Calibration, testing and monitoring of space solar cells

Lisbona, Emilio Fernandez

doi:10.1016/b978-185617457-2/50019-6

Cited by 4 publications

(8 citation statements)

References 2 publications

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“…However, the almost null atmosphere of the Moon (technically considered an exosphere) along with its weak magnetic field allows space debris, micro-meteorites to reach the lunar surface and also ultraviolet irradiation, nuclei/ion particle radiation and galactic cosmic rays to reach the PV cells resulting in cells degradation. Besides, conditions as vacuum, extreme temperature cycles, and electrostatic fields contribute to the degradation of PV cells [33]. Deep temperature cycles results in the lifetime reduction of the PV connectors due to the thermal stress.…”

Section: Lunar Regolith Electrostatic Chargementioning

confidence: 99%

Space Microgrids for Future Manned Lunar Bases: A Review

Saha

Bazmohammadi

Raya-Armenta

et al. 2021

IEEE Open J. Power Energy

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Several space organizations have been planning to establish a permanent, manned base on the Moon in recent years. Such an installation demands a highly reliable electrical power system (EPS) to supply life support systems and scientific equipment and operate autonomously in a fully self-sufficient manner. This paper explores various technologies available for power generation, storage, and distribution for space microgrids on the Moon. Several factors affecting the cost and mass of the space missions are introduced and analysed to provide a comprehensive comparison among the available solutions. Besides, given the effect of base location on the design of a lunar electrical power system and the mission cost, various lunar sites are introduced and discussed. Finally, the control system requirements for the reliable and autonomous operation of space microgrids on the Moon are presented. The study is complemented by discussing promising future technological solutions that could be applied upon a lunar microgrid.

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Section: Lunar Regolith Electrostatic Chargementioning

confidence: 99%

Space Microgrids for Future Manned Lunar Bases: A Review

Saha

Bazmohammadi

Raya-Armenta

et al. 2021

IEEE Open J. Power Energy

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“…However, the hostile environment of space, which features intense particle radiation, ultra-violet photons, deep temperature cycles and vacuum, electrostatic fields, micro-meteorites, space debris for the terrestrial orbits, etc. , can heavily degrade the PV modules while reducing quickly their lifetime [20,21]. The degradation due to particle radiation of PV cells is of especial interest for scientists and manufacturers given the deep damage and reduction of the cells' lifetime.…”

Section: The Pv Technology For Space Applicationsmentioning

confidence: 99%

“…However, due to the absence of an atmosphere and magnetosphere, other kind of drawbacks come into play. Namely, impacts of micro-meteorites, highly energetic photons, and energetic nuclei particles, deep temperature cycles and vacuum, and electrostatic fields, to name a few [21,76]. Even though all these issues degrade the PV cells, a special interest has been observed for the radiation-induced degradation due to the heavy damage induced to the solar cells, which depends on the type of particle, energy, flux, fluence, material of the cell, temperature, light intensity, etc.…”

Section: The Pv Technology For Space Applicationsmentioning

confidence: 99%

“…The space-age started in the 1950s with the use of PV technology to supply energy into space missions [21]. However, two factors are usually taken into account not only for deciding the sort of generation technology, but also the characteristics of the devices.…”

Section: Introductionmentioning

confidence: 99%

“…Firstly, the relative distance to the Sun, since it has been shown that the PV-technology is feasible for Jupiter's orbits at longest given that the light intensity is inversely proportional to the distance square [20]. Secondly, the environment, since outer space features extreme conditions such as very low temperatures and deep thermal cycles, micro-meteorites, GCRs, UV radiation, extremely low vacuum, electrostatic fields, lunar dust (for the case of the Moon), space debris (for terrestrial orbits), and highly energetic ion/nuclei particles [21]. Indeed, the degradation due to particle radiation of PV cells is usually considered so severe than it is one of the major concerns of researchers and manufacturers of the space sector.…”

Section: Introductionmentioning

confidence: 99%

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Modeling of Solar Cells and Environmental Conditions for Space Microgrids

Raya-Armenta¹

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Optimal Sizing and Siting of PV and Battery Based Space Microgrids Near the Moon’s Shackleton Crater

et al. 2023

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Space mission cost and feasibility depend mainly on the size and mass of the payload. This paper investigates the optimal photovoltaic (PV) array and battery size and mass for an islanded PV-battery powered space microgrid (MG) at the lunar south pole. The PV arrays are considered to be installed on top of towers to increase solar energy harvesting. Considering the dependency of the generated power from PV arrays on the tower height, different tower heights of 10, 50, and 100 m are investigated. The paper presents the methodology to estimate the available power from the PV system using the information of illumination time-series at the location of potential sites with different tower heights. Besides, considering the power demand of several power-consuming units at different operating states, the power demand profile of the lunar base is generated. The optimal sizing of the PV and battery system for a 1-year horizon, without considering battery degradation, results in a total mass of approximately 1.5 × 10 5 kg to 3.5 × 10 5 kg with a tower height of 10 m depending on the solar illumination profiles at different sites. For a 5-year optimization horizon of the same sites with 10 m tower height and considering the battery yearly capacity degradation, total system mass ranges approximately from 2×10 5 kg to 5.5×10 5 kg. Although increasing the tower height may considerably reduce the total size and mass of the battery and PV system, the mass of the PV tower will increase. Thus, a satisfactory trade-off in selecting the site location and tower height is required. In this regard, 15 highly illuminated sites at different locations and with different PV tower heights are assessed in this paper. To improve the reliability and flexibility of the power system, the multi-microgrid (MMG) concept is deployed to distribute the power-consuming units of the base among different MGs having their local energy production and storage systems. Finally, based on the total power demand served at a candidate site and the corresponding total system mass, a criterion, mass-per-unit-load (MPUL), is used to identify the sites that serve the highest power demand with less total system mass.

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Calibration, testing and monitoring of space solar cells

Cited by 4 publications

References 2 publications

Space Microgrids for Future Manned Lunar Bases: A Review

Space Microgrids for Future Manned Lunar Bases: A Review

Modeling of Solar Cells and Environmental Conditions for Space Microgrids

Optimal Sizing and Siting of PV and Battery Based Space Microgrids Near the Moon’s Shackleton Crater

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