초록 ▼

There is provided a hydraulic fuel system having an integrated and internally mounted oil circuit for providing high pressure in a hydraulically operated electronically controlled fuel injector fuel system. There is provide an internally mounted high pressure pump in a pump housing in the crankcase

There is provided a hydraulic fuel system having an integrated and internally mounted oil circuit for providing high pressure in a hydraulically operated electronically controlled fuel injector fuel system. There is provide an internally mounted high pressure pump in a pump housing in the crankcase and connected to internally routed high pressure lines that deliver the oil to high pressure oil rails. There is provide an integrated low pressure oil reservoir in the crank case that comprises a low pressure oil cooler and reservoir. The oil cooler is preferably immersed inside the low pressure oil reservoir to optimize available engine space and improve heat transfer. There is also provided a high pressure pump filter that covers a high pressure pump inlet feed passage to prevent debris from passing into the high pressure oil pump and other components on the high pressure oil circuit.

대표청구항 ▼

There is provided a hydraulic fuel system having an integrated and internally mounted oil circuit for providing high pressure in a hydraulically operated electronically controlled fuel injector fuel system. There is provide an internally mounted high pressure pump in a pump housing in the crankcase

There is provided a hydraulic fuel system having an integrated and internally mounted oil circuit for providing high pressure in a hydraulically operated electronically controlled fuel injector fuel system. There is provide an internally mounted high pressure pump in a pump housing in the crankcase and connected to internally routed high pressure lines that deliver the oil to high pressure oil rails. There is provide an integrated low pressure oil reservoir in the crank case that comprises a low pressure oil cooler and reservoir. The oil cooler is preferably immersed inside the low pressure oil reservoir to optimize available engine space and improve heat transfer. There is also provided a high pressure pump filter that covers a high pressure pump inlet feed passage to prevent debris from passing into the high pressure oil pump and other components on the high pressure oil circuit. during the starting operation by a high pressure pump of the fuel metering system driven independently of the engine. 8. The method of claim 1, wherein, during the starting operation, in a compression phase of a cylinder of the engine, the corresponding inlet valve of the cylinder is closed delayed after the previous intake phase so that the compression phase, wherein both the inlet and outlet valves are closed, is shortened. 9. The method of claim 1, wherein, during the starting operation in an induction phase of a cylinder of the engine, the corresponding inlet valve of the cylinder is closed delayed after the previous compression phase so that the intake phase, wherein both the inlet and outlet valves are closed, is shortened. 10. A control element including a read-only-memory or flash memory, for a control apparatus of an internal combustion engine including an engine of a motor vehicle, comprising a program stored on said control element which can be run on a computer apparatus including on a microprocessor and is suitable for carrying out a method for starting a multi-cylinder direct-injecting internal combustion engine including an engine for a motor vehicle without the aid of a starter, each cylinder of the engine running sequentially through an induction phase, a compression phase, a work phase and a discharge phase during operation of the engine, the method comprising the steps of: in advance of the starting operation, bringing at least one of the inlet and outlet valves of each of at least two cylinders, whose pistons are disposed in respective locations after top dead center, into a position corresponding to the work phase; injecting fuel into the combustion chambers of said two cylinders and igniting said fuel thereby triggering said starting operation; and, after an unsuccessful first ignition of fuel injected into at least two cylinders in the work phase, the method is carried out once more with inverted phases of the individual cylinders wherein the inlet and outlet valves of said individual cylinders are driven so that cylinders which were previously in said intake phase are now in said work phase and vice versa and individual cylinders which were previously in said compression phase are now in said discharge phase and vice versa. 11. A multi-cylinder direct-injecting internal combustion engine including an engine of a motor vehicle, the engine comprising: a detecting device for determining the positions of at least two pistons of two cylinders of said engine; positioning means for bringing at least one of the inlet and outlet valves of each of at least two cylinders, whose pistons are disposed in respective locations after top dead center, into a position corresponding to the work phase in advance of the starting operation; a fuel metering system for injecting fuel into the combustion chambers of said two cylinders and means for igniting said fuel thereby triggering said starting operation of said engine without the aid of a starter; each cylinder of the engine running sequentially through an induction phase, a compression phase, a work phase and a discharge phase during operation of the engine; and, a control apparatus including means for carrying out a method for starting said engine including the steps of: in advance of the starting operation, bringing at least one of the inlet and outlet valves of each of at least two cylinders, whose pistons are disposed in respective locations after top dead center, into a position corresponding to the work phase; injecting fuel into the combustion chambers of said two cylinders and igniting said fuel thereby triggering said starting operation; and, after an unsuccessful first ignition of fuel injected into at least two cylinders in the work phase, the method is carried out once more with inverted phases of the individual cylinders wherein the inlet and outlet valves of said individual cylinders are driven so that cylinders which were previously in sai d intake phase are now in said work phase and vice versa and individual cylinders which were previously in said compression phase are now in said discharge phase and vice versa. 12. The multi-cylinder direct-injecting engine of claim 11, wherein said positioning means is configured as a camshaft-free control of said valves. 13. The multi-cylinder direct-injecting engine of claim 11, wherein said positioning means is configured as a variable camshaft actuator, which is assigned to the inlet end, for adjusting an early closure of the inlet valves to inflow. 14. The multi-cylinder direct-injecting engine of claim 11, further comprising means for moving the piston of the cylinder into a pregivable start position at the beginning of the starting operation. 15. The multi-cylinder direct-injecting engine of claim 11, wherein said fuel metering system includes a high pressure pump, which is driven independently of said engine, for building up a fuel injection pressure. 16. A control apparatus of a multi-cylinder internal combustion engine including an engine of a motor vehicle, the engine including: a detecting device for determining the position of a piston in a cylinder of the engine; a fuel metering system for injecting fuel into a combustion chamber of at least one cylinder, whose piston is disposed in a work phase; and, means for igniting an air/fuel mixture disposed in the combustion chamber of said at least one cylinder in order to thereby trigger a starting operation of said engine without the aid of a starter; each cylinder of the engine running sequentially through an induction phase, a compression phase, a work phase and a discharge phase during operation of the engine, said control apparatus comprising means for carrying out a method for starting said engine including the steps of: in advance of the starting operation, bringing at least one of the inlet and outlet valves of each of at least two cylinders, whose pistons are disposed in respective locations after top dead center, into a position corresponding to the work phase; injecting fuel into the combustion chambers of said two cylinders and igniting said fuel thereby triggering said starting operation; and, after an unsuccessful first ignition of fuel injected into at least two cylinders in the work phase, the method is carried out once more with inverted phases of the individual cylinders wherein the inlet and outlet valves of said individual cylinders are driven so that cylinders which were previously in said intake phase are now in said work phase and vice versa and individual cylinders which were previously in said compression phase are now in said discharge phase and vice versa.