Theoretical demonstration of a capacitive rotor for generation of alternating current from mechanical motion

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In today’s world, people are increasingly finding themselves carrying several battery-powered portable devices such as mobile phones, laptops and smartwatches. Current research into the field of energy harvesting focuses on efficient transformation of the low frequency mechanical energy that is ordinarily dissipated as heat to useful electrical energy, in small (cm- or mm-scale) devices.

In this work we laid down the theoretical foundation for a light-weight capacitive rotor device which is designed to fit into a shoe sole and generate significant useful electric power of the order of Deci-Watts to Watts.

To explain the basic idea of how this device works, consider an electric circuit composed of an electric load connected in series with two capacitors, one of fixed capacitance, and the other capable of varying its capacitance over time as a result of external mechanical work. The fixed capacitor should be charged prior to the device’s operation. If the system is left on its own, then, eventually, the electric charge will be redistributed between the two capacitors, such that the voltage difference between them becomes zero. A voltage difference between the two capacitors can then be produced by applying mechanical energy to change the capacitance of the time varying capacitor. Subsequently, an electric current is generated, flowing through the resistor, to level the voltage difference between the two capacitors. By repeating this process periodically, an alternating current will be generated in the circuit.

The time-varying capacitor is made of N smaller capacitor stages, all connected in parallel and designed to vary in a completely synchronized fashion to enhance the total change in capacitance. The latter is achieved by connecting all stages through a single axle (see Figure 1), then, upon the axle rotation, a synchronized capacitance change is introduced to all stages.

Each stage is composed of a stationary semi-circular metal electrode and a disc which is part dielectric and part metal. The gap between the disc and the semi-circular electrode is filled with a lubricant. Two different dielectric materials, with different thicknesses, are situated at each half of the disc, thereby, a rotation of the disc will generate a change in capacitance. The dielectric material, facing the semi-circular electrode, is an electric insulator which prevents short-circuits in the case of electrode-disk physical contact.

Figure 1. The device comprises of a multi-stage rotor structure, connected to a reservoir capacitor Cfix, and to an electric load R. The design of the rotor structure is presented (not to scale) with an additional side view of a single stage which consists of a rotating disc and a stationary half-circular metal electrode; in the gap between the two is a lubricating liquid. Each rotating disc is shared by two adjacent stages, connected in a back-to-back fashion, in order to save space, reduce the overall mass and prevent electric shortcuts. All the stages are mounted on a common metal axle, thereby effectively connecting all stages in parallel. To ensure the prevention of shortcuts between the metal axle and the bottom of the half circular electrode, the bottom should be insulated, as depicted by a thin yellow line.  The rotor can be spun by different means, in the figure we show one option of a slide-crank mechanism, however it can equally be rotated by a wind- or water- turbine. Mechanical components to optimize the shaft rotational velocity (gearset, freewheel, and flywheel) have been omitted from the illustration for clarity. 

In the paper we thoroughly analyzed the device’s operation within two different setups: 103 (102) stages with ionic liquid (molecular liquid) lubricant and 10 um (5 nm) gaps between the electrode and disk in each stage. For each of these setups, we estimated (1) the working temperature, by considering the heat entering- and dissipating from- the system (2) the average rotational frequency of the device by matching the external force of foot press to inner drag force from the liquid, and (3) the useful power generated by the rotor device.

By choosing the fixed capacitance to be much larger than the time-varying capacitance, we get an equivalent capacitance approximately equal to that of the varying capacitor, and the fix capacitor just becomes a reservoir of charge. In this case, the generated power of the device will increase with: (1) the amplitude of change in capacitance, (2) the average of time-varying capacitance, (3) the priming voltage used to pre-charge the fixed capacitor, (4) the rotational frequency of the rotor, and (5) the number of stages along the axle.

As we show in the paper, the different thicknesses of dielectric materials are designed to maximize the amplitude of change in capacitance, while the average capacitance is mainly determined by that of the lubricating liquid. To get a realistic evaluation for the capacitance of the molecular liquid in nano-confined spaces and for the capacitance of ionic liquid in micro-confined spaces, we performed detailed molecular dynamics simulations. The cap on the priming voltage was determined by the dielectric breakdown voltage of the liquid or by the safety voltage for wearable items, the smaller of the two. 

The working temperature, in both setups, is greater than that of environment by a negligible amount. The average rotational frequency was evaluated as ~32 s-1 and ~3.5 s-1 for the ionic liquid and molecular liquid setups correspondently. The power generated for each setup is plotted against the electric load in Figure 2 and against the rotational frequency in Figure 3.

Figure 2. 

Figure 2. Average power profile against the electric load for different priming voltages for two different setups: (a) molecular liquid (propylene carbonate) and (b) ionic liquid, each presented for three different priming voltages.  

Figure 3. Average power profile as a function of rotational frequency for different loads plotted for two different setups: (a) molecular liquid (propylene carbonate) with 50 V priming voltage and (b) ionic liquid with 4 V priming voltage, each presented for three different loads.

One of the best features of our device is that it does not involve the change of the liquid contact area, as the electrodes remain permanently immersed in the liquids. It is thus based on continuous, hysteresis-free cyclical alteration of the electrode configuration through rotation of the electrode. Other attractive features of this device are that it (i) is expected to minimize hydrodynamic issues (such as turbulence), (ii) results in low friction and, unless deformed, no surface wear, (iii) when carefully designed, might not need to address specific heat management, and (iv) protects the system from electric short-circuits that would appear by physical contact between the disk and the semi-circular electrode (see Figure 1). Concomitantly, it delivers significant power and can easily be scaled up.

Smooth and efficient operation of this device is possible by having a full understanding of the electrical properties of its components and tribology; this work sets a framework for design and engineering, in progress, of such systems.

To know more about this work, please refer to the article “Theoretical demonstration of a capacitive rotor for generation of alternating current from mechanical motion” published in Nature Communications following the link:

Ehud Haimov

Researcher, Tel-Aviv University