A dust-proof assembly includes a dust-proof net and a sealing net. The sealing net includes a support portion and a flexible sealing body, and the support portion is provided with a plurality of through holes. The dust-proof net and the support portion are arranged opposite each other, and the dust-proof net is connected to the support portion. The flexible sealing body is connected to the support portion and at least partially protrudes out of the dust-proof net.

A dust-proof assembly includes a dust-proof net and a sealing net. The sealing net includes a support portion and a flexible sealing body, and the support portion is provided with a plurality of through holes. The dust-proof net and the support portion are arranged opposite each other, and the dust-proof net is connected to the support portion. The flexible sealing body is connected to the support portion and at least partially protrudes out of the dust-proof net.

A sub-assembly of external parts including, a bolt interposed between a first component and a second component compressing together a joint, securing them together by axially blocking the first component, and which cooperates with the second component to enclose a ball occupying a well of depth greater than its diameter, that an orientation housing in the second component or the bolt includes, framed by channels of depth less than its diameter, limited by stops, which ball can occupy, when subjected to the gravity field and/or a magnetic field, both an orientation housing and a complementary housing of depth less than its diameter, that the bolt or respectively the second component includes, for their relative drive by the ball when it is simultaneously braced on a channel and a complementary housing.

A method for compensating the rate as a function of the temperature of a watch (1). A water-resistant case (2) contains a movement (3) with an oscillator (4), in an internal volume V occupied by n moles of a gas of constant R, where the pressure coefficient Cp and the humidity coefficient Ch of the movement (3) are determined, an optimal value Cto of the thermal coefficient Ct of the oscillator (4) is calculated defining the relatively linear variation of the rate thereof as a function of the temperature T, compensating the pressure and humidity deviations. The pressure P and/or the constant R and/or the quantity of gas and/or the temperature T are varied in the case. In the factory, the thermal coefficient of elastic return, and/or the quantity and/or the nature of the gas in the watch, and/or the internal volume of the case (2) are modified.

A mechanical clock movement includes a resonator, an escapement linked to the resonator, and a display of at least one item of time information. The display is driven by a mechanical drive device via a counter wheel train, the work rate of which is set by the escapement. At least the resonator is housed in a chamber, in which a reduced pressure in relation to atmospheric pressure prevails. The escapement is a magnetic escapement including an escape wheel coupled directly or indirectly to the resonator via a non-contact magnetic coupling system, wherein the magnetic coupling system is formed so that a non-magnetic wall of the chamber runs through the magnetic escapement so that a first part of the escapement is located inside the chamber whereas a second part of the escapement is located outside the chamber.

A watch including a watch case, wherein the watch case includes a device for measuring the degree of humidity inside the watch, wherein the device for measuring the degree of humidity is a fibre optic device including a measuring optical fibre, the measuring optical fibre includes a portion configured such that the refractive index of said portion changes in the presence of water vapour inside the watch case.

A watch including a watch case, wherein the watch case includes a device for measuring the degree of humidity inside the watch, wherein the device for measuring the degree of humidity is a fibre optic device including a measuring optical fibre, the measuring optical fibre includes a portion configured such that the refractive index of said portion changes in the presence of water vapour inside the watch case.

In the waterproof connector, a receptacle is provided with a first housing and first contacts, and a plug is provided with a second housing and second contacts. The first housing has a header at one end portion side and a quadrangular shaped waterproof ring mounted to allow close contact with an outer perimeter of the header. The second housing has in its interior a second contact housing chamber into which the header can be introduced, and has a shell which surrounds a periphery of the plurality of second contacts. The waterproof ring has a first pucker, formed with an undulating shape at an outer perimeter of the front portion, and which can closely contact at an inner wall of the shell, and a second pucker, formed with an undulating shape at an outer perimeter of the rear portion, and which can closely contact at an inner wall of a first frame.

A device for releasably sealing a port for a wearable electronic component includes a housing that seals an electronic component and includes a void for receiving the electronic component. The device may also include a cam disposed on a side surface of the housing having a proximal end pivotally engaged with the housing between a first position where a distal end of the cam is disposed adjacent to the housing and a second position where the distal end is disposed away from the housing. The cam may include a cam port that extends through a body of the cam. The device may further include a slider disposed on the side surface of the housing between the cam and the void, where the slider is slidably engaged with the housing between a sealed position and an open position.

A device for releasably sealing a port for a wearable electronic component includes a housing that seals an electronic component and includes a void for receiving the electronic component. The device may also include a cam disposed on a side surface of the housing having a proximal end pivotally engaged with the housing between a first position where a distal end of the cam is disposed adjacent to the housing and a second position where the distal end is disposed away from the housing. The cam may include a cam port that extends through a body of the cam. The device may further include a slider disposed on the side surface of the housing between the cam and the void, where the slider is slidably engaged with the housing between a sealed position and an open position.