Provided is a switch with excellent operability. A switch is provided with a plunger, a lower torsion spring in which a biasing direction changes according to the movement of the plunger. The lower torsion spring biases the plunger in a returning direction when the plunger is in a reference position, and biases the plunger in a direction different from the returning direction when the plunger is in an operation position.

A control knob for controlling operation of a machine, the control knob including: an attachment member configured for attaching the control knob to a surface of the machine so that the control knob is operably connectable with the machine to control operation thereof; a display member comprising an electronic display module disposed thereon; an operational mode display controller for controlling display of operational modes of the machine upon the electronic display module, said operational mode display controller being configured for rotational movement around the electronic display module amongst a plurality of rotational positions, said operational mode display controller being operably connected with the electronic display module such that, responsive to the rotational movement of the operational mode display controller amongst the plurality of rotational positions, the electronic display module is configured to display a plurality of operational modes of the machine corresponding to the plurality of rotational positions; and an operational mode selector for controlling selection of one of the plurality of operational modes of the machine when said one of the plurality of operational modes is displayed on the electronic display module, the operational mode selector being configured for movement between at least a first position and a second position to actuate selection of the operational mode displayed on the electronic display module.

A switch component includes a spring plate and a cover of rubber. The cover of rubber covers at least one part of an upper surface of the spring plate. The cover of rubber includes at least one pair of supporting portions that support the spring plate.

A keyswitch uses a magnetic attraction force produced between and by a fixed part, fixedly disposed relative to a base, and a movable part, movably disposed relative to the base, as a driving force for returning a keycap to its original position. The movable part is between the fixed part and the base. The keyswitch also uses a force transmission part disposed between the keycap and the movable part as an intermediate for transferring force from the keycap to the movable part. When a force for pressing the keycap downward overcomes the magnetic attraction force, the movable part moves toward the base and then triggers a switch.

Provided is a switch that can be downsized. A switch is provided with a plunger, and an upper torsion spring configured to bias the plunger in a returning direction. The torsion spring has a first arm that extends to the plunger and abuts against the plunger. The plunger has a hole at a position into which the first arm is inserted. The hole is a through hole extending in a direction that is perpendicular to a direction in which the plunger moves, and is the same as a direction in which the first arm extends when viewed in the direction in which the plunger moves.

A button locking device includes a panel, a button installed on the panel, a bottom plate installed under the button, a first cylinder spring installed between the button and the bottom plate for resetting the button, an actuator assembly installed between the panel and the bottom plate, a toggle member installed under the button and pushed by the actuator assembly to rotate from a first position to a second position and rotated from the second position to the first position. At the first position, the toggle member stops the button from moving downward. At the second position, the toggle member allows the button to move downward. The present invention has the features of simple structure, convenient operation, low power consumption, high safety, and broad scope of applicability.

A keyswitch uses a magnetic attraction force produced between and by a fixed part, fixedly disposed relative to a base, and a movable part, movably disposed relative to the base, as a driving force for returning a keycap to its original position. The movable part is between the fixed part and the base. The keyswitch also uses a force transmission part disposed between the keycap and the movable part as an intermediate for transferring force from the keycap to the movable part. When a force for pressing the keycap downward overcomes the magnetic attraction force, the movable part moves toward the base and then triggers a switch.

A keyboard switch, including a base; a static contact; a moving contact; an upper cover; a button; a reset spring; an X-shaped rack structure; and a holding part. The X-shaped rack structure includes a first connecting rack and a second connecting rack. The first connecting rack includes a first balancing lever and two first connecting parts sleeving on the first balancing lever, the second connecting rack includes a second balancing lever and two second connecting parts sleeving on the second balancing lever; opposite surfaces of the two first connecting parts each are provided with one boss, facing surfaces of the two second connecting parts each are provided with one round hole, and the boss is inserted in the round hole so that two ends of the two first connecting racks and two ends of the two second connecting racks are connected to form two X-shaped structures.

The switch includes the base, a plurality of the fixed contact terminals, the sliding body, the operation lever, the coil spring, and the cover. From above the base, the fixed contact terminals, the sliding body, the operation lever, and the coil spring are mounted to the base, and the sliding body is pressed against the operation lever to position the operation lever. The cover is mounted to the base from above so as to press the operation lever by the pressing portion of the cover and cause the operation lever to rotate to an initial position.

A method of manufacturing a waterproof board switch according to the first embodiment comprises the following steps: (A) arranging a plurality of print circuit boards on a board plate, each of the print circuit board having a top pattern on a front surface and a bottom pattern on a rear surface; (B) insulating the rear surface of the print circuit board; (C) forming a board ass'y by thermo-compression bonding an insulation adhesive film having a dome hole to the front surface of the print circuit board; (D) forming a plurality of board holes near both edges of the dome hole on the board ass'y; (E) resting a metal dome on the dome hole such that the metal dome is able to be in contact with the top pattern; (F) arranging a top coverlay having bigger width than the insulation adhesive film on the board ass'y such that the top coverlay covers the dome hole; (G) arranging a thermoplastic resin above the top coverlay, arranging a top jig above the thermoplastic resin, arranging a bottom jig below the board ass'y and then applying thermo-compression to the thermoplastic resin by means of the top jig and the bottom jig; (H) making the thermoplastic resin having flowability flow from the top coverlay to the board hole by the step (G) such that ends of the top coverlay are bended so as to be in contact with sides of the board ass'y and then are inserted into the board hole, and then thermo-compression bonding the top coverlay to the top of the board ass'y and the sides of the board ass'y by means of the thermoplastic resin; and (I) separating the board ass'y to which the top coverlay was bonded from the board plate after the step (H).