Inefficient fluid machinery used in the energy and transportation sector is responsible for significant amounts of greenhouse gas emissions. To improve efficiency, it is necessary to characterize and reduce flow separation on curved surfaces. To this end, researchers have developed a flexible, thin film micro-electromechanical system (MEMS)-based airflow sensor that can be utilized to measure complex, three-dimensional flow separation in curved walls for high-speed airflows.
The energy and transportation sectors often make use of different kinds of fluid machinery, including pumps, turbines, and aircraft engines, all of which entail a high carbon footprint. This results mainly from inefficiencies in the fluid machinery that are caused by flow separation around curved surfaces, which are typically quite complex in nature.
To improve the efficiency of fluid machinery, one therefore needs to characterize near-wall flow on the curved surface to suppress this flow separation. The challenge in accomplishing this is multifold. First, conventional flow sensors are not flexible enough to fit into the curved walls of fluid machinery. Second, existing flexible sensors suitable for curved surfaces cannot detect the fluid angle (direction of flow). Moreover, these sensors are limited to only detecting flow separation at speeds less than 30 meters per second.
In a new study, Professor Masahiro Motosuke from the Tokyo University of Science (TUS) and his colleagues, took on this challenge. “Sensing the shear stress and its direction on curved surfaces, where flow separation easily occurs, has been difficult to achieve without using a novel technique,” said Professor Motosuke. Their work was published in Volume 13 Issue 8 of Micromachines on 12 August 2022.
The team developed a polyimide thin film-based flexible flow sensor that can be easily installed on curved surfaces without disturbing the surrounding airflow, a key requirement for efficient measurement. To enable this, the sensor was based on MEMS technology. The design allowed multiple sensors to be integrated for simultaneous measurement of the wall shear stress and flow angle on the surface of the wall.
To measure the shear stress on the walls, the sensor measured the heat loss from a micro-heater, while the flow angle was estimated using an array of six temperature sensors around the heater that facilitated multidirectional measurement. The team conducted numerical simulations of the air flow to optimize the geometry of the heaters and sensor arrays. Using a high-speed airflow tunnel as the testing environment, they achieved effective flow measurements for a wide range of airflow speeds from (30 -170) meters per second. The sensor demonstrated both high flexibility and scalability. “The circuits around the sensor can be pulled out using a flexible printed circuit board and installed in a different location, so that only a thin sheet is attached to the measurement target, minimizing the effect on the surrounding flow,” said Professor Motosuke.
The team estimated the heater output to vary as the one-third power of the wall shear stress, while the sensor output comparing the temperature difference between two oppositely placed sensors demonstrated a peculiar sinusoidal oscillation as the flow angle was changed.
The developed sensor has the potential for a wide range of applications in industrial-scale fluid machinery that often involve complex flow separation around three-dimensional surfaces. Moreover, the working principle used to develop this sensor can be extended to flows at speeds that are far lower than high-speed subsonic airflows.
“Although this sensor is designed for fast airflows, we are currently developing sensors that measure liquid flow and can be attached to humans based on the same principle. Such thin and flexible flow sensors can open up many possibilities,” said Professor Motosuke.
This novel MEMS sensor could be a game-changer in the development of efficient fluid machineries with reduced detrimental effects on our environment.