Design and Experiment Analysis of a Direct-Drive Wave Energy Converter with a Linear Generator

Zhang, Jing; Yu, Haitao

doi:10.3390/en11040735

Cited by 9 publications

(13 citation statements)

References 17 publications

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“…The design yields an output voltage of 3.5 V at the rated output power of 3 W [19]. Likewise, a PMLM design by Zhang et al [11] also employed a tubular structure for application at 0.4 m/s speed. The novelty of this design is the asymmetric slot structure which is reported to be able to reduce detent force and enhance the airgap flux density in the design [11].…”

Section: Figure 1 Energy Conversion In Wecmentioning

confidence: 99%

“…Likewise, a PMLM design by Zhang et al [11] also employed a tubular structure for application at 0.4 m/s speed. The novelty of this design is the asymmetric slot structure which is reported to be able to reduce detent force and enhance the airgap flux density in the design [11]. A tubular switched reluctance linear machine (SRLM) has been proposed and analysed by Mendes et al [20] using FEA, mathematical modelling and experiments.…”

Section: Figure 1 Energy Conversion In Wecmentioning

confidence: 99%

“…From the figure, the direct drive linear generator conversion method requires a primary interface and also an electrical generator. Typically, floating buoy or point absorber technology is used as the primary interface to capture the motion of sea wave as depicted by Zhang et al [11], Hodgins et al [12] and Franzitta et al [13]. As for linear generators, various specifications and topologies based on operating speed and applications have been proposed in the previous literature.…”

Section: Introductionmentioning

confidence: 99%

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Design and Analysis of Tubular Slotted Linear Generators for Direct Drive Wave Energy Conversion Systems

2020

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Linear generator utilization in a wave energy converter (WEC) is an attractive alternative to a rotary generator. This paper presents the design of a permanent magnet linear machine (PMLM) for WEC applications in low wave power areas. In this paper, the wave height and vertical speed of Malaysian water is used for the simulation and design. Two design variants are introduced which are tubular PMLM with no spacer (TPMLM-NS) and tubular PMLM with spacer (TPMLM-S). Finite element analysis (FEA) has been conducted to investigate the performance and to refine the main dimensions of the design in terms of split ratio, pitch ratio and tooth width. The FEA results are then validated using an analytical method which is established according to the design’s magnetic field distribution. Based on main dimension refinement, it can be deduced that both the split ratio and the pitch ratio have a significant influence on the airgap flux density and back EMF of the design. The obtained FEA results also reveal that the TPMLM-NS variant is capable of producing 240 V back EMF, 1 kW output power with satisfactory efficiency. Consequently, this indicates the capability of the design to convert wave energy with good performance. Additionally, good agreement between the analytical predictions and FEA results was obtained with a low percentage of error, thus providing concrete assurance of the accuracy of the design.

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Section: Figure 1 Energy Conversion In Wecmentioning

confidence: 99%

Section: Figure 1 Energy Conversion In Wecmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Design and Analysis of Tubular Slotted Linear Generators for Direct Drive Wave Energy Conversion Systems

2020

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“…The point absorber devices with direct drive extraction mechanism are the more efficient systems for ocean wave energy conversion at low velocity oscillations [1]. For this type of conversion devices, linear generators with permanent magnets are generally used [2][3][4][5][6]. However, linear electric machines with permanent magnets need a complicated winding system and are characterized by their elevated construction and assembly costs.…”

Section: Introductionmentioning

confidence: 99%

Maximum Power Point Tracking for a Point Absorber Device with a Tubular Linear Switched Reluctance Generator

2018

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This paper addresses the control of a Tubular Linear Switched Reluctance Generator (TLSRG) with application in a point absorber device. A maximum power point tracking (MPPT) strategy is proposed to maximize the power extraction from ocean waves. The generator is characterized by average maximum force of 120 kN and a maximum velocity of 1.3 m/s. The proposed MPPT is achieved by changing the generator damping load according to the excitation force induced by a regular wave. A hysteresis controller is applied to regulate the phase current intensity which allows the control of the linear force provided by the generator. The conversion system direct current (DC) bus voltage is adjusted by an isolated DC/DC converter with a proportional integral controller to define the appropriate duty-cycle.

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“…To achieve relatively high quality and efficiency for converting ocean wave energy into electrical energy, various ocean wave energy converters and corresponding electrical machines have been investigated. It was found that linear generators can be used in the direct drive wave energy conversion system, in which it can reduce the complexity of mechanical transmission and improve the reliability and efficiency of the system [6][7][8][9][10][11]. Several electrical generator topologies have been analyzed in the past years [12,13].…”

Section: Introductionmentioning

confidence: 99%

Optimal Design of Permanent Magnet Linear Generator and Its Application in a Wave Energy Conversion System

2018

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The emerging global wave energy industry has great potential to contribute to the world’s energy needs. However, one of the key challenges in designing a wave energy converter (WEC) is the wave energy generator. Thus, this paper focuses on the optimal design of a cylindrical permanent magnet linear generator (CPMLG), which is used for the wave energy conversion system. To reduce the end effect and enhance the magnetic field performance of the CPMLG, the level-set method is applied to the design of the topology and size for the generator. In the paper, the objective air gap magnetic field is given by the mathematical analysis method and appropriate measuring points are predetermined. The measuring points can fully reflect the distribution characteristics of the air gap magnetic field. Then, topology evolution on the permanent magnet (PM) and yoke based on the level-set method are performed. The level set function corresponding to the initial shape of the PM is constructed. The algorithm is programmed and computed iteratively using the discrete time and space variables. Finally, the performances of the CPMLG with the updated PM and width of yoke are analyzed by ANSYS Maxwell. Results show that the magnetic field distortion and the unbalance of three-phase electromotive force (EMF) of the CPMLG is reduced by the optimization of the level-set method. It has also been verified that the designed CPMLG with the level-set method could be used for WEC at different wave conditions.

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Design and Experiment Analysis of a Direct-Drive Wave Energy Converter with a Linear Generator

Cited by 9 publications

References 17 publications

Design and Analysis of Tubular Slotted Linear Generators for Direct Drive Wave Energy Conversion Systems

Design and Analysis of Tubular Slotted Linear Generators for Direct Drive Wave Energy Conversion Systems

Maximum Power Point Tracking for a Point Absorber Device with a Tubular Linear Switched Reluctance Generator

Optimal Design of Permanent Magnet Linear Generator and Its Application in a Wave Energy Conversion System

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