A wet electrolytic surface mount capacitor has a body defining an interior area and having a fill port formed through a wall of the body. A capacitive element is positioned in an interior of the body and is isolated from the body. A surface mount anode termination is in electrical communication with the capacitive element and isolated from the body. A surface mount cathode termination is in electrical communication with the body. An electrolyte is contained in the interior area of the body, and is introduced into the interior area of the body through the fill port. A fill port plug is positioned adjacent the fill port. A fill port cover compresses the fill port plug against the fill port to seal the fill port, and may be welded in place. A method of forming the capacitor is also provided.

A wet electrolytic surface mount capacitor has a body defining an interior area and having a fill port formed through a wall of the body. A capacitive element is positioned in an interior of the body and is isolated from the body. A surface mount anode termination is in electrical communication with the capacitive element and isolated from the body. A surface mount cathode termination is in electrical communication with the body. An electrolyte is contained in the interior area of the body, and is introduced into the interior area of the body through the fill port. A fill port plug is positioned adjacent the fill port. A fill port cover compresses the fill port plug against the fill port to seal the fill port, and may be welded in place. A method of forming the capacitor is also provided.

A circuit board system according to the invention comprises a circuit board (101), at least one element (102) mechanically supported with respect to the circuit board, and a spring-fastener (106) arranged to mechanically support the at least one element with respect to the circuit board. The spring-fastener comprises a pressing portion (107) pressing the at least one element and a latching portion (108) extending from an end of the pressing portion and being shape-locked in one or more apertures (109-110) of the circuit board. The latching portion and the one or more apertures of the circuit board are shaped to provide shape-locking whose opening requires at least a first movement of the latching portion in a first direction against the spring-force of the spring fastener and, subsequently, a second movement of the latching portion in a second direction against the spring-force of the spring fastener.

A circuit board system according to the invention comprises a circuit board (101), at least one element (102) mechanically supported with respect to the circuit board, and a spring-fastener (106) arranged to mechanically support the at least one element with respect to the circuit board. The spring-fastener comprises a pressing portion (107) pressing the at least one element and a latching portion (108) extending from an end of the pressing portion and being shape-locked in one or more apertures (109-110) of the circuit board. The latching portion and the one or more apertures of the circuit board are shaped to provide shape-locking whose opening requires at least a first movement of the latching portion in a first direction against the spring-force of the spring fastener and, subsequently, a second movement of the latching portion in a second direction against the spring-force of the spring fastener.

A handheld device includes an electronic instrument and a capacitive power supply for storing and delivering power to the electronic instrument. The capacitive power supply includes at least one capacitor, and an electronic circuit operable to boost a voltage from the capacitor to a higher voltage for use by the electronic instrument. The capacitive power supply can be rapidly recharged. Some configurations include an accelerometer which permits the handheld device to detect movement and perform various operations responsive to detected movement. A dual charging station is also disclosed.

A wet electrolytic surface mount capacitor has a body defining an interior area and having a fill port formed through a wall of the body. A capacitive element is positioned in an interior of the body and is isolated from the body. A surface mount anode termination is in electrical communication with the capacitive element and isolated from the body. A surface mount cathode termination is in electrical communication with the body. An electrolyte is contained in the interior area of the body, and is introduced into the interior area of the body through the fill port. A fill port plug is positioned adjacent the fill port. A fill port cover compresses the fill port plug against the fill port to seal the fill port, and may be welded in place. A method of forming the capacitor is also provided.

A wet electrolytic surface mount capacitor has a body defining an interior area and having a fill port formed through a wall of the body. A capacitive element is positioned in an interior of the body and is isolated from the body. A surface mount anode termination is in electrical communication with the capacitive element and isolated from the body. A surface mount cathode termination is in electrical communication with the body. An electrolyte is contained in the interior area of the body, and is introduced into the interior area of the body through the fill port. A fill port plug is positioned adjacent the fill port. A fill port cover compresses the fill port plug against the fill port to seal the fill port, and may be welded in place. A method of forming the capacitor is also provided.

The present invention relates generally to substrates for making polymers and methods for making polymers. The present invention also relates generally to polymers and devices comprising the same.