μ-Biomimetic flow-sensors--introducing light-guiding PDMS structures into MEMS

In the area of biomimetics, engineers use inspiration from natural systems to develop technical devices, such as sensors. One example is the lateral line system of fish. It is a mechanoreceptive system consisting of up to several thousand individual sensors called neuromasts, which enable fish to se...

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Veröffentlicht in:	Bioinspiration & biomimetics 2015-06, Vol.10 (3), p.036001-036001
Hauptverfasser:	Herzog, Hendrik, Klein, Adrian, Bleckmann, Horst, Holik, Peter, Schmitz, Sam, Siebke, Georg, Tätzner, Simon, Lacher, Manfred, Steltenkamp, Siegfried
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Sprache:	eng
Schlagworte:	Animals Biomimetics Biomimetics - instrumentation Devices Dimethylpolysiloxanes - chemistry Equipment Design Equipment Failure Analysis Fish Fishes - physiology Lateral Line System - physiology Light Medical Micro-Electrical-Mechanical Systems - instrumentation Microelectromechanical systems Refractometry - instrumentation Rheology - instrumentation Sensors Surface Plasmon Resonance - instrumentation Thick films Transducers Water flow
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container_title	Bioinspiration & biomimetics
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creator	Herzog, Hendrik Klein, Adrian Bleckmann, Horst Holik, Peter Schmitz, Sam Siebke, Georg Tätzner, Simon Lacher, Manfred Steltenkamp, Siegfried
description	In the area of biomimetics, engineers use inspiration from natural systems to develop technical devices, such as sensors. One example is the lateral line system of fish. It is a mechanoreceptive system consisting of up to several thousand individual sensors called neuromasts, which enable fish to sense prey, predators, or conspecifics. So far, the small size and high sensitivity of the lateral line is unmatched by man-made sensor devices. Here, we describe an artificial lateral line system based on an optical detection principle. We developed artificial canal neuromasts using MEMS technology including thick film techniques. In this work, we describe the MEMS fabrication and characterize a sensor prototype. Our sensor consists of a silicon chip, a housing, and an electronic circuit. We demonstrate the functionality of our μ-biomimetic flow sensor by analyzing its response to constant water flow and flow fluctuations. Furthermore, we discuss the sensor robustness and sensitivity of our sensor and its suitability for industrial and medical applications. In sum, our sensor can be used for many tasks, e.g. for monitoring fluid flow in medical applications, for detecting leakages in tap water systems or for air and gas flow measurements. Finally, our flow sensor can even be used to improve current knowledge about the functional significance of the fish lateral line.
doi_str_mv	10.1088/1748-3190/10/3/036001
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In sum, our sensor can be used for many tasks, e.g. for monitoring fluid flow in medical applications, for detecting leakages in tap water systems or for air and gas flow measurements. 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In sum, our sensor can be used for many tasks, e.g. for monitoring fluid flow in medical applications, for detecting leakages in tap water systems or for air and gas flow measurements. 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subjects	Animals Biomimetics Biomimetics - instrumentation Devices Dimethylpolysiloxanes - chemistry Equipment Design Equipment Failure Analysis Fish Fishes - physiology Lateral Line System - physiology Light Medical Micro-Electrical-Mechanical Systems - instrumentation Microelectromechanical systems Refractometry - instrumentation Rheology - instrumentation Sensors Surface Plasmon Resonance - instrumentation Thick films Transducers Water flow
title	μ-Biomimetic flow-sensors--introducing light-guiding PDMS structures into MEMS
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