The present disclosure relates to an apparatus, system, and method for a microelectromechanical (MEM) device formed on a transparent, insulating substrate. The MEM device may take the form of an electrostatic comb actuator. The fabrication process employs three-dimensional structuring of the substrate to form the actuator combs, biasing elements, and linkages. The combs and other elements of the actuator may be rendered electrically conducting by a conformal conductive coating. The conductive coating may be segmented into a plurality of electrodes without the use of standard lithography techniques. A linear-rotational actuator is provided, which may comprise two perpendicularly-arranged, linear actuators that utilize moveable linkage beams in two orthogonal dimensions. A linear or torsional ratcheting actuator is also provided by using comb actuators in conjunction with a ratcheting wheel or cog. Furthermore, several methods for electrically connecting non-contiguous or enclosed elements are provided.

A timepiece mechanism comprising a regulator, an energy distributing member a pallet fork controlled by the regulator to alternate in locking and releasing the energy distributing member, and a decoupling member elastically connected to the pallet fork and to the regulator. The decoupling member is arranged so as to oscillate between two stop elements.

A micro-electromechanical systems (MEMS) driving arrangement for an electronic device, the micro-electromechanical systems (MEMS) driving arrangement including a driven wheel; a driving actuation assembly for causing rotation of the driven wheel; an indicator assembly including an indicator; and a force absorbing assembly coupled intermediate the indicator assembly and the driven wheel; whereby a force acting upon the indicator assembly is absorbed by the force absorbing assembly so as to inhibit rotation of the driven wheel relative to the driving actuation assembly.

The invention relates to a one-piece metal component including an electroformed metal body, the external surface of the body including, only over or to a predetermined depth, less trapped hydrogen than the rest of the electroformed metal body causing a hardening relative to the rest of the body in order to improve the wear resistance of the one-piece component while preserving a relative magnetic permeability of less than 10 and the ability to be driven or pressed fit.

A micro machine may be in or less than the micrometer domain. The micro machine may include a micro actuator and a micro shaft coupled to the micro actuator. The micro shaft is operable to be driven by the micro actuator. A tool is coupled to the micro shaft and is operable to perform work in response to at least motion of the micro shaft.

The invention relates to a silicon-based component with at least one chamfer formed from a method combining at least one oblique side wall etching step with a Bosch etching of vertical side walls, thereby enabling aesthetic improvement and improvement in the mechanical strength of components formed by micromachining a silicon-based wafer.

A method for fabrication of a micromechanical part made of a one-piece synthetic carbon allotrope based material, the method including: forming a substrate with a negative cavity of the micromechanical part to be fabricated; coating the negative cavity of the substrate with a layer of the synthetic carbon allotrope based material in a smaller thickness than the depth of the negative cavity; and removing the substrate to release the one-piece micromechanical part formed in the negative cavity.

The present invention relates to a method for producing a timepiece comprising at least one first part produced by a microfabrication or microforming method in at least one first material, said method comprising at least: a step of depositing, on said first part, without moulding, at least one second part of said timepiece in at least one second material, and a step of treating the second material in order to connect together the components on the first part.

A micromechanical structure has a first micromechanical element, a second micromechanical element and a torsion spring arrangement having a first torsion spring element, having a first center line, mechanically connected to the first micromechanical element at a first contact region and to the second micromechanical element at a second contact region, and having a second torsion spring element, having a second center line, mechanically connected to the first micromechanical member at a third contact region and to the second micromechanical member at a fourth contact region in order to connect the first micromechanical member and the second micromechanical member to be movable relative to each other. A distance between the first and second center lines, starting from the first and third contact regions toward the second and fourth contact regions, decreases in a first portion and increases in a second portion. In a rest position of the micromechanical structure, the first and second torsion spring elements are arranged without contact to each other.

A method for fabrication of a micromechanical part made of a one-piece synthetic carbon allotrope based material, the method including: forming a substrate with a negative cavity of the micromechanical part to be fabricated; coating the negative cavity of the substrate with a layer of the synthetic carbon allotrope based material in a smaller thickness than the depth of the negative cavity; and removing the substrate to release the one-piece micromechanical part formed in the negative cavity.