A microwave cavity resonator sensor for water-in-oil measurements

Sharma, Prafull; Lao, Liyun; Falcone, Gioia

doi:10.1016/j.snb.2018.01.211

Cited by 78 publications

(23 citation statements)

References 25 publications

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“…The results show that the proposed sensor has the highest Q-factor compared to the recently proposed sensors in Table 3. Planar split ring resonator 525 [6] Complementary split ring resonator 80 [7] Planar symmetrical split ring resonator 652 [10] Planar ring resonator 146.67 [11] Substrate Integrated waveguide 334.6 [12] Cavity Substrate Integrated Waveguides ≈300 [13] Re-Entrant cavity waveguide 1190 [14] Multiresonance rectangular cavity waveguide 2605 [15] Circular cavity resonator waveguide 47 [24] Planar split ring resonator 506 [25] Multiple split ring resonator 430 Proposed sensor Gap waveguide cavity resonator 4832…”

Section: Sensor Designmentioning

confidence: 99%

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Analysis and investigation of a novel microwave sensor with high Q-factor for liquid characterization

Alhegazi¹,

Zakaria²,

Shairi³

et al. 2019

TELKOMNIKA

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In this paper, a new design of microwave sensor with high Q-factor for liquid characterization is analyzed and investigated. The new microwave sensor is based on a gap waveguide cavity resonator (GWCR). The GWCR consists of upper plate, lower plate and array of pins on the lower plate. The liquid under test (LUT) is characterized by placing it inside the GWCR where the electric field concentrates using a quartz capillary that is passing through microfluidic channels. The results show that the proposed sensor has a high Q-factor of 4832. Moreover, the proposed sensor has the ability to characterize different types of liquids such as oils, ethanol, methanol and distilled water. The polynomial fitting method is used to extract the equation of the unknown permittivity of the LUT. The results show that the evaluated permittivity using the proposed sensor has a good agreement with the reference permittivity. Therefore, the proposed sensor is a good candidate for food and pharmaceutical applications.

show abstract

Section: Sensor Designmentioning

confidence: 99%

“…However, the disadvantage of these sensors is the low Q-factor, which reflects the low sensitivity. Therefore, some researchers tend to use a metal waveguide to increase the Q-factor and sensitivity [13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Analysis and investigation of a novel microwave sensor with high Q-factor for liquid characterization

Alhegazi¹,

Zakaria²,

Shairi³

et al. 2019

TELKOMNIKA

View full text Add to dashboard Cite

show abstract

“…As a result, many types of microwave sensors are introduced in different research studies such as industrial sensors that are used in many fields especially in the detection of the characteristics of material due in variation of the permittivity constant [2], detection of gaps in concrete [3], humidity sensor [4], gas detection sensor [5], one-dimensional (1D) and 2D linear and circular displacement microwave sensors [6][7][8][9][10][11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

High sensitivity simple structured displacement sensor using corrugated substrate‐integrated waveguide (CSIW)

Soltan

Sadeghzadeh

Mohammad-Ali-Nezhad

2020

IET Microwaves, Antennas & Propagation

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In this study, a corrugated substrate‐integrated waveguide (CSIW) is used to design a passive microwave displacement sensor. Hence, one of the electric walls of the proposed structure is formed by open‐circuited quarter guided wavelength stubs and the other walls are made by metal vias and moveable copper metal is placed on the stubs. By displacing the moveable metal layer along with the stubs, the length of the stubs is changed and therefore the resonant frequency is shifted. An analytical model that relates the variation of the resonant frequency and the displacement has been formulated. The proposed sensor seems like a simple structure and it is operated at 2.4–2.9 GHz. There is a good agreement between the measured results and those obtained by simulation. The measured results indicate that the sensor provides a high dynamic range of displacement of 15 mm and high sensitivity of 25.16 MHz/mm.

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“…In 2009, a method for the determination of water content in crude oil mixture by microwave technology was proposed by Makeev et al [5,6]. Sharma et al did more research on this method to a high degree [7]. In 1995, García-Golding et Al.…”

Section: Introductionmentioning

confidence: 99%

A Visual Measurement of Water Content of Crude Oil Based on Image Grayscale Accumulated Value Difference

Liu

Chu

Peng

et al. 2019

Sensors

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In the process of oil exploitation, the water level of an oil well can be predicted and the position of reservoir can be estimated by measuring the water content of crude oil, with reference for the automatic production of high efficiency in the oil field. In this paper, a visual measuring method for water content of crude oil is proposed. The oil and water in crude oil samples were separated by centrifugation, distillation or electric dehydration, and a water–oil layered mixture was formed according to the unequal densities. Then the volume ratio of water and oil was analyzed by digital image processing, and the water content and oil content was able to be calculated. A new method for measuring water content of crude oil based on IGAVD (image grayscale accumulated value difference) is proposed, which overcomes the uncertainty caused by environmental illumination and improves the measurement accuracy. In order to verify the effectiveness of the algorithm, a miniaturization and low-cost system prototype was developed. The experimental results show that the average power consumption is about 165 mW and the measuring error is less than 1.0%. At the same time, the real-time and remote transmission about measurement results can be realized.

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A microwave cavity resonator sensor for water-in-oil measurements

Cited by 78 publications

References 25 publications

Analysis and investigation of a novel microwave sensor with high Q-factor for liquid characterization

Analysis and investigation of a novel microwave sensor with high Q-factor for liquid characterization

High sensitivity simple structured displacement sensor using corrugated substrate‐integrated waveguide (CSIW)

A Visual Measurement of Water Content of Crude Oil Based on Image Grayscale Accumulated Value Difference

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