An enclosure, such as an electrical enclosure, includes a base having a series of walls that define an interior, and a cover. The base and cover include a hinge arrangement that enables the cover to be secured to the base for movement between a closed position and an open position. The hinge arrangement enables the cover to be hinged to either a first wall of the base or an opposite, second wall of the base. A latch member is configured to be selectively engaged with either the first wall of the base or the second wall of the base, and is engaged with the second wall of the base when the cover is hinged to the first wall of the base and is engaged with the first wall of the base when the cover is hinged to the second wall of the base.

An enclosure, such as an electrical enclosure, includes a base having a series of walls that define an interior, and a cover. The base and cover include a hinge arrangement that enables the cover to be secured to the base for movement between a closed position and an open position. The hinge arrangement enables the cover to be hinged to either a first wall of the base or an opposite, second wall of the base. A latch member is configured to be selectively engaged with either the first wall of the base or the second wall of the base, and is engaged with the second wall of the base when the cover is hinged to the first wall of the base and is engaged with the first wall of the base when the cover is hinged to the second wall of the base.

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.

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.

A wristwatch is described, including a middle having a side wall, defining a median plane and further having attachment members for securing respective first and second ends of a strap to the middle, and a cover capable of pivoting, relative to the middle, between a first closed position in which the ends of the strap are locked onto the middle, and a second open position in which the ends of the strap are free to be separated from the middle. The cover is arranged so as pivot about a rotational axis parallel to the median plane, each attachment member including a hole provided in the side wall and intended for receiving the corresponding end of the strap by insertion in a direction substantially parallel to the median plane.

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.

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.

Provided is a timepiece case that does not require a seal ring, such as an O ring, that is made of a resin material. The timepiece case includes a case body configured from metallic glass; and a button part that is formed integrally with the case body and is flexible.

Provided is a timepiece case that does not require a seal ring, such as an O ring, that is made of a resin material. The timepiece case includes a case body configured from metallic glass; and a button part that is formed integrally with the case body and is flexible.

An enclosure, such as an electrical enclosure, includes a base having a series of walls that define an interior, and a cover. The base and cover include a hinge arrangement that enables the cover to be secured to the base for movement between a closed position and an open position. The hinge arrangement enables the cover to be hinged to either a first wall of the base or an opposite, second wall of the base. A latch member is configured to be selectively engaged with either the first wall of the base or the second wall of the base, and is engaged with the second wall of the base when the cover is hinged to the first wall of the base and is engaged with the first wall of the base when the cover is hinged to the second wall of the base.