Electromagnetic Characteristics of Permanent Magnet Linear Generator (PMLG) Applied to Free-Piston Engine (FPE)

Xu, Yongming; Zhao, Diyuan; Wang, Yaodong; Ai, Mengmeng

doi:10.1109/access.2019.2909278

Cited by 15 publications

(9 citation statements)

References 22 publications

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“…Nowadays, permanent magnet linear generators (PMLGs) have been a promising choice for the direct-drive wave energy converter (DD-WEC) systems owing to their simple structure, friendly maintenance and high efficiency (Trapanese et al , 2019). Additionally, the DD-WEC system with PMLG can greatly lower the system cost by avoiding the use of hydraulic devices and gear boxes (Xu et al , 2019). Unfortunately, the PMLGs used in DD-WEC system have a disadvantage of low power density owing to their low operation speed (Farrok et al , 2019).…”

Section: Introductionmentioning

confidence: 99%

Design and analysis of tubular permanent magnetic linear generator with 120° phase belt toroidal windings

Yan

Nie

et al. 2021

COMPEL

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Purpose To improve the power density and generation efficiency of the tubular permanent magnetic linear generators (TPMLGs) under realistic sea-stator condition, a TPMLG with 120° phase belt toroidal windings (120°-TPMLG) for wave energy conversion is proposed in this paper. Design/methodology/approach First, the structure of the 120°-TPMLG is introduced and its operation principle is analyzed. Second, the design process of the 120°-TPMLG is described. Meanwhile, the finite-element models of the 120°-TPMLG and the TPMLG with traditional fractional pitch windings (T-TPMLG) are established based on the similar overall dimensions. Then, the electromagnetic characteristics of the 120°-TPMLG are analyzed, such as air gap flux density, back electromotive force and load voltage. Finally, a comparative analysis of the magnetic flux density, flux linkage, load and no-load performance of the two generators are conducted. Findings The result shows that the 120°-TPMLG has higher power density and generation efficiency than the T-TPMLG. Originality/value This paper proposes a TPMLG with 120° phase belt toroidal windings (120°-TPMLG) to improve the power density and generation efficiency.

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Section: Introductionmentioning

confidence: 99%

Design and analysis of tubular permanent magnetic linear generator with 120° phase belt toroidal windings

Yan

Nie

et al. 2021

COMPEL

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“…The AC side of the rectifier can be improved by adding a power factor compensator. However, the effect of adding the power factor compensator is not ideal [5][6][7]. The pulse width modulation (PWM) rectifier can improve the power factor with high total harmonic distortion (THD) of the AC side while realizing two-way energy flow, solve the free-piston Stirling linear power generation system since its inception dynamic problem [8,9].…”

Section: Introductionmentioning

confidence: 99%

Control of linear generator based on hysteresis‐SVPWM current rectification and bidirectional buck/boost converter used for energy storage

Ali

Wang

et al. 2021

IET Renewable Power Gen

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The free-piston Stirling linear generation system has tremendous applications in space power supply, biomass generation, solar thermal generation, factory waste heat generation, and other industrial fields. However, the free-piston Stirling linear generation system suffered from the disadvantages of fluctuation of output electric energy and self-starting. To solve the aforesaid problems, a two-level electric energy conversion control mode which combines three-phase AC/DC and bidirectional buck/boost DC to DC converter is proposed in this paper to make the generation system with stable output DC power. Then, both the linear and non-linear mathematical model of the free-piston Stirling engine are established. Additionally, to improve the performance of frequency and displacement tracking, the traditional proportional-integral (PI) in the position loop is replaced by Proportional Resonance (PR) controller. Moreover, the Hysteresis-SVPWM current control strategy with high robustness and dynamic response is applied to the rectifier to realize the unit power factor control of the AC side of the generator and the stability and controllability of the DC side voltage. Finally, the three-phase voltage Source Rectifier (VSR) and Bi-directional DC/DC with an appropriate inductance and capacitance for energy storage are modelled. The effectiveness of the proposed system is validated using theoretical analysis and simulations in Matlab.This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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“…A new dual-port linear electrical generator topology was proposed in [8], improving the generation performance of linear generators by optimizing the shape of stator teeth, which is capable to transfer electrical power with an adequate voltage even at zero vertical velocity of the oceanic wave. Xu designed a tubular permanent magnet linear generator using I-shaped and rectangular designs, and the output power and efficiency of the I-shaped PMLG are higher than that of rectangular one [9]. A linear generator for the wave energy conversion system was proposed in [10], which improves system stability by reducing the cogging force.…”

Section: Introductionmentioning

confidence: 99%

A Plate Moving-Magnet Linear Generator Designed for Free-Piston Engines

Sun

Liu

2020

IEEE Access

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Free-piston engine coupled with linear generator is a research hotspot in the field of novel vehicle mounted power generation devices. A plate moving-magnet linear generator (PMMLG) is proposed and designed for free-piston engines in this paper. Magnetic circuit of the novel linear generator is analyzed and modeled in detail. The dimensions of a 2 kW prototype with the max stroke of 40 mm and the max electromagnetic force of 800 N is designed by using the derived magnetic circuit model. Static and transient electromagnetic field finite element models with motion solvers are created. Magnetic field distribution, electromagnetic force characteristics, EMF characteristics, coil inductance, generating power and losses of the linear generator are analyzed and compared with two reported prototypes. Computational fluid dynamics model of the PMMLG is established, and the temperature field is analyzed to verify that the air-cooling conditions can ensure long-term stable running of the linear generator without demagnetization. The research results show that the linear generator has the characteristics of low moving mass, low cogging force, high generating efficiency and high response speed. INDEX TERMS Linear generator, electromagnetic analysis, thermal analysis, free-piston.

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Electromagnetic Characteristics of Permanent Magnet Linear Generator (PMLG) Applied to Free-Piston Engine (FPE)

Cited by 15 publications

References 22 publications

Design and analysis of tubular permanent magnetic linear generator with 120° phase belt toroidal windings

Design and analysis of tubular permanent magnetic linear generator with 120° phase belt toroidal windings

Control of linear generator based on hysteresis‐SVPWM current rectification and bidirectional buck/boost converter used for energy storage

A Plate Moving-Magnet Linear Generator Designed for Free-Piston Engines

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