Maslii, L. V. Asmolova, and N. T. Goncharuk

Subjects

switched-inductor electric drive, electromechanical system, control system, fuzzy speed controller, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Introduction. The study is devoted to the development of the functionality of a railway track switch by introducing a switched-inductor electric drive. This solution justifies simplifying the mechanical part of the switches by changing the gearbox to a ball-screw and locating the all kinematic line of the switches on the mono-sleeper type. Goal. A study of the mono-sleeper turnout type behaviour to meet modern traffic safety requirements and improve operational reliability factors. Methodology. Based on electric drive theory, a kinematic line of a mono-switch turnout type with nonlinear friction characteristic is presented. Using differential equation theory and Laplace transformation, a mathematic description of a four-phase switched-inductor motor with ball-screw in a mechanical line of a single-mass electromechanical system has been made. A simulation mathematical model of the electric drive of mono-sleeper turnout type as the control system with a switched-inductor motor and nonlinear friction characteristic was built in MATLAB. Results. Simulation modelling of a mathematical model of a mono-sleeper turnout type with a switched-inductor motor and ball-screw gear has been developed and implemented. Studies of dynamics of turnout point movement have shown that, in contrast to the motors used today, the switched-inductor motor makes it possible to simplify the mechanical part of the drive, which leads to reduced time spent on laying and maintenance of turnout points, and therefore makes the design more reliable. The application of PID controller and fuzzy speed controller has shown improved dynamics of turnout point, while the fuzzy PID controller provides better performance of the set values and turnout point movements. Originality. First developed a mathematical model of the electric drive of the mono-sleeper turnout type, taking into account nonlinear friction characteristic, as an object of speed control of turnout point movement, is developed. Practical value. The developed mathematical model of a railway track turnout of the mono-sleeper type with a switched-inductor motor and ball-screw gear enables more efficient use of a microprocessor control system, creation of promising electric motor protection means and control of a turnout point.

Published

2021

37. Evaluation of Bone Consolidation in External Fixation with an Electromechanical System.

Author

Paulino, Maria F., Roseiro, Luis M., Balacó, Inês, Neto, Maria A., and Amaro, Ana M.

Subjects

EXTERNAL fixators, HUMAN anatomical models, BONE growth, ORTHOPEDISTS, HEALING, FRACTURE healing

Abstract

Featured Application: The findings of this work can help doctors decide when it is appropriate to remove the external fixator. The monitoring of fracture or osteotomy healing is vital for orthopedists to help advise, if necessary, secondary treatments for improving healing outcomes and minimizing patient suffering. It has been decades since osteotomy stiffness has been identified as one main parameter to quantify and qualify the outcome of a regenerated callus. Still, radiographic imaging remains the current standard diagnostic technique of orthopedists. Hence, with recent technological advancements, engineers need to use the new branches of knowledge and improve or innovate diagnostic technologies. An electromechanical system was developed to help diagnose changes in osteotomy stiffness treated with the external fixator LRS Orthofix®. The concept was evaluated experimentally and numerically during fracture healing simulation using two different models: a simplified model of a human tibia, consisting of a nylon bar with a diameter of 30 mm, and a synthetic tibia with the anatomical model from fourth-generation Sawbones®. Moreover, Sawbones® blocks with different densities simulated the mechanical characteristics of the regenerated bone in many stages of bone callus growth. The experimental measurements using the developed diagnostic were compared to the numerically simulated results. For this external fixator, it was possible to show that the displacement in osteotomy was always lower than the displacement prescribed in the elongator. Nevertheless, a relationship was established between the energy consumption by the electromechanical system used to perform callus stimulus and the degree of osteotomy consolidation. Hence, this technology may lead to methodologies of mechanical stimulation for regenerating bone, which will play a relevant role for bedridden individuals with mobility limitations. [ABSTRACT FROM AUTHOR]

Published

2022

38. A Software Product for Improving Efficiency Control of the Electric Drive of a Shearer.

Author

Babokin, G. I., Shpreher, D. M., and Zelenkov, A. V.

Abstract

A software product designed to improve the efficiency and automation of control decisions during the operation of a shearer in real conditions is presented. The purpose of the paper is to identify the shapes of the curves characterizing the type of external influence on the electromechanical system in the form of a jump in the resistance of coal to cutting, as well as to study the reliability and error indicators of the algorithm for recognizing the type of input action according to the multiparameter response of this system (in the sections of the current inrush of the asynchronous cutting motor and changes in shearer feed speed). Typical tasks to be performed are graphical analysis of response curves for heuristic analysis and selection of the length of the fragment to be recognized depending on the variability of the curves when the level of the jump in the cutting resistance of coal changes, creation of a training sample or a database of curve templates for various combinations of PI-controller parameters and levels of step action or a jump in coal cutting resistance, single recognition of curve fragments using a software module, and study of the statistical properties of predictive models in various conditions of the system functioning. The software product allows investigating the issues of noise immunities of recognition models and the sufficiency of the observation interval to obtain reliable forecasts for the jump in coal cutting resistance. Fields of application include control systems, diagnostics and information processing of electromechanical objects, and cleaning mechanized complexes. [ABSTRACT FROM AUTHOR]

Published

2022

39. Issues of Multi-Motor Electric Drive Dynamics through the Example of Converter Tilting Mechanism

Author

V. F. Borisenko, V. A. Sidorov, and A. I. Zemlyansky

Subjects

converter, electromechanical system, shafting, dynamics, design model, thermal and vibration diagnostics, Mining engineering. Metallurgy, TN1-997

Abstract

Many heavy machines and mechanisms of mining and metallurgical industry, for example, basic-oxygen converters (BOCs), are equipped with multi-motor electric drive. Reducing the influence of the disadvantages characteristic of a branched multi-connected system is possible by creating control systems based on mathematical models of the considered electromechanical systems (EMS). The full mathematical model takes into account the number of EMS motors, gear backlashes, elasticity of shafting, the effect of dissipative forces, etc. Disadvantage of this approach is complexity of such models, which leads to high computational costs and time expenditure for their implementation. To analyze dynamic processes arising under acceleration and deceleration conditions of the electromechanical system of the converter tilting mechanism, it is proposed to use a simplified equivalent simulation model, which would take into account changing the EMS natural oscillation frequency for any operation conditions based on process and design features. Based on the simulation model analysis, it was concluded that it is necessary to assess mechanical loads in the system by comparing their current and basis values, as well as taking into account the damping properties of the electric drive. To reduce dynamic loads, it is proposed to form a law of changing the control voltage using an intensity generator, which reduces the risks of occurrence of elastic moments, significantly exceeding those permissible for this class of mechanisms. The results of thermal and vibration diagnostics for assessing malfunctions of key units of the converter tilting mechanism, as well as assessing the system behavior based on the Matlab Simulink model with varying shafting elasticity and normalized gear backlashes, showed significant effect of the latters on the dynamic loads.

Published

2020

40. Synthesis of adaptive electric drive control system of horizontal looper

Author

Iosif Breido and Yelena Kuntush

Subjects

electromechanical system, horizontal looper, synthesis of damping system, variable inertia moment, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The article presents studies on the electromechanical system of a metallurgical horizontal looper in the steelmaking industry. During the operation of this unit, parameters in the system changes due to variations of length and mass of the steel strip, these variations significantly change elastic properties and reduce moments of inertia. Various methods of combating elastic vibrations in electromechanical systems are analyzed in this article. The article presents a description of experiments with a horizontal looper. A mathematical model for two extreme positions of the unit was developed based on experimental results. Simulation experiments were made and their results are presented. A new control system structure is proposed to reduce vibrations in the electromechanical system of a horizontal looper. A power-up sensor, adjuster and velocity derivative feedback were added into the model structure. The proposed feedback link structure takes into account the change of steel strip length. From the experimental data it follows that the proposed system provides effective damping of mechanical vibrations in the steel strip if its length during operation is changed.

Published

2020

41. Comparative evaluation of classic and fuzzy control algorithms for electric drive system of multi-point molding of products of double curvature

Author

N. E. Deryuzhkova, V. A. Solovyev, V. V. Teterin, and D. V. Urasov

Subjects

interconnected control system, electromechanical system, fuzzy regulation, Engineering (General). Civil engineering (General), TA1-2040

Abstract

One of the methods for manufacturing double curvature parts used in the manufacture of aircraft and ship bodies is the bending of sheet material on a molding machine, which is a complex mechanism. The article discusses the use of various control algorithms for a multi-point molding system. A comparative analysis of the classic and fuzzy control algorithms is performed. Based on the research, it is concluded that it is advisable to use one or another control algorithm.

Published

2020

42. Development and Practical Implementation of Digital Observer for Elastic Torque of Rolling Mill Electromechanical System

Author

Vadim R. Gasiyarov, Andrey A. Radionov, Boris M. Loginov, Alexander S. Karandaev, Olga A. Gasiyarova, and Vadim R. Khramshin

Subjects

rolling mill, electromechanical system, elastic torque, observer, emergency modes, emergency braking, Production capacity. Manufacturing capacity, T58.7-58.8

Abstract

The strategic initiative aimed at building “digital metallurgy” implies the introduction of diagnostic monitoring systems to trace the technical condition of critical production units. This problem is relevant for rolling mills, which provide the output and determine the quality of products of metallurgical companies. Making up monitoring systems requires the development of digital shadows and coordinate observers, the direct measurement of which is either impossible or associated with numerous difficulties. These coordinates include the spindle torque applied by the spring-transmitting torque from the motor to the rolling stand rolls. The development and research are conducted by the example of the electromechanical systems of the horizontal stand at the plate mill 5000. The stand electric drive characteristics are given, and the emergency modes that cause mechanical equipment breakdowns are analyzed that. The relevance of analyzing transient torque processes in emergency modes has been accentuated. The paper points to the shortcomings of the system for elastic torque direct measurement, including low durability due to the harsh operating conditions of precision sensors. It also highlights the need to install the measuring equipment after each spindle. The disadvantage of the previously developed observer is the function of calculating the electric drive speed derivative. This causes a decrease in noise immunity and signal recovery accuracy. The contribution of this paper is building a digital elastic torque observer that has advantages over conventional technical solutions, based on the theoretical and experimental studies. The technique for virtual observer adjustment was developed and tested in the Matlab-Simulink software package. For the first time, a comprehensive analysis was conducted for spindle elastic torques in emergency modes that caused equipment damage. An algorithm was developed for an emergency shutdown of a stand electric drive in the worst-case mode of strip retraction between work and backup rolls, due to the overlap of the strip on the roll. Further, the algorithm was tested experimentally. The criteria for diagnosing pre-emergencies was then justified. An adaptive motor-braking rate controller was developed. The developed observer and emergency braking system are in operation at the mill 5000. Long experimental research proved the efficiency of dynamic load monitoring and the reduction in the number of equipment breakdowns.

Published

2023

43. Adjustable Vibration Exciter Based on Unbalanced Motors

Author

Volodymyr Osadchyy, Olena Nazarova, Taras Hutsol, Szymon Glowacki, Krzysztof Mudryk, Andrzej Bryś, Anatolii Rud, Weronika Tulej, and Mariusz Sojak

Subjects

vibration exciter, unbalance, angular position, mathematical model, control system, electromechanical system, Chemical technology, TP1-1185

Abstract

In European industry, such as metallurgical, mining and processing, construction, food, and chemical, vibration exciters are used, which indicates their wide and, in some cases, unique technological capabilities. The most common are electromagnetic and unbalanced vibration exciters. The advantages of electromagnetic vibration exciters include the ability to control the amplitude of the vibration by changing the electrical power supplied; the disadvantages are high material consumption. However, unbalanced vibration exciters have low energy efficiency, which is associated with difficult start-up conditions and with an overestimated mechanical power of the vibration exciter in relation to the power required by the technology itself, which is due to the need to minimize the effect of the technological load on the operating mode of the vibrating unit. Adjusting the amplitude of the disturbing force of unbalanced vibration exciters, regardless of the vibration frequency, will make it possible to reduce the installed power of the unit by passing the resonant frequency with a minimum disturbing force and compensating for the effect of the process load by means of a closed-loop electric drive. In the course of the study, an analytical description of the interaction of the rotating unbalances located on a common movable platform was obtained. On the basis of these analytical dependencies, a mathematical model was developed that takes into account the dynamic characteristics of a frequency-controlled asynchronous electric drive of a closed-loop control system for the mutual arrangement of rotating unbalances. The simulation results confirmed the possibility of using the specified electric drive to control the oscillation amplitude directly in the process of operation of a four-unbalanced vibration exciter. A physical experiment was carried out to determine the transient processes of changing the angular velocity of an induction motor with an abrupt change in the frequency converter setting. On the basis of this experiment, the previously created mathematical model was refined in terms of describing the dynamic parameters of the electric drive. The proposed structure of the control system, the performance of which has been confirmed by mathematical modeling, makes it possible to implement an adjustable four-unbalanced vibration exciter using single commercially available asynchronous vibrators.

Published

2023

44. Nonlinear dynamics of two electromechanical arms acting discontinuously on a balloon under the action of a sinusoidal excitation.

Author

Ebanda ALA, Tchakui MV, and Woafo P

Abstract

Compression systems based electromechanical actuators require a good understanding of their dynamics for a better performance. This paper deals with the study of the nonlinear dynamics of an electromechanical system with two rotating arms subjected to a sinusoidal excitation for fluid compression purposes. The physical model integrating two balloons to be compressed by the arms alternately is presented and the mathematical equations traducing their dynamics are established. We emphasize on the influence of some control parameters namely the supply voltage, the discontinuity position and the viscoelastic ratio on the behaviour of the angular displacement of the arms. The study is also done by neglecting the inductance in the electrical part of the system. It is obtained that while the arms exhibit periodic motion during regular movement, compression of the balloons induces a shift to multi-periodic or chaotic dynamics, occasionally reverting to periodicity. Experimental and numerical simulation results demonstrate good agreement, with the R-system approximating more experimental outcomes than the RL-system. These findings hold significant implications for various environmental applications utilizing pump technology., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2024 The Authors.)

Published

2024

45. A Novel Self-Actuated Linear Drive for Long-Range-of-Motion Electromechanical Systems

Author

Mason Dooley and Xiangrong Shen

Subjects

linear actuator, belt drive, electromechanical system, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Obtaining powered linear movement over a long range of motion is a common yet challenging task, as the majority of linear actuators have limited ranges of motion as determined by their functioning mechanisms. In this paper, the authors present a novel belt-based self-actuated linear drive (B-SALD), in which a self-powered moving platform slides on a slotted track with essentially unlimited range of motion (only limited by the length of the track). Unlike the traditional rack-and-pinion mechanism, the B-SALD system uses a double-sided timing belt as the power-transmitting element. With the teeth on its inner surface, the belt interacts with a timing pulley for its own circulation; with the teeth on its outer surface, the belt interacts with a linear rail with parallel slots and drives the translation of the moving platform. The unique functioning mechanism generates multiple distinct advantages: no lubrication is required; the slotted track is simple and inexpensive to manufacture; and it provides an inherent compliance to buffer shock loading. With the experiments conducted on a preliminary prototype, it has been demonstrated that the B-SALD is able to provide accurate positioning and continuous motion control, an overall mechanical efficiency of 70% over the majority of the load range, and the capability of generating large force output in the desired manner.

Published

2022

46. Semisupervised Graph Convolution Deep Belief Network for Fault Diagnosis of Electormechanical System With Limited Labeled Data.

Author

Zhao, Xiaoli, Jia, Minping, and Liu, Zheng

Abstract

The labeled monitoring data collected from the electromechanical system is limited in the real industries; traditional intelligent fault diagnosis methods cannot achieve satisfactory accurate diagnosis results. To deal with this problem, an intelligent fault diagnosis method for electromechanical system based on a new semisupervised graph convolution deep belief network algorithm is proposed in this article. Specifically, the labeled and unlabeled samples are first employed to design a new adaptive local graph learning method for constructing the graph neighbor relationship. Meanwhile, the labeled samples are applied to describe the discriminative structure information of data via the latest circle loss. Finally, the local and discriminative objective functions are reconstructed under the semisupervised learning framework. The experimental results from the motor-bearing system demonstrate that the method can achieve 98.66 % accuracy with only 10 % of training labeled data, which indicates that it is a promising semisupervised intelligent fault diagnosis method. [ABSTRACT FROM AUTHOR]

Published

2021

47. Diagnostics of Thermal Condition of Electromechanical Machinery

Author

V. F. Borisenko, A. I. Zemlyansky, V. A. Sidorov, and E. V. Sidorova

Subjects

thermal monitoring, electromechanical system, thermal estimated weight, temperature distribution, diagnostic indicator, Mining engineering. Metallurgy, TN1-997

Abstract

The paper is devoted to studying issues of machinery thermal state monitoring using generalized approach to objectives of electromechanical system (EMS) diagnostics based on current temperature values. Generalized mathematical model of EMS (a homogeneous body or a multi-weight estimated heat balance diagram) for various operation conditions of a facility allows to identify diagnostic indicators (criteria) for taking specific measures to stabilize its operation. Increasing efficiency of the facility thermal state monitoring can be achieved using noncontact measuring instruments to determine temperature distribution over the facility surface. Temperature distribution over an EMS facility surface enables concluding on maintenance necessity. For effective application of noncontact thermal-imaging equipment for diagnostics of EMS on the basis of the provisions presented in the paper, training program for specialists in thermometering of industrial facilities has been developed.

Published

2019

48. Research of the Electric Power Conversion in Wind Turbines with the Aerodynamic Multiplication

Author

Alekseevskiy D.G., Andrienko P.D., and Nemykina O.V.

Subjects

electromechanical system, wind turbine, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Renewable energy sources, TJ807-830

Abstract

The paper deals with the research of busbar power losses depending on electrical equipment installation and the dynamic change of the generated power of a wind turbine with the aerodynamic multiplication. The analysis of the electricity conversion electromechanical system is carried out on the example of the first Ukrainian pilot wind turbine with the aerodynamic multiplication of the TG-1000 type. The aim of the article is analytic method creation of analysis of power relative losses in busbars of electrical equipment depend on its arrangement, as well as the research of electromagnetic processes in the electromechanical system depend on the wind flow speed at the height axis of the turbogenerators setted on the blades of the wind wheel (WW) turbine by computer modelling method. This aim achieves by the rectifiers series connection and their location changing (generator clips), which allows the DC energy transfer inside the wind turbine. The research results have showed that power losses reduce in busbars and lead to increase wind turbine efficiency and decrease cable consumption. Electromagnet processes modelling of visual block model have evidenced the adequacy of the assumptions in the determination of the power losses. It has been obtained that the wind flow speed irregularity at the height axis of the turbogenerator and steering angle between turbogenerator axis and wind wheel rotation plane provokes the power generation variances, which pulse according to wind wheel rotation speed. In addition, balanced current of the circuit has provided the symmetrizing amplitudes of the power generator.

Published

2019

49. Health-diagnosis of electromechanical system with a principal-component bayesian neural network algorithm.

Author

Wen, Bor-Jiunn, Lin, Yung-Sheng, Tu, Hsing-Min, and Hsieh, Cheng-Chang

Subjects

*ALGORITHMS, *MULTIPROCESSORS, *GOAL (Psychology), *DIAGNOSIS

Abstract

This study proposes a cloud tele-measurement technique on an electromechanical system, and uses a neural network algorithm based on principal-component analysis (PCA) to quickly diagnose its performance. Three vibration, three temperature, electrical voltage, and current sensors were mounted on the electromechanical system, and the external braking device was used to provide different load-states to simulate the operating states of the motor under different conditions. Moreover, a single-chip multiprocessor was used through the sensor to instantly measure the various load-state simulations of the motor. The operating states of the electromechanical system were classified as normal, abnormal, and required-to-be-turned-off states using a principal-component Bayesian neural network algorithm (PBNNA), to enable their quick diagnosis. Furthermore, PBNNA successfully reduces the dimensionality of the multivariate dataset for rapid analysis of the electromechanical system's performance. The accuracy rates of health-diagnosis based on the Bayesian neural network algorithm and PBNNA models were obtained as 97.7% and 98%, respectively. Finally, the single-chip multiprocessor based on PBNNA is used to automatically upload the measurement and analysis results of the electromechanical system to the cloud website server. The establishment of this model system can optimize prediction judgment and decision-making based on the damage situation to achieve the goals of intelligence and optimization of factory reconstruction. [ABSTRACT FROM AUTHOR]

Published

2021

50. MATHEMATICAL MODELLING OF TRANSIENTS IN THE ELECTRIC DRIVE OF THE TURNOUT OF THE MONO-SLEEPER TYPE WITH SWITCHED-INDUCTOR MOTOR.

Author

Buriakovskyi, S. G., Maslii, A. S., Asmolova, L. V., and Goncharuk, N. T.

Subjects

ELECTRIC drives, ELECTRIC transients, ELECTRIC motors, MATHEMATICAL models, ELECTRIC inductors, LAPLACE transformation, SPUR gearing

Abstract

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Published

2021