Control concepts for dielectric elastomer actuators

“…Furthermore it should be noted that controlling the upper semiconductor switches of the full-bridge circuits requires more complex, floating driver circuitry. From a circuit point of view, the only difference between the Isolated Bidirectional Full-Bridge converter (IBFBC) 4,11,17 , shown in Figure 4a), and the DAB converter 18 , depicted in Figure 4b), is the position of the inductance L dSk or L DABk . Each converter module consists of one primary full-bridge circuit comprising the semiconductor switches S 1k …S 4k and antiparallel diodes D 1k …D 4k and one secondary full-bridge circuit including the switches S 5k …S 8k and the diodes D 5k …D 8k coupled via the high frequency transformer T k .…”

“…4 As shown for an inductive load in Figure 1a), a controlled voltage source has to be used in order to control the current through the inductance, which is described by the differential equation v L = L·di L /dt. Complementary, for driving a capacitive load, exemplified in Figure 1b), a controlled current source has to be realized, which allows to control the voltage v C according to the differential equation i C = C·dv C /dt.…”

Bidirectional power electronics for driving dielectric elastomer transducers

“…Furthermore it should be noted that controlling the upper semiconductor switches of the full-bridge circuits requires more complex, floating driver circuitry. From a circuit point of view, the only difference between the Isolated Bidirectional Full-Bridge converter (IBFBC) 4,11,17 , shown in Figure 4a), and the DAB converter 18 , depicted in Figure 4b), is the position of the inductance L dSk or L DABk . Each converter module consists of one primary full-bridge circuit comprising the semiconductor switches S 1k …S 4k and antiparallel diodes D 1k …D 4k and one secondary full-bridge circuit including the switches S 5k …S 8k and the diodes D 5k …D 8k coupled via the high frequency transformer T k .…”

“…4 As shown for an inductive load in Figure 1a), a controlled voltage source has to be used in order to control the current through the inductance, which is described by the differential equation v L = L·di L /dt. Complementary, for driving a capacitive load, exemplified in Figure 1b), a controlled current source has to be realized, which allows to control the voltage v C according to the differential equation i C = C·dv C /dt.…”

Bidirectional power electronics for driving dielectric elastomer transducers

“…One method of recovering the stored energy from a DEA is to use a DC-DC step-down converter to re-convert the high voltage energy back into its original low voltage form [3][4][5]. This low voltage energy can be returned to the supply (e.g.…”

Transferring electrical energy between dielectric elastomer actuators

“…Here, we consider the full bridge push-pull converter topology with cascaded high-voltage output as proposed in. 4,9 Analyzing this topology, electric losses occur mainly due to the forward resistance R DS(on) of the applied semiconductors and the series resistance R w of the wiring and inductive components, which is considered in R DS(on) . As a specific number of semiconductors is applied in the power electronics (depending on the cascades to reach the output voltage range), the resistance R PE , describing a topology equivalent resistor, is used to determine the losses of the power electronics.…”

Evaluation and optimization of energy harvesting cycles using dielectric elastomers