A button structure and a terminal using the same are provided. The button structure includes a connecting element, a press element, and at least one elastic element connected to the connecting element and the press element. The elastic element is configured to provide a restoring force after the press element is pressed toward the connecting element. The connecting element is provided with an instruction transmission port and at least one of a current transmission port and a data transmission port. The press element is provided with an instruction triggering port and at least one of a current transmission pin and a data transmission pin. The current transmission pin is electrically connected to the current transmission port to output or input current. The data transmission pin is electrically connected to the data transmission port to output or input data.

An adapter assembly configured to be coupled to a surgical loading unit includes a switch, an elongated member, and an annular member. The switch is configured to be toggled in response to the surgical loading unit being coupled to the adapter assembly. The elongated member is in communication with the switch and is resiliently biased in a distal direction toward a locking position in which the switch is toggled. The annular member is disposed adjacent the elongated member and is rotatable between a first orientation, in which the annular member prevents distal movement of the elongated member, and a second orientation, in which the elongated member moves distally to toggle the switch.

The present disclosure relates to a circuit breaker comprising: a circuit breaking part in which contact points of a fixed contact and a movable contact are in contact with each other; and an energy accumulation part for accumulating energy of a closing spring for controlling contact between the fixed contact and the movable contact, wherein the energy accumulation part comprises: an electromotive energy accumulation part; and a manual energy accumulation part separated from the electromotive energy accumulation part by a manual energy accumulation spring, and engaged with the electromotive energy accumulation part by unit of external pressure so as to transmit an inputted rotational force to the electromotive energy accumulation part, thereby accumulating the energy of the closing spring.

The present utility model discloses an adjustable contactor including: a static contact fixed in the contactor; a movable contact which is connected in the movable contact bracket through a contact spring, and which makes contact with the static contact in accordance with the movement of the movable contact bracket in the contactor; the contactor further includes adjusting knobs provided in the movable contact bracket at one end in connection with the contact spring while corresponding to the contact springs connected with individual movable contacts, the adjusting knob being set so that adjustment of the compression or release of the contact spring is achieved by rotating the adjusting knob so as to adjust the contact pressure of the movable contact.

An acoustic user interface apparatus and method can detect physical touch contacting a sensing surface and improve the accuracy of direction recognition of a touch or rubbing without any complicated algorithm. The user interface apparatus and method use one microphone to detect and analyze sound waves which are generated by collisions between bumps formed in a top plate or bottom plate of the interface apparatus and the opposing bottom plate or top plate when a user is touching or rubbing the sensing surface.

What is presented is a key module for a keyboard. The key module comprises a key tappet. The key module also comprises a module housing. The module housing is formed to movably accommodate the key tappet, in order to enable a translational actuation movement of the key tappet between a rest position and in an actuated position relative to the module housing. The key module further comprises a trigger element for triggering an actuation signal of the key module in response to the actuation movement. The trigger element is attached to the key tappet. The trigger element is a contactor for electrically shorting contact pads of a circuit substrate of the keyboard. The trigger element comprises more than two elastically deformable contact fingers for contacting the contact pads after different pre-travel paths in the course of the actuation movement.

A rotational push switch includes a bottom shell having a first and a second conductive terminals connected to a power supply, and a third conductive terminal connected to the conductive elastic piece. The conductive elastic piece is mounted in the bottom shell. A switch assembly is mounted on a top shell mounted on the bottom shell. The switch assembly is switched to connect or detach the conductive elastic piece and the second conductive terminal. A cap is mounted on the switch assembly. When the conductive elastic piece is connected to or departed from the second conductive terminal, ON/OFF symbols can be correspondingly seen in a display window of the cap, and a user can recognize an ON/OFF state of the rotational push switch.

What is presented is a key module (110) for a keyboard. The key module (110) comprises a key tappet (220). The key module (110) also comprises a module housing (230). The module housing (230) is formed to movably accommodate the key tappet (220), in order to enable a translational actuation movement of the key tappet (220) between a rest position and in an actuated position relative to the module housing (230). The key module (110) further comprises a trigger element (240) for triggering an actuation signal of the key module (110) in response to the actuation movement. The trigger element (240) is attached to the key tappet (220). The trigger element (240) is a contactor for electrically shorting contact pads of a circuit substrate of the keyboard. The trigger element (240) comprises more than to elastically deformable contact fingers for contacting the contact pads after different pre-travel paths in the course of the actuation movement.

The key switch includes, a base, a button attached to the base so as to be capable of coming into contact with the base and separating from the base, and a coil spring disposed between the base and the button for urging the button in a direction separating from the base. The coil spring has at least an end turn portion formed at one end, a densely wound portion that is continuous with the end turn portion and compressed in an initial state in which the button is attached to the base so that adjacent windings come into contact with each other, and a coarsely wound portion which is continuous with the densely wound portion and in which a winding pitch is larger than that of the densely wound portion, and in the initial state, adjacent windings are separated from each other.

A force-controlled-switch comprises a diaphragm spring element and an absorber-plate. The absorber-plate is configured to absorb kinetic energy of the force-controlled-switch. In particular, the absorber-plate absorbs a part of the diaphragm-spring-element's kinetic energy.