Modeling of magnetic shape memory alloy plates for pressure sensor application

Salarieh, Hassan; Naderi, Hossein

doi:10.1177/1045389x20947170

Cited by 2 publications

(1 citation statement)

References 20 publications

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“…In addition, with the development of the biomedical field, the requirements for the focusing accuracy of microscopic imaging have reached the sub-micron or even nanometer level. The total internal reflection fluorescence microscopic imaging depth of membrane surface protein movement is close to 70nm-300nm, and the height between the objective lens and the slide needs to be adjusted for focusing to obtain clear images with a position accuracy of nanometer level [1,2] . Traditional driving mechanisms such as servo motors, linear motors, and rigid driving mechanisms such as precision screw and precision guide rails, etc.…”

Section: Introductionmentioning

confidence: 99%

Magnetic shape memory alloy driver mechanism and nonlinear hysteresis model

Zhang,

Liu,

2024

International Conference on Image Processing and Artificial Intelligence (ICIPAl 2024)

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The dynamic performance (stroke, resolution, speed, etc.) of the focusing mechanism of a microscopic imaging system is the key factor affecting the image quality and detection efficiency. The focusing speed and resolution of the microscopic imaging system depend on the ultra-precise motion of the focusing mechanism. In this study, magnetic shape memory alloy(MSMA) is used to develop a driver for rapid focusing of microscopic imaging system.The more accurate mathematical model is established to study nonlinear control method, improve the accuracy of magnetic shape memory alloy, The magnetic shape memory alloy driver can be applied to realize fast and high-precision focusing in microscopic imaging system, which provides a new idea for focusing device in microscopic imaging system.

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Section: Introductionmentioning

confidence: 99%

Magnetic shape memory alloy driver mechanism and nonlinear hysteresis model

Zhang,

Liu,

2024

International Conference on Image Processing and Artificial Intelligence (ICIPAl 2024)

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Optimisation of Active Magnetic Elements in Beam-like Structures—Numerical Modelling Studies

Majewska

2024

Materials

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This paper explores integrating advanced materials, including magnetic shape memory alloys, magnetorheological fluids, and classical shape memory alloys, within structural elements to achieve exceptional physical properties. When these materials are integrated within structures—whether as wires, actuators, or dampers—they provide the structures with unique static, dynamic, and damping characteristics not commonly found in nature. This study aimed to evaluate the efficacy of these active materials in enhancing the performance of beam-like structures. This investigation was conducted through a comprehensive numerical analysis, focusing on a composite beam. The study examined the impact of different active elements, their position within the structure, and their influence on key dynamic properties. Additionally, a simplified damage scenario was considered, wherein the adverse effects of structural damage were mitigated through the strategic application of these materials. Numerical simulations were carried out using the finite element method, with custom computational codes developed in MATLAB. The findings of these simulations are presented and discussed in this paper.

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Modeling of magnetic shape memory alloy plates for pressure sensor application

Cited by 2 publications

References 20 publications

Magnetic shape memory alloy driver mechanism and nonlinear hysteresis model

Magnetic shape memory alloy driver mechanism and nonlinear hysteresis model

Optimisation of Active Magnetic Elements in Beam-like Structures—Numerical Modelling Studies

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