Disclosed is a method for manufacturing a horological component according to which a silicon-based piece having the desired shape of the horological component is produced and the piece is subjected to a thermal oxidation and deoxidation treatment to remove a predetermined thickness of silicon in order to increase the mechanical strength of the piece. This method is characterized in that the thermal oxidation and deoxidation treatment is carried out in several steps, each step including a thermal oxidation phase followed by a deoxidation phase.

Disclosed is a method of making a timepiece spring from monocrystalline material including the following steps: drawing the spring; identifying one or more zones of weakness of the spring in which or in at least one of which the spring will break in the event of excessive deformation; manufacturing the spring from a wafer of monocrystalline material extending in a determined plane, while orienting the spring in the wafer such that the direction of the macroscopic stresses in the or each zone of weakness when the spring is deformed is substantially parallel to a plane of cleavage of the material intersecting the determined plane. Also disclosed is a timepiece spring obtained by such a method.

An assembly (300) includes (i) a hairspring (2) made of a paramagnetic alloy including at least one of the following elements: Nb, V, Ta, Ti, Zr and Hf, notably an alloy including the elements Nb and Zr with between 5% and 25% by mass of Zr and an interstitial doping agent including oxygen, and (ii) at least one fastening part (1; 1′), notably two parts (1; 1′), in particular a stud (1) or a collet (1′), for an end (2a; 2b) of the hairspring (2), the at least one part (1; 1′) having a first portion (10; 10′) that is designed to come into contact with the hairspring (2) and that is made of titanium or titanium alloy or of tantalum or tantalum alloy, notably grade 2 titanium or grade 5 titanium.

A fastening stud (1) for one end of a hairspring, the stud having a first portion (10) designed to come into contact with the hairspring, the first portion being formed such as to have a first surface (10b) and a second bearing surface (10c) with the hairspring.

An elastic retaining member is for attaching a horological component to a support element. The retaining includes an opening into which the support element is capable of being inserted. The retaining member also includes rigid arms and elastic arms defined between the connection zones of the retaining member. The arms contribute to procuring elastic gripping of the support element in the opening, each rigid arm being provided with a single convex contact zone of the retaining member capable of engaging with a corresponding convex contact portion of the support element.

A one-piece balance spring including a single strip wound on itself between an inner coil and an outer coil, the strip having a geometry such that when the angle of contraction of the balance spring has a value of 360 degrees, there is a substantially constant distance between each coil from the inner coil to the penultimate coil.

A holding member for fixing a timepiece component on support elements of different cross section includes an opening into which each support element can be inserted, the holding member having structural elements together forming a body configured to ensure mounting of each support element in the opening. Each of the structural elements includes a first structural sub-element and a second structural sub-element, the first structural sub-element including a volume of material greater than a volume of material constituting the second structural sub-element. The holding member includes a connecting portion ensuring the mounting of each of the support elements in the holding member, the portion being defined on an inner face of the first structural sub-element.

A balance with hairspring of the present disclosure includes a balance shaft rotatably supported by a support member, a collet fixed to the balance shaft, and a metal hairspring fixed to the collet, and the hairspring includes an inner end portion fixed to the collet, a first winding portion continuously formed from the inner end portion and formed along a Grossmann curve, and a second winding portion continuously formed from the first winding portion and formed along an Archimedes' spiral, and the collet includes a fixing portion to which the inner end portion of the hairspring is fixed, and an outer peripheral shape portion arranged at a position facing an inner surface of the first winding portion and configured to form the first winding portion into a shape of the Grossmann curve.

An elastic securing organ for fastening a horological component on a support element including an outer peripheral wall capable of being connected to said horological component and an inner peripheral wall defining a triangular-shaped opening wherein the support element is capable of being inserted, the elastic securing organ includes elastic arms each forming one side of the triangular opening and helping ensure the gripping of the support element in the opening, each arm including: at least one cut-out defined completely or partially along the body of said arm, an elastic contact zone with the support element, and elastic peripheral zones which extend between this contact zone and the ends of this elastic arm, the contact zone having a greater quantity of material than the quantity of material forming each of the peripheral zones thereof.

A method produces an assembly of an elastic holding member-timepiece component assembly with a support element. The elastic holding member is made of an electrically insulating material and the support element is made of an electrically conductive material. The method includes mounting the assembly with the support element aiming to define at least one zone for receiving at least one element for blocking a movement of the holding member relative to the support element, and producing by galvanic metal growth the at least one blocking element on at least one of the reception zones.