On availability of the optimal regimes in a Knudsen Cs-Ba thermionic converter at high emitter temperatures

Кузнецов, В. И.; Ender, A. Ya.; Babanin, V. I.

doi:10.1063/1.5027052

Cited by 11 publications

(2 citation statements)

References 4 publications

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“…Calculating system efficiency values, in addition to facilitating comparisons between energy conversion platforms, has the added benefit of highlighting areas for improvement. For instance, an analysis may reveal the need for low-power cooling systems that can efficiently remove heat from the collector (e.g., liquid cooling, [158] heat pipes, [82,194,195] or radiation [196] ) or for efficient burner designs that recuperate waste exhaust heat and deliver it to the emitter. [197][198][199] In summary, the system efficiency incorporates energy loss pathways that are external to a TEC but nevertheless important for its operation, allowing for more meaningful comparisons between energy generation architectures.…”

Section: Efficiency Metricsmentioning

confidence: 99%

Progress Toward High Power Output in Thermionic Energy Converters

Campbell

Celenza

Schmitt³

et al. 2021

Advanced Science

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Thermionic energy converters are solid‐state heat engines that have the potential to produce electricity with efficiencies of over 30% and area‐specific power densities of 100 Wcm−2. Despite this prospect, no prototypes reported in the literature have achieved true efficiencies close to this target, and many of the most recent investigations report power densities on the order of mWcm−2 or less. These discrepancies stem in part from the low‐temperature (<1300 K) test conditions used to evaluate these devices, the large vacuum gap distances (25–100 µm) employed by these devices, and material challenges related to these devices' electrodes. This review will argue that, for feasible electrode work functions available today, efficient performance requires generating output power densities of >1 Wcm−2 and employing emitter temperatures of 1300 K or higher. With this result in mind, this review provides an overview of historical and current design architectures and comments on their capacity to realize the efficiency and power potential of thermionic energy converters. Also emphasized is the importance of using standardized efficiency metrics to report thermionic energy converter performance data.

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Section: Efficiency Metricsmentioning

confidence: 99%

Progress Toward High Power Output in Thermionic Energy Converters

Campbell

Celenza

Schmitt³

et al. 2021

Advanced Science

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“…Из экспериментов известно, что при высоких температурах эмиттера максимальная удельная мощность термоэмиссионного преобразователя энергии достигается при давлениях цезия, соответствующих области перехода из бесстолкновительного в столкновительный для электронов режим [31]. Проведенное нами исследование влияния столкновений электронов на стационарные характеристики плазменного диода даст возможность для проведения оптимизации характеристик ТЭП.…”

Section: заключениеunclassified

Устойчивые И Неустойчивые Режимы Плазменных Диодов При Наличии Столкновений Электронов

Pramanik

Кузнецов²,

Chakrabarti

2019

Журнал Технической Физики

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A thermionic energy converter is modelled by the Pierce diode which inter-electrode region is filled uniformly with immovable ions. Stability features of such diode steady states in the presence of electron-gas background collision are studied. Time-independent solutions are analytically obtained by Lagrangian formalism. Using a perturbation approach we derived a relevant dispersion equation. Both aperiodic and oscillatory solutions of such an equation are studied. The regions corresponding to unstable aperiodic modes are specifed. On the other hand, all oscillatory modes are shown to be stable.

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