A New Non-Intrusive Optical Technique to Measure Transparent Liquid Level and Volume

Singh, Hidam Kumarjit; Chakroborty, S K; Talukdar, Hrishikesh; Singh, Namrata; Bezboruah, Tulshi

doi:10.1109/jsen.2010.2068543

Cited by 38 publications

(17 citation statements)

References 10 publications

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“…The optical sensors (fiber optics, γrays), ultrasonic sensors etc. belonging to the non-contact type liquid-level measurement methods as in [1][2][3][4][5][6] are not suitable for measuring liquid level through a container without contacting the liquid. Further, these are very complex and expensive because of their associated electronic circuit.…”

Section: Introductionmentioning

confidence: 99%

Design of a low cost signal conditioning circuit for self-compensated non contact capacitive type multi threshold liquid level sensor

Babu¹,

Manohar

2014

International Conference on Circuits, Communication, Control and Computing

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A novel technique to design a reliable signal conditioning circuit (SCC) for self-compensating capacitive sensor meant for multi threshold liquid level measurements is presented in this paper. The non-contact type sensor for the measurement and control of liquid level is the key to avoid the corrosion of contact sensors due to chemicals and the usage of compensation system. The proposed capacitive, non-contact type sensor employs self-compensation technique whose output is of the order of Pico Farads, which is difficult to process for further control action. To overcome this, it is proposed here to design a reliable and precise signal conditioning circuit. Also, an efficient SCC is developed using Linear OPAMP. Experimental results reveal that the resolution of measurement of liquid level is improved with respect to electrode dimensions and the designed SCC converts the low capacitance output in a significant manner.

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Section: Introductionmentioning

confidence: 99%

Design of a low cost signal conditioning circuit for self-compensated non contact capacitive type multi threshold liquid level sensor

Babu¹,

Manohar

2014

International Conference on Circuits, Communication, Control and Computing

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“…Both noncontact and contact sensing methods are available for optical water level sensing. Noncontact optical water stage sensing devices, including laser based [5], and light-emitting diode (LEDs) based sensors [6], began to attract industry attention in the early 1970's .The noncontact LED-based optical sensors have eliminated effects on optical properties of the monitored water leading to the possibility for multiparameter sensing [7]. However, in order to achieve an accurate measurement, this technique requires a large number of LEDs and phototransistors, resulting in a costly solution.…”

Section: Introductionmentioning

confidence: 99%

Fiber optic sensing system for in-situ simultaneous monitoring of water stage, quality, and temperature

Huang

2014

SPIE Proceedings

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To accurately track the water stage changes and environmental influences on water quality and have sufficient follow-ups to prevent potential flood and environmental hazards, an in-situ continuous monitoring system for water stage and quality is helpful. Traditional in-situ water-stage monitoring system has relative low accuracy and require separate sensors for water quality and temperature which complex the evaluation. Advanced optical fiber sensors, with unique features of real-time and multiparameter sensing capacity, could provide potential simultaneous evaluation of flooding, water-quality deterioration, and science-based decision support. In this study, an in-situ monitoring system for water stage, overall water quality, and temperature is developed using long-period fiber grating (LPFG) sensors. When part of the LPFG sensor is submerged in water, the resonant wavelength of each cladding mode of the LPFG sensor varies linearly with the submerged length (refer to water stage) and temperature, and nonlinearly with refractive index changes (referred to the water quality). Two resonant wavelengths were used to relate the water stage and overall water quality to the change in resonant wavelengths of the LPFG sensor. Sharing the same fiber line, one sequential glass packaged LPFG was used to monitor the temperature changes at the same location. The algorithm for simultaneous determination of the water stage, overall water quality, and temperature was analytically formulated and experimentally validated. Benefit from the multi-parameter sensing using one single fiber line, the developed optical sensing network can potentially provide a low-cost, real-time, and high resolution solution for the in-situ water quality monitoring.

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“…There is a large variety of methods for liquid-level measurement, ranging from electrical sensors, mechanical floats, and fiber optics to ultrasonic methods [1][2][3][4][5][6]. Most of these methods, however, are not suitable for measuring liquid level through an opaque container without contacting the liquid.…”

Section: Introductionmentioning

confidence: 99%

“…A capacitive semi-cylindrical sensor mounted around a liquid container can measure liquid level without contacting the liquid [2], but its measurement accuracy is not high because the capacitance is strongly dependent on the distance between a container and a sensor. Consequently, optical sensors [3,4] are not suitable for measuring the level of liquid in opaque containers or containers with labels.…”

Section: Introductionmentioning

confidence: 99%

Contactless liquid-level measurement through opaque container using millimeter-wave sensor

Nakagawa

Hyodo

Osada

et al. 2011

2011 IEEE SENSORS Proceedings

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A novel contactless method for measuring liquid level through an opaque container is proposed. A millimeter-wave Doppler sensor is used to "see" through a target container and measure the liquid level on the basis of the absorption of millimeter waves in liquid. One of the challenges is to achieve accurate liquid-level measurement (within sub-millimeter error) despite the inherently large beam-spread angle of the millimeter wave due to diffraction. A piezoelectric vibrator enables accurate measurement by reflecting a limited portion of the spread beam and modulating it to distinguish it from the other portion of the beam. The feasibility of the proposed method for clearly detecting an air-liquid interface concealed in an opaque container was confirmed experimentally. Nonlinearity error of the measured liquid level was within ±0.5 mm, which is the first demonstration of accurate liquid-level measurement using a millimeter-wave sensor.

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A New Non-Intrusive Optical Technique to Measure Transparent Liquid Level and Volume

Cited by 38 publications

References 10 publications

Design of a low cost signal conditioning circuit for self-compensated non contact capacitive type multi threshold liquid level sensor

Design of a low cost signal conditioning circuit for self-compensated non contact capacitive type multi threshold liquid level sensor

Fiber optic sensing system for in-situ simultaneous monitoring of water stage, quality, and temperature

Contactless liquid-level measurement through opaque container using millimeter-wave sensor

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