Calibration Model Optimization for Strain Metrology of Equal Strength Beams Using Deflection Measurements

Yan, Yonggang; Wu, Zhengxing; Cui, Jianjun; Chen, Kai; Tang, Yanhong; Yang, Ning

doi:10.3390/s23063059

Cited by 6 publications

(4 citation statements)

References 20 publications

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“…The curved metallic substrate was subjected to all degrees of freedom on one end, while the other end experienced strain through a load applied to the CPTFSG. In the current study of strain sensors on planes, strain sensors can be calibrated using equal-strain beams or beam-theoretical computations to determine the amount of strain applied to the sensor. , On the contrary, strains on curved surfaces are more challenging to calculate than those on planes. In this work, a commercial strain transducer was installed on the back of the curved substrate for strain calibration.…”

Section: Resultsmentioning

confidence: 99%

Conformal Fabrication of Thick Film Platinum Strain Gauge Via Error Regulation Strategies for In Situ High-Temperature Strain Detection

Chen,

Zhao,

Zeng

et al. 2023

ACS Appl. Mater. Interfaces

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Monitoring high-temperature strain on curved components in harsh environments is a challenge for a wide range of applications, including in aircraft engines, gas turbines, and hypersonic vehicles. Although there are significant improvements in the preparation of high-temperature piezoresistive film on planar surfaces using 3D printing methods, there are still difficulties with poor surface compatibility and high-temperature strain testing on curved surfaces. Herein, a conformal direct ink writing (CDIW) system coupled with an error feedback regulation strategy was used to fabricate high-precision, thick films on curved surfaces. This strategy enabled the maximum amount of error in the distance between the needle and the substrate on a curved surface to be regulated from 155 to 4 μm. A conformal Pt thick-film strain gauge (CPTFSG) with a room-temperature strain coefficient of 1.7 was created on a curved metallic substrate for the first time. The resistance drift rate at 800 °C for 1 h was 1.1%, which demonstrated the excellent stability and oxidation resistance of the CPTFSG. High-temperature dynamic strain tests up to 769 °C revealed that the sensor had excellent high-temperature strain test performance. Furthermore, the CPTFSG was conformally deposited on an aero-engine turbine blade to perform in situ tensile and compressive strain testing at room temperature. High-temperature strain tests were conducted at 100 and 200 °C for 600 and 580 με, respectively, demonstrating a high steady-state response consistent with the commercial high-temperature strain transducer. In addition, steady-state strain tests at high temperatures up to 496 °C were tested. The CDIW error modulation strategy provides a highly promising approach for the high-precision fabrication of Pt thick films on complex surfaces and driving in situ sensing of hightemperature parameters on curved components toward practical applications.

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Section: Resultsmentioning

confidence: 99%

Conformal Fabrication of Thick Film Platinum Strain Gauge Via Error Regulation Strategies for In Situ High-Temperature Strain Detection

Chen,

Zhao,

Zeng

et al. 2023

ACS Appl. Mater. Interfaces

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“…Finally, a highly conductive thin film composed of multiple layers of graphene was obtained through highpressure rolling. In addition, as a carbon material, graphene has good chemical stability and adaptability to complex environments compared with metal materials [40]. Based on the four-probe method [41], the graphene film showed a high conductivity of 1.1 × 10 6 S m −1 .…”

Section: Methodsmentioning

confidence: 99%

“…The patch antenna was pasted onto an equal strength beam, and the loading process was conducted by adding weights. Equal strength beams were commonly used in the research and calibration of strain sensors [40]. The strain of the beam was transmitted to the antenna, causing a change in the size of the antenna patch and a shift in its resonant frequency.…”

Section: Lateral and Longitudinal Strain Measurementmentioning

confidence: 99%

Bidirectional large strain monitoring using a novel graphene film-based patch antenna sensor

Weng,

Peng,

Gao

et al. 2024

Smart Mater. Struct.

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This study proposes a rectangular microstrip patch antenna sensor based on a high-conductivity graphene film for bidirectional strain detection in structural health monitoring (SHM). By using a highly conductive graphene film instead of traditional metal foil to produce a patch antenna, the antenna possesses a higher flexibility and a larger sensing range. The mechanical, electromagnetic, and radiative properties were investigated. The strain sensing principle based on the resonant frequency offset of the graphene film antenna was proposed. The relationships between the resonant frequency shift and structural strain were quantitatively explored through theoretical deductions, finite element simulations, and experiments. According to the experimental results, the shift in the resonant frequency was linearly related to the lateral and longitudinal strains. The sensitivity coefficients for the lateral and longitudinal strains were 2.2037 kHz/με and 3.6198 kHz/με, respectively. The thermal strain can be distinguished based on the linear resonant frequency-temperature relationship. The results demonstrated the advantages and prospects of the proposed novel patch antenna for SHM.

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“…Yan et al [ 22 ] adopted analytical methods such as finite element analysis and measurement experiments to solve the problems existing in the measurement model. By modifying the conventional deflection method measurement model, they obtained the engineering measurement application model.…”

Section: Introductionmentioning

confidence: 99%

Research on a Precision Calibration Model of a Flexible Strain Sensor Based on a Variable Section Cantilever Beam

Wang

Cui

Tang

et al. 2023

Sensors

Self Cite

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The flexible strain sensor’s measuring range is usually over 5000 με, while the conventional variable section cantilever calibration model has a measuring range within 1000 με. In order to satisfy the calibration requirements of flexible strain sensors, a new measurement model was proposed to solve the inaccurate calculation problem of the theoretical strain value when the linear model of a variable section cantilever beam was applied to a large range. The nonlinear relationship between deflection and strain was established. The finite element analysis of a variable section cantilever beam with ANSYS shows that the linear model’s relative deviation is as high as 6% at 5000 με, while the relative deviation of the nonlinear model is only 0.2%. The relative expansion uncertainty of the flexible resistance strain sensor is 0.365% (k = 2). Simulation and experimental results show that this method solves the imprecision of the theoretical model effectively and realizes the accurate calibration of a large range of strain sensors. The research results enrich the measurement models and calibration models for flexible strain sensors and contribute to the development of strain metering.

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Calibration Model Optimization for Strain Metrology of Equal Strength Beams Using Deflection Measurements

Cited by 6 publications

References 20 publications

Conformal Fabrication of Thick Film Platinum Strain Gauge Via Error Regulation Strategies for In Situ High-Temperature Strain Detection

Conformal Fabrication of Thick Film Platinum Strain Gauge Via Error Regulation Strategies for In Situ High-Temperature Strain Detection

Bidirectional large strain monitoring using a novel graphene film-based patch antenna sensor

Research on a Precision Calibration Model of a Flexible Strain Sensor Based on a Variable Section Cantilever Beam

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