A switch mechanism has a compliant buckling bar that includes a single fixed end mounted to a mounting surface and a free end that is displaced with respect to the fixed end. The mounting of the fixed end to the mounting surface may constitute the only fixed connection between the bar and the mounting surface. The bar moves between two stable positions in response to a transition force applied transversely to the free end. Residual stress in the bar may be higher when the free end is at each of the stable positions than when the free end is at a neutral position located between the stable positions.

A switch mechanism has a compliant buckling bar that includes a single fixed end mounted to a mounting surface and a free end that is displaced with respect to the fixed end. The mounting of the fixed end to the mounting surface may constitute the only fixed connection between the bar and the mounting surface. The bar moves between two stable positions in response to a transition force applied transversely to the free end. Residual stress in the bar may be higher when the free end is at each of the stable positions than when the free end is at a neutral position located between the stable positions.

An input device includes a housing; an invertible spring provided inside the housing; a load sensor arranged alongside the invertible spring inside the housing; a stem extending across a top portion of the invertible spring and the load sensor, and configured to push both the top portion of the invertible spring and the load sensor in response to an operating load applied to the stem; and a first fixed contact provided inside the housing, wherein the stem is a conductive member, and in response to the operating load applied to the stem, the stem pushes both the top portion of the invertible spring and the load sensor, and also comes into contact with the first fixed contact so that the first fixed contact is energized via the stem.

An input device includes a housing; an invertible spring provided inside the housing; a load sensor arranged alongside the invertible spring inside the housing; a stem extending across a top portion of the invertible spring and the load sensor, and configured to push both the top portion of the invertible spring and the load sensor in response to an operating load applied to the stem; and a first fixed contact provided inside the housing, wherein the stem is a conductive member, and in response to the operating load applied to the stem, the stem pushes both the top portion of the invertible spring and the load sensor, and also comes into contact with the first fixed contact so that the first fixed contact is energized via the stem.

A surface mount snap switch and method of making the same, including a housing having a plurality of channels formed therein and a cover configured for snap-fit engagement with the housing. The snap switch also includes an actuator slidably disposed at least partially within the housing, a first terminal having an external surface mount portion and another portion press-fittingly held within one of the plurality of channels of the housing, and a second terminal having an external surface mount portion and another portion press-fittingly held within another one of the plurality of channels of the housing. The snap switch further includes a blade contact having a first end portion pivotally associated with the first terminal and a second end portion comprising a blade contact button, and the actuator is configured to interact with the blade contact to electrically couple the first terminal and the second terminal.

A control module (10) for an electronic device including a push-button (11) including a striker element (111), a switch (12) adapted to occupy a connected state and a rest state, said striker element (111) being configured to drive the switch (12) into one or the other of the connected and rest states, the control module further comprising a stop member (13) against which the striker element (111) comes to bear when it drives the switch (12) into the connected state or into the rest state.

An input device includes a housing; an invertible spring provided inside the housing; a load sensor arranged alongside the invertible spring inside the housing; a stem extending across a top portion of the invertible spring and the load sensor, and configured to push both the top portion of the invertible spring and the load sensor in response to an operating load applied to the stem; and a first fixed contact provided inside the housing, wherein the stem is a conductive member, and in response to the operating load applied to the stem, the stem pushes both the top portion of the invertible spring and the load sensor, and also comes into contact with the first fixed contact so that the first fixed contact is energized via the stem.

An input device includes a housing; an invertible spring provided inside the housing; a load sensor arranged alongside the invertible spring inside the housing; a stem extending across a top portion of the invertible spring and the load sensor, and configured to push both the top portion of the invertible spring and the load sensor in response to an operating load applied to the stem; and a first fixed contact provided inside the housing, wherein the stem is a conductive member, and in response to the operating load applied to the stem, the stem pushes both the top portion of the invertible spring and the load sensor, and also comes into contact with the first fixed contact so that the first fixed contact is energized via the stem.

A surface mount snap switch and method of making the same, including a housing having a plurality of channels formed therein and a cover configured for snap-fit engagement with the housing. The snap switch also includes an actuator slidably disposed at least partially within the housing, a first terminal having an external surface mount portion and another portion press-fittingly held within one of the plurality of channels of the housing, and a second terminal having an external surface mount portion and another portion press-fittingly held within another one of the plurality of channels of the housing. The snap switch further includes a blade contact having a first end portion pivotally associated with the first terminal and a second end portion comprising a blade contact button, and the actuator is configured to interact with the blade contact to electrically couple the first terminal and the second terminal.

A push-button switch capable of adjusting output power includes a housing. The housing includes a contact assembly and a power adjustment assembly therein. The contact assembly includes an upper terminal, a lower terminal and a connecting elastic plate below the upper terminal. A support seat is provided in the housing. An upper end of the support seat is provided with a first bracket. The first bracket is inserted through the connecting elastic plate. The first bracket is provided with a first slot. One end of the connecting elastic plate is fixedly connected to the upper terminal. Another end of the connecting elastic plate is engaged with the first slot. A drive mechanism is provided above the connecting elastic plate for driving the connecting elastic plate downward. The push-button switch has an ergonomic design.