Provided is a linear vibration motor, including: a housing having a receiving space; a vibration unit received in the receiving space; an elastic assembly configured to suspend the vibration unit in the receiving space, and a driving unit fixed to the housing and configured to drive the vibration unit to vibrate. The linear vibration motor includes a coil assembly and two first permanent magnets respectively provided at two sides of the coil assembly. The vibration unit includes one of the coil assembly and the first permanent magnets, and the driving unit includes the other one. When the vibration unit is static, a central axis of the first permanent magnet perpendicular to a vibrating direction of the vibration unit and a central axis of the coil assembly perpendicular to the vibrating direction of the vibration unit are spaced apart from each other in the vibrating direction of the vibration unit.

A transducer assembly configured to convert a pyrotechnic initiation to an electrical signal may comprise a magnet, a hollow tube, and a conductive element. The hollow tube may be wrapped around the magnet in the shape of a coil. The hollow tube may be at least partially filled with a thermite. The conductive element may be coupled to an outlet of the hollow tube. The conductive element may seal the outlet of the hollow tube.

An energy harvester coupled to a vibration source includes a housing, a transducer, and an amplifier. The transducer may have a first part and a second part. The first part and the second part may move relative to each other along a central axis in response to a motion from the vibration source. The amplifier is coupled to the housing and operable to amplify an amplitude of the motion received from the vibration source. The amplifier has an input member coupled to the vibration source and an output member coupled to the first part of the transducer. The input member moves at a distance D1 in response to the motion from the vibration source. The output member moves the first part of the transducer in response to the input member moving. The first part of the transducer moves along the central axis by a distance D2, where D2>D1.

An energy harvester coupled to a vibration source includes a housing, a transducer, and an amplifier. The transducer may have a first part and a second part. The first part and the second part may move relative to each other along a central axis in response to a motion from the vibration source. The amplifier is coupled to the housing and operable to amplify an amplitude of the motion received from the vibration source. The amplifier has an input member coupled to the vibration source and an output member coupled to the first part of the transducer. The input member moves at a distance D1 in response to the motion from the vibration source. The output member moves the first part of the transducer in response to the input member moving. The first part of the transducer moves along the central axis by a distance D2, where D2>D1.

A switch power generating mechanism includes at least a first movable component, a second movable component, a first deforming component connected to the first movable component, and a power generator, wherein a pressing force is transmitted to the second movable component from the outside of the switch power generating mechanism to cause at least part of the first movable component and at least part of the second movable component to move in a connected manner and cause the first movable component to rotate by a fixed amount to deform the first deforming component by a fixed amount; and the deformation of the first deforming component is released once the first movable component has been caused to rotate by the fixed amount, and power generation is performed with power generated in the power generator due to the first movable component rotated by a fixed amount with the release from the deformation.

A triboelectric generator include at least two yarns, one of which has been infiltrated with a material having a positive triboelectric affinity and one of which has been infiltrated with a material having a negative triboelectric affinity. The at least two yarns are threaded through holes within a disk so that both of the yarns are disposed on both sides of the disk and pass through the holes within the disk. The at least two yarns are helically wrapped (or “coiled”) together on both sides of the disk. During uncoiling, the moving contact between the two yarns, infiltrated with materials having opposite triboelectric affinities, causes an electrical charge to develop. The generated electrical charge can be conducted away for use as electricity.

A voltage generator for converting a movable magnetic field into electrical voltage. The voltage generator includes an excitation unit, a conversion unit, and a power line unit. The excitation unit includes at least one magnet which is arranged on a body which is rotatably and/or moveably mounted. The at least one magnet generates a magnetic field. The conversion unit functionally cooperates with the excitation unit. The conversion unit includes a support body and a magnetization wire which is magnetized by the magnetic field. The magnetization wire includes, over its cross-section, a magnetically hard part and a magnetically soft part. The magnetization wire is wound around the support body to provide an axial tension. The power line unit functionally cooperates with the conversion unit. The power line unit includes an electric coil which is arranged around the conversion unit. The electric coil includes an electrifiable current conductor wire.

According to one embodiment, a power control circuit includes a converter, a signal generating circuit, an estimation unit, and a controller. The converter includes a switching circuit and is configured to transform an output voltage from a power generator. The signal generating circuit is configured to transmit a signal to the switching circuit. The estimation unit is configured to determine a switching operation condition based on vibration information indicative of a vibration applied to the power generator. The controller is configured to control an operation of the switching circuit based on the determined switching operation condition.

According to one embodiment, a power control circuit includes a converter, a signal generating circuit, an estimation unit, and a controller. The converter includes a switching circuit and is configured to transform an output voltage from a power generator. The signal generating circuit is configured to transmit a signal to the switching circuit. The estimation unit is configured to determine a switching operation condition based on vibration information indicative of a vibration applied to the power generator. The controller is configured to control an operation of the switching circuit based on the determined switching operation condition.

An electrical power generator includes a first part having an elongated shape, a first end and a second end. The first part is arranged for attachment to a base in correspondence with the first end and configured to be located in a fluid and configured such that, when said fluid moves, the first part generates vortices in said fluid so that a lift force is generated on the first part, which produces an oscillating movement of the first part. In addition, the generator includes a subsystem configured for converting the oscillating movement of the first part into electrical energy. The subsystem is at least partially housed within the first part.