Experimentation and Analysis of Intra-Cavity Beam-Splitting Method to Enhance the Uniformity of Light in the Powersphere

He, Tiefeng; Pan, Guobing; Zheng, Guoliang; Xu, Zikun; Lv, Zhijian; Wu, Qingyang; Wan, Lili; Huang, Haixuan; Shi, Tianyu

doi:10.3390/photonics11020128

Photonics

2024

DOI: 10.3390/photonics11020128

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Experimentation and Analysis of Intra-Cavity Beam-Splitting Method to Enhance the Uniformity of Light in the Powersphere

Tiefeng He,

Guobing Pan,

Guoliang Zheng

et al.

Abstract: The powersphere is a spherical enclosed receiver composed of multiple photovoltaic cells. It serves as a replacement for traditional photovoltaic panels in laser wireless power transmission systems for optoelectronic conversion. The ideal powersphere aims to achieve a uniform distribution of light within the cavity through infinite reflections, reducing energy losses in the circuit. However, due to the high absorption rate of the photovoltaic cells, the direct irradiation area on the inner surface of the power… Show more

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Cited by 2 publications

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Laser wireless power transmission based on spherical reflector intra-cavity beam splitting

Xu,

Yang,

Zheng

et al. 2024

Appl. Opt.

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The powersphere is an energy reception device in a laser wireless power transmission system, converting light into electricity, and also has a certain effect of light uniformity. However, in the actual application process, limitations due to laser power, photovoltaic cell absorption rate, and direct irradiation area restrict light uniformity, thus reducing photoelectric conversion efficiency. A spherical reflector at the center of the powersphere to enhance internal reflection and improve light uniformity was proposed. Utilizing LightTools software, we established a simulation model to simulate the energy distribution of light on the powersphere after reflection by the sphere, analyzing light uniformity and constructing an experimental platform for validation. Results show the reflector significantly boosts uniformity, doubling the powersphere’s output power and reducing voltage and current disparities, thereby enhancing system conversion efficiency.

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Laser wireless power transmission based on spherical reflector intra-cavity beam splitting

Xu,

Yang,

Zheng

et al. 2024

Appl. Opt.

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Experimental and analytical study of light uniformity in the double-incidence powersphere based on ellipsoidal reflection within a cavity

He,

Wu,

et al. 2024

Opt. Express

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The powersphere is an enclosed spherical photovoltaic receiver designed to achieve light uniformity through multiple reflections. However, in practical applications, the high absorption rate of the laser cells causes a significant difference in irradiance between direct and reflected light, preventing optimal light uniformity. This results in power loss and reduces both the conversion efficiency and output power in laser wireless power transmission. To address this, we propose a method that uses dual laser incidence and employs an ellipsoid for light reflection within the powersphere. A mathematical model of the powersphere, based on elliptical reflections inside the cavity, was developed and theoretically validated. Using this model, this study designed a system with symmetrical laser incidence from both ends of the powersphere and elliptical reflection within its cavity. Simulation analysis demonstrated improved light uniformity and intensity on the inner surface. An experimental platform based on dual-beam incidence and ellipsoid reflection was constructed, with results showing improved voltage uniformity from 0.09 to 0.86, current uniformity from 0.25 to 0.96, and a 26% increase in output power. These theoretical, simulation, and experimental findings confirm that dual-beam incidence and ellipsoid reflection effectively enhance both uniformity and output power in the powersphere.

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Experimentation and Analysis of Intra-Cavity Beam-Splitting Method to Enhance the Uniformity of Light in the Powersphere

Cited by 2 publications

References 31 publications

Laser wireless power transmission based on spherical reflector intra-cavity beam splitting

Laser wireless power transmission based on spherical reflector intra-cavity beam splitting

Experimental and analytical study of light uniformity in the double-incidence powersphere based on ellipsoidal reflection within a cavity

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