A watch including a case containing a plate and an electronic module powered by a button cell battery, a conductor electrically connecting the button cell battery to the electronic module and a clamping device capable of ensuring an electrical connection between the button cell battery and the conductor, wherein the clamping device includes a magnet.

A circuit includes: a power generation module a low-frequency motion energy harvesting module, configured to harvest a direct current output by the power generation module when the human body is in a low-frequency motion state; a high-frequency motion energy harvesting module, configured to harvest a direct current output by the power generation module when the human body is in a high-frequency motion state; an energyrespectively connected to the low frequency motion cncrgy harvesting modulo configured to store electrical energy; and a motion switching module, respectively connected to the power generation module, the low-frequency motion energy harvesting module and the high-frequency motion energy harvesting module, and configured to monitor a human body motion state, and control, according to the human body motion state, switching between operation of the low-frequency motion energy harvesting module and operation of the high-frequency motion energy harvesting module, to respectively charge the energy storage module.

A battery holding device includes a battery holding member and a plate. The plate houses the battery holding member. The battery holding member includes a fastener and a battery holder. The fastener is fixed to the plate. The battery holder holds a battery, and is arranged at a position where the battery holder does not contact the plate.

A smart watch, which simultaneously provides the two functions of a physical watch and a mobile terminal, and a method for controlling the same are disclosed. The present invention provides a smart watch and a method for controlling the smart watch, the smart watch comprising; a case; at least one hand for displaying current time, the at least one hand being arranged to be adjacent to the inner periphery of the case; a movement for moving the hand along the inner periphery of the case, the movement being located inside the case; and a display unit configured to display various types of information, the display unit being located in the case, wherein the hand and a screen of the display unit are simultaneously shown to a user.

A smart watch, which simultaneously provides the two functions of a physical watch and a mobile terminal, and a method for controlling the same are disclosed. The present invention provides a smart watch and a method for controlling the smart watch, the smart watch comprising; a case; at least one hand for displaying current time, the at least one hand being arranged to be adjacent to the inner periphery of the case; a movement for moving the hand along the inner periphery of the case, the movement being located inside the case; and a display unit configured to display various types of information, the display unit being located in the case, wherein the hand and a screen of the display unit are simultaneously shown to a user.

A battery charger comprising a main housing peripheral wall interconnecting a first base surface and a second base surface, an engagement portion protruding from the first base surface and extending in an axial direction to define an end surface a battery charging terminal protruding axially from the end surface, and a pair of self-engaging latches which is under a resilient bias to protrude laterally outwards and away from an engagement portion peripheral wall; wherein the engagement portion has a lateral profile which is shaped and dimensioned for insertion into a correspondingly shaped and dimensioned battery charger receptacle along the axial direction, and the latches are shaped dimensioned and positioned to retract inwardly towards the battery charging terminal upon encountering the battery charger receptacle until reaching a latching portion on the battery charger receptacle whereat the latches are to enter into releasable latched engagement with the latching portion.

A device includes a flexible printed circuit board (PCB) that includes a first battery connection, a second battery connection, and a mechanical coupling apparatus. The first battery connection is for providing a first electrical connection to a first terminal of a battery. The second battery connection is for providing a second electrical connection to a second terminal of the battery. When the flexible PCB is in a first flex position, the first and second battery connections are at a distance where at least one of the first battery connection and the second battery connection is not electrically coupled to the respective one of the first and second terminals of the battery. When the flexible PCB is in a second flex position, the battery is electrically coupled to the first and second battery terminals and is mechanically held in place by the mechanical coupling apparatus.

A device includes a flexible printed circuit board (PCB) that includes a first battery connection, a second battery connection, and a mechanical coupling apparatus. The first battery connection is for providing a first electrical connection to a first terminal of a battery. The second battery connection is for providing a second electrical connection to a second terminal of the battery. When the flexible PCB is in a first flex position, the first and second battery connections are at a distance where at least one of the first battery connection and the second battery connection is not electrically coupled to the respective one of the first and second terminals of the battery. When the flexible PCB is in a second flex position, the battery is electrically coupled to the first and second battery terminals and is mechanically held in place by the mechanical coupling apparatus.

Provided is a method of manufacturing an electrostatic induction transducer, the method including: providing a conductive substrate; providing a first electret material film on a first surface of the conductive substrate; providing a second electret material film on a second surface of the conductive substrate; forming a through hole that penetrates the conductive substrate, the first electret material film, and the second electret material film; mounting a supported member being conductive to the conductive substrate while allowing the conductive substrate to move in an in-plane direction; and applying charges to the first electret material film and the second electret material film by a charging process.

Provided is a method of manufacturing an electrostatic induction transducer, the method including: providing a conductive substrate; providing a first electret material film on a first surface of the conductive substrate; providing a second electret material film on a second surface of the conductive substrate; forming a through hole that penetrates the conductive substrate, the first electret material film, and the second electret material film; mounting a supported member being conductive to the conductive substrate while allowing the conductive substrate to move in an in-plane direction; and applying charges to the first electret material film and the second electret material film by a charging process.