It’s a Bird, It’s a Plane: Flow Patterns Around an Oscillating Piezoelectric Fan Blade

Engineers at Nokia Bell Labs use multiphysics simulation to capture the interplay between an oscillating piezoelectric fan and the surrounding airflow in the pursuit of a quiet, reliable, and low-energy cooling solution.

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COMSOL Multiphysics is used to design piezoelectric fans, a stepping stone between natural and forced convection.

The following is an excerpt from Multiphysics Simulation 2017. 

From a snake’s movement, to a gecko’s climbing grip, to a cheetah’s running stride, bio-inspired design is making its way into robotics, electronics, and medical device innovations. Among the creatures that have influenced recent tech developments, the motion of a bird’s wings has inspired the creation of an oscillating piezoelectric fan blade.

As electronics have grown smaller and smaller, and are used for extended periods of time, the internal heat load is greater, demanding new, compact cooling methods. Piezoelectric fans - in which a piezoelectric material expands and contracts as voltage is applied to it, triggering movement of a cantilever blade and consequent air flow – are reliable, low-power, and quiet, making them promising in this application.

Among those furthering the science behind this concept are Akshat Agarwal and Ronan Frizzell of Nokia Bell Labs, who worked to characterize air flow around the fans. The insight into the air flow patterns around an oscillating blade has relevance in unexpected applications with similar air flow as well.

A Stepping Stone Between Natural and Forced Convection

Designers of electronic devices used for extensive amounts of time usually rely on either natural convection or forced convection by way of powered fans to manage heat generation. However, forced convection requires a significant amount of power and doesn’t scale down well to the small scale needed for today’s generation of electronics.

Halfway between natural and forced convection, a piezoelectric material provides heat handling ability by expanding and contracting when a voltage is applied, resulting in an oscillating movement of the attached fan blade that initiates air flow. As Frizzell explained, “A piezoelectric fan is a stepping stone. Natural convection is preferred when possible, but in certain cases, it makes sense to incorporate an active part to move the air.” The fan blade used in the research at Nokia consists of a piezoelectric material bonded to an acetate strip and a mylar shim (Figure 1).

Figure 1: The fan consists of a piezoelectric ceramic attached to a flexible acetate blade. The assembly is affixed to a mylar shim with electrical contact points for the piezoelectric ceramic.Figure 1: The fan consists of a piezoelectric ceramic attached to a flexible acetate blade. The assembly is affixed to a mylar shim with electrical contact points for the piezoelectric ceramic.

With a dynamic system on a small scale, understanding the fluid dynamics can be tricky. In order to truly capture the air flow around the oscillating beam, the engineers at Nokia needed to expand upon work that had been done in two dimensions to three-dimensional simulations and physical testing.

Determining the Air Flow Pattern

Engineers at Nokia Bell Labs first characterized the system experimentally using phase-locked particle image velocimetry (PIV), which allowed them to determine the vorticity and in-plane velocity of an unconfined fan in free space (Figure 2), for a total of 11 positions of the oscillating beam. For each position, data was acquired along 5 x-y planes and 5 x-z planes to obtain a 3D field.

Figure 2: Phase locked PIV measurements for the vorticity (colored contour map) and the in-plane velocity (vector field) of an unconfined fan.

Figure 2: Phase locked PIV measurements for the vorticity (colored contour map) and the in-plane velocity (vector field) of an unconfined fan.Figure 2: Phase locked PIV measurements for the vorticity (colored contour map) and the in-plane velocity (vector field) of an unconfined fan.

The next step was to model the beam-air interaction to gain further insight into the system. When it came to determining a strategy for the simulation, speed and accuracy were key considerations.

“It was important for us to be able to accurately model fluid flow around the blade as fast as possible,” Frizzell said. “This would let us virtually perform design iterations and investigate how these blades would behave in many different situations.”

The engineers first looked at modeling methods used in literature, but the computational demands of such approaches led them to consider another approach. COMSOL® would demand fewer computational resources and included the arbitrary Lagrangian-Eulerian method, the preferred method for simulating the physics of this system. This method combines fluid flow formulated using an Eulerian description with solid mechanics formulated using a Lagrangian description.

Agarwal used COMSOL® to perform a 3D bi-directional fluid-structure interaction (FSI) analysis of the forces and fluid behavior in and around the oscillating blade. This analysis allowed him to accurately capture the physics of the system. Thanks to the flexibility of COMSOL®, Agarwal was able to simplify the design in some of his simulations, to select the best approach in each aspect of the simulation.

To simplify the study for computational efficiency, the engineers modeled the shear force and fluid pressure during the movement instead of studying the fan actuation itself. The simulation results revealed the fluid velocity (Figure 3), as well as the structures of the vortices and their movement around the fan blade.

Figure 3: The COMSOL simulation shows the vorticity and the velocity field at two positions during oscillation.Figure 3: The COMSOL simulation shows the vorticity and the velocity field at two positions during oscillation.

“We obtained a picture of the air flow close to the blade, with a better resolution than what we could get from experimental results. At the edge of the blade is where most flow occurs and momentum is greatest. From our experiments we were able to look at the velocimetry image and capture planes of motion. Then we stitched those planes together to obtain the shape of the vortices. But the resolution is limited because you can only get a certain number of planes during an experiment,” Agarwal added. “When you do a full 3D simulation of such a problem, you can study velocity close to the fan and far away, and you can plot many different variables.”

“The software also provides a way to extract data evaluated on the mesh or grid defined by the user —that data can then be used however needed, for example, in another software, or processed with a script,” Agarwal finished. He and Frizzell performed postprocessing to generate representations of the vorticity in the air flow around the blade.

Multiphysics Simulation and Experiment: A Powerful Combination

The Nokia Bell Labs team found that their simulations captured all the details and dynamics of the system and the simulations analyzed air flow and movement near the blade in more detail than physical experimentation alone. Their study resulted in a validated model that they expect to use as a benchmark in future designs. Knowledge from their results can be even used for applications in other fields, such as flapping wing unmanned aerial vehicles (UAVs).

“The power of COMSOL is that we can implement new geometries and optimize the design much more quickly. I was able to play with the design and take the best of the design features that I was after,” Agarwal concluded. Future studies may examine the air flow and fluid dynamics around more than one oscillating blade, to understand how multiple fans used together might impact the cooling effect.

Click here to read the 2017 edition of Multiphysics Simulation and learn how mathematical modeling and multiphysics simulation are being leveraged as a powerful tool in many other industries.

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