Your search keyword '"Manuel I. Peña-Cruz"' showing total 6 results

1. A Linear Hybrid Concentrated Photovoltaic Solar Collector: A Methodology Proposal of Optical and Thermal Analysis

Author

Eduardo Venegas-Reyes, Naghelli Ortega-Avila, Manuel I. Peña-Cruz, Omar J. García-Ortiz, and Norma A. Rodríguez-Muñoz

Subjects

CPV/T, CPVT, ray-tracing, radiative flux distribution, non-uniformity, Technology

Abstract

The photovoltaic cell surface in linear hybrid concentrated solar collectors receives non-uniform radiative flux, causing additional thermal stress due to hot spots and reducing its electrical performance and durability. The current study proposes a parametric methodology to determine the optimal receiver displacement required in a linear Cassegrain-type hybrid solar collector. The aim was to achieve a minimal non-uniformity distribution and a high radiative flux over the photovoltaic cells, considering optical errors close to real environment conditions and analyzing the heat transfer to determine the electrical and thermal efficiencies. The developed methodology was applied to analyze a case study with a receiver width of 0.125 m and rim angle of 80° and using a commercial silicon photovoltaic cell that supports up to 7000 W/m2. After applying the methodology, a hybrid solar collector with a concentration ratio of 13.0 and receiver displacement of 0.14 m is recommended. As a result, 5728 W/m2 of average radiative flux with non-uniformity lower than 4% was achieved. Thus, thanks to the proposed configuration, a low non-uniformity and high radiative flux were achieved, benefiting the photovoltaic cells’ life while improving their operation.

Published

2021

2. Dust Deposition Classification on the Receiver Tube of the Parabolic Trough Collector: A Deep Learning-Based Approach.

Author

Alan Brian Díaz Reyna, Luis M. Valentín-Coronado, and Manuel I. Peña-Cruz

Published

2022

3. Physicochemical and optical properties of a sustainable and low cost solar absorber coating based on activated carbon from coconut shell

Author

Paola Elizabeth Martínez-Mireles, Manuel I. Peña-Cruz, Beatriz Escobar-Morales, Gonzalo Carrillo-Baeza, Iván Salgado-Tránsito, Neith Pacheco, Soledad Pech-Cohuo, and Nancy Guadalupe González-Canché

Subjects

Mechanics of Materials, Mechanical Engineering, General Materials Science, Condensed Matter Physics

Published

2022

4. A comprehensive analysis of the optical and thermal performance of solar absorber coatings under concentrated flux conditions

Author

Leopoldo Martínez-Manuel, Nancy G. González-Canché, Luis B. López-Sosa, Jose G. Carrillo, Wujun Wang, Carlos A. Pineda-Arellano, Fernando Cervantes, Juan Jose Alvarado Gil, and Manuel I. Peña-Cruz

Subjects

Renewable Energy, Sustainability and the Environment, General Materials Science

Published

2022

5. Hydrothermal liquefaction of wood wastes in a concentrating solar plant: A techno-economic analysis

Author

Eduardo Bautista-Peñuelas, Juan Daniel Macías, Heidi I. Villafán-Vidales, Patricio J. Valadés-Pelayo, Pedro Arcelus-Arrillaga, Alejandro Ayala-Cortés, Karla Cedano-Villavicencio, Camilo A. Arancibia-Bulnes, and Manuel I. Peña-Cruz

Subjects

Fuel Technology, Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology

Published

2023

6. Optical design optimization for improved lamp-reflector units in high-flux solar simulators

Author

Leopoldo Martínez-Manuel, Manuel I. Peña-Cruz, Amaia Mutuberría, and Marcelino Sánchez González

Subjects

Electrical and Electronic Engineering, Engineering (miscellaneous), Atomic and Molecular Physics, and Optics

Abstract

High flux solar simulators are artificial solar facilities developed to imitate the on-sun operations of concentrating solar power technologies but under a well-controlled lab-scale environment. We report the optical enhancement of different high flux solar simulators for solar thermal and thermochemical applications. The solar simulator enhancement is numerically conducted by optimizing the geometry of ellipsoidal reflectors at focal lengths of 1600, 1800, and 2000 mm. The Monte Carlo ray-tracing technique is employed to evaluate the optical performance of different reflector designs. The typical seven-lamp solar simulator arrangement in hexagonal configuration is modeled to analyze the optical performance at different focal lengths. In addition, different xenon arc lamps are modeled with rated powers of 3000, 4000, 4500, and 5000 W for assessing the radiative flux characteristics of the proposed solar simulators. After the optimization, theoretical results show that peak fluxes and radiative powers of 7.2 − 14 . 3 M W / m 2 and 5.06–10.4 kW, respectively, can be achieved with the proposed designs of solar simulators for the different rated powers. Compared with a commercial reflector, theoretical peak flux and power can be improved up to 36% and 17.9%, respectively, with the proper combination of lamp-reflector units. We provide design alternatives to select a more suitable light source at low-rated powers ( ≤ 5000 W ) and different focal lengths of the reflector, which simplifies the complexity of the design and improves the performance of solar simulators.

Published

2022