A Resonant Pressure Microsensor with a Wide Pressure Measurement Range

Xiang, Chao; Lu, Yulan; Cheng, Chao; Wang, Junbo; Chen, Deyong; Chen, Jian

doi:10.3390/mi12040382

Cited by 13 publications

(7 citation statements)

References 35 publications

(39 reference statements)

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“…In comparison to other resonant high-pressure sensors [16,20,27,28], this developed sensor possessed a wider pressure range, higher correlation coefficients of the pressure sensitivities, higher Q values, and more simple fabrication process (see table 1).…”

Section: Characterization Resultsmentioning

confidence: 99%

“…The intrinsic frequency f 0 of a H-shaped resonator in the first laterally vibrating modal can be approximately calculated by a double ended fixed beam as follows [20]:…”

Section: The Optimization Of Resonators and Diaphragmmentioning

confidence: 99%

“…In recent years, in order to compensate for the resonator's frequency variation over temperature, Roshan adopted the ratio of temperature coefficients of two resonators to obtain temperature information [18]. Besides, our previous works in the high pressure sensing areas, such as Lu [19] and Xiang [20], utilized the difference of the temperature sensitivities of the dual resonators to improve the temperature compensation precisions compared to off-chip temperature sensor compensation manners to a great extent in the high pressure sensing areas. Whereas, the linearity and the pressure sensitive range of the sensor were compromised due to difficulties of dual resonators layouts on a limited small-dimension pressure sensitive diaphragm.…”

Section: Introductionmentioning

confidence: 99%

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A resonant high-pressure sensor based on dual cavities

Chen

et al. 2021

J. Micromech. Microeng.

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High-pressure sensors enable expansive demands in ocean sciences, industrial controls, and oil explorations. Successful sensor realized in piezoresistive high-pressure sensors which suffer from the key issue of compromised accuracies due to serious temperature drifts. Herein, this paper presents a high accuracy resonant high-pressure sensor with the pressure range of 70 MPa. Different from conventional resonant high-pressure sensor, the developed sensor utilized a dual-resonator-cavity design to minimize temperature disturbances and improve the pressure sensitivities. Besides, four circle cavities were used to maintain a high vacuum level for resonators after anodic bonding process. In details, Dual resonators, which is parallelly placed in the tensile and compressive stresses areas of a rectangular pressure sensitive diaphragm, are separated vacuum-packaged in the parallel dual cavities. Thus, pressure under measurement bends the pressure sensitive diaphragm, producing an increased pressure sensitivity and a decreased temperature sensitivity by the differential outputs of the dual resonators. Parameterized mathematical models of the sensor were established and the parameters of the models were optimized to adjust the pressure sensitivities and the temperature sensitivities of the sensor. Simplified deep reactive ion etching was used to form the sensing structure of the sensor and only once anodic bonding was used to form vacuum packaging for the dual resonators. Experimental results confirmed that the Q values of the resonators were higher than 32 000. Besides, the temperature sensitivity of the sensor was reduced from 44 Hz °C−1 (494 ppm °C−1) to 1 Hz °C−1 (11 ppm °C−1) by the differential outputs of the dual resonators in the temperature range of −10 °C–60 °C under the pressure of 1000 kPa. In addition, the accuracy of the sensor was better than 0.02% FS within the pressure range of 110–6500 kPa and the temperature range of −10 °C–60 °C by using a polynomial algorithm.

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Section: Characterization Resultsmentioning

confidence: 99%

“…The intrinsic frequency f 0 of a H-shaped resonator in the first laterally vibrating modal can be approximately calculated by a double ended fixed beam as follows [20]:…”

Section: The Optimization Of Resonators and Diaphragmmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A resonant high-pressure sensor based on dual cavities

Chen

et al. 2021

J. Micromech. Microeng.

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“…To sum up, there are a variety of microfluidic chip fabrication methods at present that can realize the fabrication of microchannels with complex structures and the packaging of microchannels by bonding in the later stage. However, the manufacturing and packaging of microchannels at present have strict requirements on processing equipment and working conditions, and even pose certain risks [ 34 , 35 ]. Therefore, this paper proposes a microfluidic chip processing method that combines 3D-printing technology and polymer-dissolution technology that can form microchannels inside a PDMS substrate.…”

Section: Introductionmentioning

confidence: 99%

Research on Integrated 3D Printing of Microfluidic Chips

Sun

Yin

2023

Micromachines

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Microfluidic chips have the advantages of miniaturization, integration, and portability, and are widely used in the early diagnosis of major diseases, personalized medical treatment, environmental detection, health quarantine, and other fields. The existing microfluidic chip manufacturing process is difficult to operate because of complex three-dimensional channels, complicated manufacturing steps, limited printing materials, the difficulty of operating the bonding process, and the need to purchase expensive new equipment. In this paper, an integrated molding method for microfluidic chips that integrates 3D printing and polymer dissolution technology is proposed. First, the channel mold of poly(vinyl alcohol) (PVA) or high impact polystyrene (HIPS) is dissolved to complete the manufacturing of the microfluidic chip channel. The integrated 3D-forming method of microfluidic chips proposed in this paper can manufacture microchannels inside the microfluidic chip, avoid the bonding process, and eliminate the need for rapid alignment of microchannels, material modification, and other operations, thus improving the stability of the process. Finally, by comparing the microchannels made by PVA and HIPS, it is concluded that the quality of the microchannels made by HIPS is obviously better than that made by PVA. This paper provides a new idea for the fabrication of microfluidic chips and the application of HIPS.

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“…Zhang et al introduced a micromechanical resonant pressure sensor with two resonators and solved the overload problem [16]. Xiang et al introduced a resonant pressure microsensor in which the silicon islands are deployed on an SOI wafer to improve the equivalent sti ness and structural stability of the pressure-sensitive diaphragm [17]. Zhao et al and Yan et al developed temperature-insensitive silicon resonant pressure sensors with very-low-frequency temperature coe cients [18,19].…”

Section: Introductionmentioning

confidence: 99%

Effects of Resonator Shape on Nonlinear Resonant Frequencies of a Microresonant Pressure Sensor

Han

2022

Shock and Vibration

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A nonlinear dynamics equation for a novel microresonant pressure sensor with a cross-type resonator is proposed. The nonlinear resonant frequencies of the sensor are calculated. Effects of the system parameters and gas pressure on the nonlinear resonant frequencies are investigated. Results show that the effects of nonlinearity on the resonant frequencies increase with increasing length of the resonator, and they decrease with decreasing the clearance between the resonator and the baseplate or gas pressure.

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A Resonant Pressure Microsensor with a Wide Pressure Measurement Range

Cited by 13 publications

References 35 publications

A resonant high-pressure sensor based on dual cavities

A resonant high-pressure sensor based on dual cavities

Research on Integrated 3D Printing of Microfluidic Chips

Effects of Resonator Shape on Nonlinear Resonant Frequencies of a Microresonant Pressure Sensor

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