Family of Micromachined Wall Hot-Wire Sensors on Polyimide Foil

Buder, U.; Berns, Andreas; Klitzing, Jan-Phillip von; Obermeier, Ε.; Petz, Ralf; Nitsche, W.

doi:10.2514/1.25033

Cited by 6 publications

(6 citation statements)

References 26 publications

(27 reference statements)

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“…The sensor arrays presented here rely on the same principle as [8], but substantial improvements have been achieved. The major drawbacks of the existing sensors are improved.…”

Section: Introductionmentioning

confidence: 98%

“…Unfortunately, the commercially available arrays are not optimized regarding the heat losses into the substrate or their dynamic behavior. To address this issue, a flexible sensor has been presented, on which the thermal transport mechanisms have been simulated and later been improved [8]. The result is a flexible hot-film sensor, being fabricated by dry-etching the substrate under the sensing element.…”

Section: Introductionmentioning

confidence: 99%

“…For aerodynamic measurements, a different sensor concept has been presented, namely a wall shear stress sensor [8]. The working principle is based on heat transfer from a heated film into the fluid, similar to a hot-wire anemometer [9].…”

Section: Introductionmentioning

confidence: 99%

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Flexible hot-film anemometer arrays for flow measurements on curved structures

et al. 2013

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In this paper, a set of flexible aeroMEMS sensor arrays for flow measurements in boundary layers is presented. The sensor principle of these anemometers is based on convective heat transfer from a hot-film into the fluid. All sensors consist of a nickel sensing element and copper tracks. The functional layers are attached either on a ready-made polyimide foil or on a spin-on polyimide layer. These variants are necessary to meet the varying requirements of measurements in different environments. Spin-on technology enables the use of very thin PI layers, being ideal for measurements in transient flows. It is a unique characteristic of the presented arrays that their total thickness can be scaled from 5 to 52 µm. This is essential, because the maximum sensor thickness has to be adapted to the various thicknesses of the boundary layers in different flow experiments. With these sensors we meet the special requirements of a wide range of fluid mechanics. For less critical flow conditions with much thicker boundary layers, thicker sensors might be sufficient and cheaper, so that ready-made foils are perfect for these applications. Since the presented sensors are flexible, they can be attached on curved aerodynamic structures without any geometric mismatches. The entire development, starting from theoretical investigations is described. Further, the micro-fabrication is explained, including all typical processes e.g. photolithography, sputtering and wet-etching. The wet-etching of the sensing element is described precisely, because the resulting final dimensions are critical for the functional characteristics.

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“…The sensor arrays presented here rely on the same principle as [8], but substantial improvements have been achieved. The major drawbacks of the existing sensors are improved.…”

Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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Flexible hot-film anemometer arrays for flow measurements on curved structures

et al. 2013

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“…By now, plenty of research has proved that wall shear stress (WSS) measurement along the leading edge is a realistic way to detect the separation line/point in real-time. Basically, WSS measurement can be divided into two major schemes: hot-wire/film based shear-stress sensor [108,109] and floating-element based sensor [110][111][112]. The structure of Hotwire/film sensors is relatively simple, employing heated components on the sensor surface to indirectly measure the variation of shear stress, with fast response (around dozens of kilohertz) and high sensitivity (<1 Pa) [108,109].…”

Section: Flexible Shearing Sensorsmentioning

confidence: 99%

“…Basically, WSS measurement can be divided into two major schemes: hot-wire/film based shear-stress sensor [108,109] and floating-element based sensor [110][111][112]. The structure of Hotwire/film sensors is relatively simple, employing heated components on the sensor surface to indirectly measure the variation of shear stress, with fast response (around dozens of kilohertz) and high sensitivity (<1 Pa) [108,109]. Oppositely, floating-element based sensors directly sense the shear-stress force with the floating element.…”

Section: Flexible Shearing Sensorsmentioning

confidence: 99%

Flexible smart sensing skin for “Fly-by-Feel” morphing aircraft

Huang

Zhu

Xiong

et al. 2021

Sci. China Technol. Sci.

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Flexible smart sensing skin is a key enabling technology for the future "Fly-by-Feel" control of morphing aircraft. It represents the next-generation skin of aircraft that can exhibit a more powerful sensing function than a conventional one and could be mounted on arbitrary curvilinear surfaces, especially for advanced autonomic, morphing aircraft. Recent significant technical advances in flexible electronics have overcome many historic drawbacks of conventional smart skin, e.g., only a limited number of discrete block sensors can be integrated due to the inevitable structural damage and heavy guidelines. Herein, we review the key developments in flexible sensors technology and highlight both the state-of-the-art devices and the potential applications for the measurement of aircraft. We begin with the importance of flexible smart skin for morphing aircraft and then expand to the latest progress in various types of flexible sensors. Then we highlight flexible sensors as smart skin to measure aerodynamic parameters and monitor the structural health, and further to achieve the Fly-by-Feel control. Finally, the challenges and opportunities on flexible smart sensing skin are discussed, from the functional design to practical applications.

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