3D-Printed Load Cell Using Nanocarbon Composite Strain Sensor

Joung, Kwan Young; Kim, Sung Yong; Kang, Inpil; Cho, Sung Ho

doi:10.3390/s21113675

Cited by 10 publications

(4 citation statements)

References 30 publications

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“…Generally, they are the key part of digital weighing systems. These measurements are made using the pressure principle by the load cell [17,18]. (4) The integrated "AVIA SEMICONDUCTOR" HX711 24-bit precision analog to digital converter (ADC) was developed for digital weighing sensors in industrial control applications that are linked to bridge sensors [19,20].…”

Section: Needs Approachmentioning

confidence: 99%

Development and Implementation of an RFID-Enabled Automatic Rice Vending System Using Arduino Mega 2560

Ritzkal,

Prakosa,

Aprian

et al. 2024

ISI

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Section: Needs Approachmentioning

confidence: 99%

Development and Implementation of an RFID-Enabled Automatic Rice Vending System Using Arduino Mega 2560

Ritzkal,

Prakosa,

Aprian

et al. 2024

ISI

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“…However, most conventional strain sensors exhibit linearity only up to the elastic limit, followed by nonlinearity, which renders sensor calibration difficult and reduces the reliability of large deformation measurements. [29,30] The linearity in the ML response indicates that strain transfers from the AA7075-T6 surface to the matrix and from the matrix to the SAO particle are linearly proportional despite the plastic flow in the AA7075-T6 and in the matrix (Figure S4, Supporting Information). In addition, the linearity in the ML is expected to originate from the elastic deformation of the SAO particles because the stress accumulated in the epoxy matrix is likely to be insufficient to initiate plastic deformation in the SAO particles, which are highly rigid compared with the matrix (E SAO /E matrix ≈ 67, where E is the Young's modulus).…”

Section: Field To Effective Strain Field Mappingmentioning

confidence: 99%

Digital Image Correlation Compatible Mechanoluminescent Skin for Structural Health Monitoring

et al. 2022

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Monitoring structural health using mechanoluminescent (ML) effects is widely considered as a potential full‐field and direct visualizing optical method with high spatial and temporal resolution and simple setup in a noncontact manner. The challenges and uncertainties in the mapping of ML field to effective strain field, however, tend to limit significant commercial ML applications for structural health monitoring systems. Here, however, quantification problems are resolved using the digital image correlation (DIC) method. Specifically, an image containing mechanically induced photon information is processed using a DIC algorithm to measure the strain field components, which enables the establishment of a calibration curve when the ML field is mapped onto the effective strain field using pixel level information. The results show a linear relationship between effective strain and ML intensity despite the plastic flow in ML skin. Furthermore, the calibration curve allows for easy conversion of ML field to effective‐strain field at the crack‐tip plastic zone of the alloy structure, retaining its spatial resolution. The compatibility of ML skin with the DIC algorithm not only enables the quantification of the ML effects of several organic/inorganic ML materials, but may also be useful in elucidating the fundamentals of the trap‐controlled mechanism.

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“…It has been found that TPU can be combined with multi-walled carbon nanotubes (MWCNTs) to fabricate a piezoresistive strain sensor using the FDM technology (Joung et al , 2021; Xiang et al , 2019; Christ et al , 2019). The carbon nanotube (CNT)–TPU-based sensor shows good cyclic repeatability, and the steady-state behaviour reaches relatively quickly.…”

Section: Introductionmentioning

confidence: 99%

Sensitivity enhancement through geometry modification of 3D printed conductive PLA-based strain sensors

S.K.,

Kallippatti Lakshmanan

2023

RPJ

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Purpose The purpose of this study is to increasing the gauge factor, reducing the hysteresis error and improving the stability over cyclic deformations of a conductive polylactic acid (CPLA)-based 3D-printed strain sensor by modifying the sensing element geometry. Design/methodology/approach Five different configurations, namely, linear, serpentine, square, triangular and trapezoidal, of CPLA sensing elements are printed on the thermoplastic polyurethane substrate material individually. The resistance change ratio of the printed sensors, when loaded to a predefined percentage of the maximum strain values over multiple cycles, is recorded. Finally, the thickness of substrate and CPLA and the included angle of the triangular strain sensor are evaluated for their influences on the sensitivity. Findings The triangular configuration yields the least hysteresis error with high accuracy over repeated loading conditions, because of its uniform stress distribution, whereas the conventional linear configuration produces the maximum sensitivity with low accuracy. The thickness of the substrate and sensing element has more influence over the included angle, in enhancing the sensitivity of the triangular configuration. The sensitivity of the triangular configuration exceeds the linear configuration when printed at ideal sensor dimensional values. Research limitations/implications The 3D printing parameters are kept constant for all the configurations; rather it can be varied for improving the performance of the sensor. Furthermore, the influences of stretching rate and nozzle temperature of the sensing material are not considered in this work. Originality/value The sensitivity and accuracy of CPLA-based strain sensor are evaluated for modification in its geometry, and the performance metrics are enhanced using the regression modelling.

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3D-Printed Load Cell Using Nanocarbon Composite Strain Sensor

Cited by 10 publications

References 30 publications

Development and Implementation of an RFID-Enabled Automatic Rice Vending System Using Arduino Mega 2560

Development and Implementation of an RFID-Enabled Automatic Rice Vending System Using Arduino Mega 2560

Digital Image Correlation Compatible Mechanoluminescent Skin for Structural Health Monitoring

Sensitivity enhancement through geometry modification of 3D printed conductive PLA-based strain sensors

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