An ignition device for an extraneously igniting combustion piston engine with an ignition chamber located between a cylinder head and a piston, wherein the cylinder head has an end surface which defines the ignition chamber and which is at least partially formed as a cylinder head electrode, and wherein an ignition chamber electrode is disposed within the ignition chamber and forms an ignition gap with the cylinder head electrode.

An engine automatic stop/restart device includes an ignition-prohibition-decision unit that prohibits an ignition for an engine, which is controlled by the ignition-control unit, when a reverse rotation of the engine is detected based on a crank-angle signal; and an ignition-prohibition-release-decision unit that releases an ignition prohibition, after the ignition is prohibited by the ignition-prohibition-decision unit; in which the ignition-prohibition-release-decision unit releases the ignition prohibition when regular rotational signals of the engine, of which count is greater than or equal to a predetermined count, is detected and an engine revolution number is greater than or equal to a predetermined revolution number, after the reverse rotation of the engine is detected, and before a crank is positioned at a compression top dead center of the engine.

Pump systems having electrically conductive membranes are described. In embodiments of the invention, the electrically conductive membranes can be utilized as speakers to produce ultrasonic and audible sounds. The electrically conductive membranes are made from materials such as graphene, graphene oxide, and polymer films having a thin conductive coating.

Pump systems having electrically conductive membranes are described. In embodiments of the invention, the electrically conductive membranes can be utilized as speakers to produce ultrasonic and audible sounds. The electrically conductive membranes are made from materials such as graphene, graphene oxide, and polymer films having a thin conductive coating.

A control device for an internal combustion engine including a variable compression ratio mechanism arranged to vary a relative position relationship between a piston and a cylinder, and thereby to vary a mechanical compression ratio, and a fuel injection valve arranged to directly inject a fuel within a combustion chamber, the control device includes: at least in an engine high load region including a full open, the compression ratio at an exhaust upper dead center being controlled to a low compression ratio, a fuel injection start timing of the fuel in which an air-fuel mixture is formed within the combustion chamber, and which is ignited by an ignition plug being set before an exhaust upper dead center so that a fuel injection period crosses an upper dead center.

A control device for an internal combustion engine including a variable compression ratio mechanism arranged to vary a relative position relationship between a piston and a cylinder, and thereby to vary a mechanical compression ratio, and a fuel injection valve arranged to directly inject a fuel within a combustion chamber, the control device includes: at least in an engine high load region including a full open, the compression ratio at an exhaust upper dead center being controlled to a low compression ratio, a fuel injection start timing of the fuel in which an air-fuel mixture is formed within the combustion chamber, and which is ignited by an ignition plug being set before an exhaust upper dead center so that a fuel injection period crosses an upper dead center.

An ignition device for an extraneously igniting combustion piston engine with an ignition chamber located between a cylinder head and a piston, wherein the cylinder head has an end surface which defines the ignition chamber and which is at least partially formed as a cylinder head electrode, and wherein an ignition chamber electrode is disposed within the ignition chamber and forms an ignition gap with the cylinder head electrode.