Harvesting Energy from Soil-Air Temperature Differences for Batteryless IoT Devices: A Case Study

arXiv - CS - Systems and Control Pub Date : 2024-05-05 DOI:arxiv-2405.02986

Priyesh Pappinisseri Puluckul, Maarten Weyn

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Abstract

The temperature difference between soil and air holds the potential to generate energy to power many low-power IoT devices. However, there is a lack of studies in the literature that explore the nuances of soil-air thermal energy harvesting. This paper offers a comprehensive discussion on soil-air thermal energy harvesting. We engineer a custom Soil-air Thermoelectric Generator (SoTEG) that incorporates an off-the-shelf TEG and an efficient heat transfer network. A detailed discussion of the design and analysis of SoTEG is presented along with a versatile simulation model which can be used to simulate the performance of the harvester under different ambient conditions. Investigations using the model and results gathered from experiments demonstrate that the SoTEG has a heat transfer efficiency of 34.5% with room for improvement and can power a load from temperature differences as low as 3 {\deg}C between soil and air, or 1 {\deg}C across the TEG. Power generated by SoTEG at 3 {\deg}C difference amounts to 110 {\mu}Wor a power density of 11.58mW/m2. When connected to a Power Management Unit (PMU), the combined system generates around 30 {\mu}Wat 3 {\deg}C. During a 14-day outdoor deployment in a winter month, the maximum power generated by the combined system is 337 {\mu}W when the temperature difference across the TEG is 2.75 {\deg}C. Additionally, the model analysis reveals that the weather conditions have an impact on the harvester. While Solar radiation enhances power generation, wind can either improve or diminish the harvested energy depending on whether it is day or night.

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为无电池物联网设备从土壤-空气温差中收集能量：案例研究

土壤和空气之间的温差蕴含着为许多低功耗物联网设备提供能量的潜力。然而，文献中缺乏对土壤-空气热能采集细微差别的研究。本文对土壤空气热能收集进行了全面探讨。我们设计了一种定制的土壤空气热电发电机（Soil-air ThermoelectricGenerator，SoTEG），它结合了现成的 TEG 和高效的传热网络。使用该模型进行的调查和实验结果表明，SoTEG 的热传导效率为 34.5%，还有改进的余地，可以利用土壤和空气之间低至 3{\deg}C 的温差或 TEG 之间低至 1 {\deg}C 的温差为负载供电。在 3 {\deg}C 的温差下，SoTEG 产生的功率为 110 {\mu}W 或 11.58mW/m2 的功率密度。当连接到电源管理单元（PMU）时，组合系统在 3 {deg}C 下可产生约 30 {mu}Wat 的电能。在冬季一个为期 14 天的户外部署中，当 TEG 上的温差为 2.75 摄氏度时，组合系统产生的最大功率为 337 {/mu}W。此外，模型分析表明，天气条件对收割机也有影响。太阳辐射会提高发电量，而风力则会根据白天或夜晚的情况提高或降低收获的能量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - CS - Systems and Control

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