Measuring Temperatures Generated by Air Plasma Technology

Power Engineering and Engineering Thermophysics Pub Date : 2022-10-31 DOI:10.56578/peet010108

C. Fragassa, Marco Arru, F. Capelli, A. Pavlović, M. Gherardi

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Abstract

The atmospheric pressure air plasma technology is based on the general principle of transforming the air into an ideal conductor of plasma energy thanks to the application of an electric potential difference able to ionize the molecules. Applying the principle to the human surgery, it comes to be possible to assure an energy transfer from plasma-generator devices to the human tissue in a relatively simple way: passing through the air, with exceptionally limited effects in terms of tissue heating. Such a condition is very useful to assure effective treatments in surgery: less thermal damage, fewer side effects on the patient. This is also what emerged during the use of innovative devices embedding the Airplasma® technology (by Otech Industry S.r.l.), where temperatures on human tissues were measured stably below 50°C. However, the profiles assumed by the temperature along the different electrodes during the operating conditions are rather unclear. This knowledge is essential to improve the efficiency of the electrodes (through their redesign in shapes and materials) as well as to reduce the invasiveness of surgical interventions. The present work had the purpose of characterizing the most common electrodes thanks to temperature measurements carried out by infrared sensors respect to different operating conditions. A simplified finite element model was also developed to support the optimal redesign of electrodes.

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测量空气等离子体技术产生的温度

大气压空气等离子体技术是基于将空气转化为等离子体能量的理想导体的一般原理，这要归功于能够电离分子的电位差的应用。将这一原理应用到人体手术中，就有可能以一种相对简单的方式确保能量从等离子体发生器设备转移到人体组织:通过空气，在组织加热方面的影响非常有限。这样的条件是非常有用的，以确保有效的治疗手术:更少的热损伤，更少的副作用，对病人。这也是在使用嵌入Airplasma®技术的创新设备(由Otech Industry S.r.l.)期间出现的，其中人体组织的温度稳定地测量在50°C以下。然而，在工作条件下，沿不同电极的温度所假设的曲线是相当不清楚的。这些知识对于提高电极的效率(通过重新设计电极的形状和材料)以及减少手术干预的侵入性至关重要。由于红外传感器在不同的工作条件下进行了温度测量，本工作的目的是表征最常见的电极。建立了简化的有限元模型，以支持电极的优化再设计。

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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Power Engineering and Engineering Thermophysics

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