A method and apparatus generate electrical currents and/or voltage in tissue using particles composed of liquid crystals and magnetic particles.

A method and apparatus generate electrical currents and/or voltage in tissue using particles composed of liquid crystals and magnetic particles.

An electrostatic device includes: a fixed portion, a moveable portion, and an elastically-supporting portion that are formed in a same substrate; and a first glass package and a second glass package that are anodically bonded to each other on one and the other of front and back surfaces of the substrate with the fixed portion and the elastically-supporting portion separated from each other, the second glass package forms a sealed space in which the moveable portion is arranged between the first and second glass packages, an electret is formed at least partially in the fixed portion and the moveable portion, and a first electrode connected to the fixed portion and exposed on an outer surface of the second glass package and a second electrode connected to the elastically-supporting portion and exposed on the outer surface of the second glass package are formed in the second glass package.

An electrostatic device includes: a fixed portion, a moveable portion, and an elastically-supporting portion that are formed in a same substrate; and a first glass package and a second glass package that are anodically bonded to each other on one and the other of front and back surfaces of the substrate with the fixed portion and the elastically-supporting portion separated from each other, the second glass package forms a sealed space in which the moveable portion is arranged between the first and second glass packages, an electret is formed at least partially in the fixed portion and the moveable portion, and a first electrode connected to the fixed portion and exposed on an outer surface of the second glass package and a second electrode connected to the elastically-supporting portion and exposed on the outer surface of the second glass package are formed in the second glass package.

A power supply circuit that outputs an electric power input from a vibration-driven energy harvesting element to an external load includes a rectifying circuit that rectifies an alternating current power input from the vibration-driven energy harvesting element; a first capacitor that accumulates a power output from the rectifying circuit; a chopper circuit that has a switching element controlling a chopper timing and has an input terminal connected to the first capacitor; and a control signal generation unit that supplies a control signal to the switching element, wherein: the control signal generation unit generates the control signal without referring to a voltage of the first capacitor.

A vibration transducer for sensing vibrations includes a first flexible triboelectric member, a second flexible triboelectric member, a plurality of attachment points, a first electrode and a second electrode. The first flexible triboelectric member includes a first triboelectric layer and a material being on a first position on a triboelectric series. A conductive layer is deposited on the second side thereof. The second flexible triboelectric member includes a second triboelectric layer and a material being on a second position on the triboelectric series that is different from the first position on the triboelectric series. The second triboelectric member is adjacent to the first flexible triboelectric member. When the first triboelectric member comes into and out of contact with the second triboelectric member as a result of the vibrations, a triboelectric potential difference having a variable intensity corresponding to the vibrations can be sensed between the first and second triboelectric members.

A vibration transducer for sensing vibrations includes a first flexible triboelectric member, a second flexible triboelectric member, a plurality of attachment points, a first electrode and a second electrode. The first flexible triboelectric member includes a first triboelectric layer and a material being on a first position on a triboelectric series. A conductive layer is deposited on the second side thereof. The second flexible triboelectric member includes a second triboelectric layer and a material being on a second position on the triboelectric series that is different from the first position on the triboelectric series. The second triboelectric member is adjacent to the first flexible triboelectric member. When the first triboelectric member comes into and out of contact with the second triboelectric member as a result of the vibrations, a triboelectric potential difference having a variable intensity corresponding to the vibrations can be sensed between the first and second triboelectric members.

The invention relates to a miniature kinetic energy harvester (1) for generating electrical energy, comprising: —a support (2), —a first element (3) having walls (32-35) surrounding at least one cavity (31), —at least one spring (4) mounted between the first element (3) and the support (2), the spring (4) being arranged so that the first element (3) may be brought into oscillation relative to the support (2) according to at least one direction (X) of oscillation, —a transducer (5) arranged between the first element (3) and the support (2) for converting oscillation of the first element (3) relative to the support (2) into an electrical signal, —at least one second element (7) housed within the cavity (31) and mounted to freely move within the cavity (31) relative to the first element (3) so as to impact the walls (32-35) of the cavity (31) when the harvester (1) is subjected to vibrations.

The invention relates to a miniature kinetic energy harvester (1) for generating electrical energy, comprising: —a support (2), —a first element (3) having walls (32-35) surrounding at least one cavity (31), —at least one spring (4) mounted between the first element (3) and the support (2), the spring (4) being arranged so that the first element (3) may be brought into oscillation relative to the support (2) according to at least one direction (X) of oscillation, —a transducer (5) arranged between the first element (3) and the support (2) for converting oscillation of the first element (3) relative to the support (2) into an electrical signal, —at least one second element (7) housed within the cavity (31) and mounted to freely move within the cavity (31) relative to the first element (3) so as to impact the walls (32-35) of the cavity (31) when the harvester (1) is subjected to vibrations.

Wireless power transmission (WPT) systems are provided. For example, the WPT system can use one or more power transmitting coils and a receiver for electromagnetically coupled wireless power transfer. The electrodynamic receiver can be in the form of an electrodynamic transducer where a magnet is allowed to oscillate near a receiving coil to induce a voltage in the receiving coil, a piezoelectric transducer where the magnet causes a vibrating structure with a piezoelectric layer to move, an electrostatic transducer where movement of the magnet causes a capacitor plate to move, or a combination thereof. An alternating magnetic field from the transmitting coil(s) excites the magnet in the receiver into mechanical resonance. The vibrating magnet then functions similar to an energy harvester to induce voltage/current on an internal coil, piezoelectric material, or variable capacitor. Embodiments utilize magnetic coupling and electromechanical resonance for safe, spatially distributed, low-frequency power delivery to portable devices.