Modelling and performance improvement of phase-angle-based conductivity sensor

2016 IEEE First International Conference on Control, Measurement and Instrumentation (CMI) Pub Date : 2016-02-25 DOI:10.1109/CMI.2016.7413779

Avishek Adhikary, G. Kumar, Susanta Banerjee, S. Sen, K. Biswas

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引用次数: 14

Abstract

In a previous work [1], a phase angle based conductivity sensing is reported, using a polymer (DQN-70) coated epoxy probe. That reported sensor is robust, light weight and low cost and its sensing technology is a simple and novel one. But, the sensing range is limited to low value (10 μS/cm to 1 mS/cm) and it needs high frequency excitation (200 kHz, 2 MHz and more). This paper aims to overcome those limitations. This work proposes an electrical equivalent model for the reported sensing system. Through this modeling, this paper analyses different aspects of said phase-based-sensing. The modelling also explains how the distributive capacitance of the system plays a key role in such sensing. It is shown that, the sensor performance (range and operating frequency) is improved by increasing the effective capacitance. The system is then modified accordingly and the concept is validated experimentally. The modified system senses higher range (10 μS/cm to 2.5 mS/cm) at only 200 kHz frequency.

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基于相位角的电导率传感器建模及性能改进

在先前的工作[1]中，报道了一种基于相角的电导率传感，使用聚合物(DQN-70)涂层环氧探针。该传感器具有鲁棒性好、重量轻、成本低等特点，其传感技术简单新颖。但是，传感范围仅限于低值(10 μS/cm ~ 1 mS/cm)，并且需要高频激励(200 kHz、2 MHz以上)。本文旨在克服这些限制。这项工作为报告的传感系统提出了一个电等效模型。通过该模型，分析了基于相位传感的各个方面。该模型还解释了系统的分布电容如何在这种传感中起关键作用。结果表明，增大有效电容可以提高传感器的工作范围和工作频率。然后对系统进行了相应的修改，并对该概念进行了实验验证。改进后的系统仅在200 kHz频率下即可感知更高的量程(10 μS/cm至2.5 mS/cm)。

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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2016 IEEE First International Conference on Control, Measurement and Instrumentation (CMI)

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