A spark plug includes: an insulator with an axial hole; a center electrode held in a front end side of the axial hole; a cylindrical metal shell disposed around the insulator and having a seal part brought into contact with an outer circumferential surface of the insulator; a ground electrode arranged to form a gap with the center electrode; and a cap connected to a front end part of the metal shell to define therein an auxiliary combustion space in which the gap is formed, the cap having at least one through hole formed to provide communication between the auxiliary combustion space and the outside, wherein the condition (B/A)0.25 is satisfied where A represents a volume of an imaginary space defined at a position frontward of the seal part; and B represents a volume of parts of the ground and center electrodes located in the imaginary space.

A pre-chamber spark plug. The pre-chamber spark plug includes a housing, a pre-chamber, a cap that closes the pre-chamber on the housing and that has one or more through-openings, and an ignition device situated in the pre-chamber. The cap has a cap base and a cap jacket. The cap jacket and a housing inner wall of the housing defines a pre-chamber inner wall. The pre-chamber is defined by the pre-chamber inner wall and the cap base. At least one rib projects into the pre-chamber is formed in the region of the pre-chamber inner wall.

A pre-chamber spark plug. The pre-chamber spark plug includes a housing, a pre-chamber, a cap that closes the pre-chamber on the housing and that has one or more through-openings, and an ignition device situated in the pre-chamber. The cap has a cap base and a cap jacket. The cap jacket and a housing inner wall of the housing defines a pre-chamber inner wall. The pre-chamber is defined by the pre-chamber inner wall and the cap base. At least one rib projects into the pre-chamber is formed in the region of the pre-chamber inner wall.

An illuminated engine cover assembly including an engine attachment system and an illuminated engine cover is disclosed. The illuminated engine cover assembly comprises an attachment element attached to the engine and an illuminated engine cover composed of polymerized foam. The illuminated engine cover has a recessed area and a receptacle for releasable attachment to the engine attachment element. An illuminated feature is attached to the cover's recessed area. A contact element is fitted within the receptacle. A flexible printed circuit for providing contact between the illuminated feature and the contact element of the receptacle is embedded within the engine cover. A support lattice is optionally embedded within the cover. The support lattice has ends and an intermediate portion to which the illuminated feature is attached. Grommets are attached to each end of the support lattice. The releasable attachment receptacles are formed in the grommets.

A conductive ball stud fastener arrangement for providing energy to a removable electrified component having an electrified element when the component is attached to an electrified substrate is disclosed. The ball stud fastener includes an insulating body, an electrified conductor having a conductive tip that is continuous with a conductive, centrally formed conductive stem, and a conductive attachment portion for attachment to the electrified substrate. The electrified component includes grommets having conductive elements. The ball stud fasteners are easily removed from and attached to the grommets. The conductive elements of the grommets are part of a circuit to which the electrified element of the electrified component is attached. According to one embodiment, the conductive ball stud fastener arrangement and its associated circuit includes a photoelectric sensor that opens and closes the circuit. In another embodiment, the ball studs themselves act as switches to open and close the circuit.

A conductive ball stud fastener arrangement for providing energy to a removable electrified component having an electrified element when the component is attached to an electrified substrate is disclosed. The ball stud fastener includes an insulating body, an electrified conductor having a conductive tip that is continuous with a conductive, centrally formed conductive stem, and a conductive attachment portion for attachment to the electrified substrate. The electrified component includes grommets having conductive elements. The ball stud fasteners are easily removed from and attached to the grommets. The conductive elements of the grommets are part of a circuit to which the electrified element of the electrified component is attached. According to one embodiment, the conductive ball stud fastener arrangement and its associated circuit includes a photoelectric sensor that opens and closes the circuit. In another embodiment, the ball studs themselves act as switches to open and close the circuit.

A conductive ball stud fastener arrangement for providing energy to a removable electrified component having an electrified element when the component is attached to an electrified substrate is disclosed. The ball stud fastener includes an insulating body, an electrified conductor having a conductive tip that is continuous with a conductive, centrally formed conductive stem, and a conductive attachment portion for attachment to the electrified substrate. The electrified component includes grommets having conductive elements. The ball stud fasteners are easily removed from and attached to the grommets. The conductive elements of the grommets are part of a circuit to which the electrified element of the electrified component is attached. According to one embodiment, the conductive ball stud fastener arrangement and its associated circuit includes a photoelectric sensor that opens and closes the circuit. In another embodiment, the ball studs themselves act as switches to open and close the circuit.

A conductive ball stud fastener arrangement for providing energy to a removable electrified component having an electrified element when the component is attached to an electrified substrate is disclosed. The ball stud fastener includes an insulating body, an electrified conductor having a conductive tip that is continuous with a conductive, centrally formed conductive stem, and a conductive attachment portion for attachment to the electrified substrate. The electrified component includes grommets having conductive elements. The ball stud fasteners are easily removed from and attached to the grommets. The conductive elements of the grommets are part of a circuit to which the electrified element of the electrified component is attached. According to one embodiment, the conductive ball stud fastener arrangement and its associated circuit includes a photoelectric sensor that opens and closes the circuit. In another embodiment, the ball studs themselves act as switches to open and close the circuit.

A spark ignition device includes a ceramic insulator with a metal shell surrounding at least a portion of the ceramic insulator. A ground electrode is attached to the shell. The ground electrode has a ground electrode sparking tip spaced from a central sparking tip by a spark gap. A first terminal is arranged in electrical communication with the central sparking tip and is configured for electrical connection with a power source. The device further includes a second terminal configured for electrical connection with the power source. The second terminal is spaced from the first terminal, with the second terminal being arranged in electrical communication with the first terminal. A heater element brings the first terminal in electrical communication with the second terminal and completes an electrical circuit. The heater element has a resistance greater than the first and second terminals thereby producing a significant source of heat.

A spark ignition device includes a ceramic insulator with a metal shell surrounding at least a portion of the ceramic insulator. A ground electrode is attached to the shell. The ground electrode has a ground electrode sparking tip spaced from a central sparking tip by a spark gap. A first terminal is arranged in electrical communication with the central sparking tip and is configured for electrical connection with a power source. The device further includes a second terminal configured for electrical connection with the power source. The second terminal is spaced from the first terminal, with the second terminal being arranged in electrical communication with the first terminal. A heater element brings the first terminal in electrical communication with the second terminal and completes an electrical circuit. The heater element has a resistance greater than the first and second terminals thereby producing a significant source of heat.