DE1576009A1 - Process for fuel preparation in multi-cylinder injection internal combustion engines and machines operating according to the process - Google Patents

Description

"Method for fuel preparation in multi-cylinder" internal combustion engines and machines operating according to the method "The invention relates to a Method for fuel preparation in multi-cylinder injection internal combustion engines by means of compressed gas as well as on multi-cylinder internal combustion engines operating according to the method.

Injection internal combustion engines are known in which for atomization of the fuel uses compressed air from the cylinder in the compression stroke of the same will. The main object of the invention is to provide one for the most complete possible Combustion particularly effective atomization and processing of the fuel to achieve a simple way that is particularly suitable for multi-cylinder machines.

Accordingly, the method according to the invention consists essentially in that the fuel jet to be injected into a cylinder is completely or partially through hot compressed gas taken from another cylinder is atomized. As compressed gas for fuel processing is used in particular for expansion or Compression gas, the fuel jet atomized by the compressed gas of the other cylinder is preferably injected in the intake stroke of the associated cylinder.

The pressurized gas can be fed directly to the intake manifold (in front of the inlet valve) or in the combustion chamber (behind the inlet valve) for the injector to be injected Fuel jet are guided. The fuel preparation can be done with atomization the fuel jet can be improved even further by means of compression gas, that by quantity, overflow time and entry point of the compression gas the mixture density is influenced in the cylinder so that a certain stratified charge results.

Further details of the invention are the following description one shown schematically in the drawing, according to the method according to the invention working four-cylinder internal combustion engine. Show here Fig. 1 is a plan view of the engine block with the overflow lines below one another connected cylinders, Fig. 2 is a schematic longitudinal section through the 2nd and 3. Cylinder of a first embodiment, FIG. 3 shows a schematic longitudinal section by the 1st and 2nd cylinders of a second embodiment and FIG. 4 is an ignition sequence diagram. In 1 shows the cylinders connected by overflow lines 10 and 11, respectively 12 (1, 2, 3, 4) of the four-cylinder internal combustion engine 13 with the firing order 1, 3, 4, 2 shown. The solid lines 10 mean overflow lines, in which expansion gas from cylinders preceding in the firing order in the intake stroke the following cylinder in the firing order by one crankshaft revolution is routed to the injection nozzles in the intake lines or combustion chambers. the Dashed lines 11 also mean - for another embodiment of the Invention - overflow lines in which compression gas from each in the Firing order of the preceding cylinders in the intake stroke of the respective following ones in the firing order Cylinders are routed to their injectors in the intake lines or combustion chambers will.

4 shows a stroke and ignition sequence diagram of the individual cylinders, the piston stroke between bottom dead center (UT) and top dead center (0T) of each individual cylinder being represented over two crankshaft revolutions of 7200 crank angles. The ignition point of each of these is indicated at the end of each compression stroke by the ignition symbol marked with the cylinder number 1, 2, 3 or 4, the same applies to the intake, compression, expansion and ejection of each cylinder by the dashed lines marked in FIG. 4 with a correspondingly bordered cylinder number.

In the exemplary embodiment according to FIG. 2 there is the injection nozzle 14 in the intake manifold 15 in front of the inlet valve 16 of the second cylinder with the cylinder space 17. It is supposed to be expansion gas for processing the fuel used will. For this purpose z. B. in the expansion stroke at point A (Fig. 4) by the Upper edge 18 of piston 19 opens a control bore 20 in cylinder wall 21 (Fig. 2), which via an overflow line 22 to the suction pipe 23 of the 3rd cylinder is connected to the cylinder space 24. Exhaust gas with the corresponding piston position Pressure flows in the direction of the arrow to the injection nozzle 25 from the overflow line 22 is encased and together with this forms an annular space 27. The fuel jet 26 is exiting approximately concentrically through the exiting at high temperature and speed Gas jet in the annular space 27 or at its outlet opening torn and with evaporation the fuel droplets processed. The control bore 20 remains open until in Extension stroke in B (Fig. 4) the piston upper edge 18 closes the bore 20 again. From A to B there is a connection between the cylinder space of the one in the expansion stroke Cylinder 2 with the suction channel 23 of cylinder 3. However, there is also the end of the suction stroke of cylinder 2 from A1 to B1 again connection of this cylinder with the intake manifold 23 of cylinder 3, which is now at the end of the expansion stroke or is at the beginning of the extension stroke. In the worst case, it can come out of the intake manifold 23 of the 3rd cylinder air can also be sucked in or in the beginning of the compression stroke of the second cylinder under flow reversal mixture. from the second cylinder in the line 22 are pushed over. However, this is not lost, but is upstream in the intake manifold 23 of the 3rd cylinder. Instead of the top of the piston 18 can also have a bore 28 (shown in dash-dotted lines in FIG. 2) in the piston 19 to control the bore 20 in the cylinder wall 21 can be provided. So is it is possible, depending on the position of the boreholes, to do one at any time Expansion or compression stroke to derive a precisely metered amount of gas. the The amount of gas depends on the time cross section and the pressure difference between the cylinders and suction line. In order to use the other mentioned execution option of the Method according to the invention compression gas from the preceding ones in the ignition sequence Cylinders in the intake stroke of the subsequent cylinders in the firing order To be able to use atomization of the fuel jet is, for example, in Fig. 3 shown arrangement taken. In this case z. B. the first and the second cylinder of a four-cylinder injection engine. In the compression stroke of the second cylinder 2 and the suction stroke of the cylinder 1 is in point D (Fig. 4) Control bore 30 in the cylinder wall 31 is opened by the control bore 32 in the piston 33, and the air-fuel mixture flows through the overflow line at the pressure prevailing in D. 34 in the direction of the arrow to the one opening into the intake manifold 36 of the first cylinder Injection nozzle 35 which is encased by the overflow line 34. In point E becomes the connection of the combustion chamber 38 of the second cylinder to the intake manifold 36 of the first Cylinder closed. However, there is a corresponding connection in each cycle the cylinder, i.e. also in the expansion stroke of cylinder 2 from E1 to D1 (Fig. 4), and simultaneous compression stroke of cylinder 1 in the exhaust stroke of Cylinder 2 from D2 to E2 and in its suction stroke from E3 to D3. In this case, under certain circumstances from E1 to D1 and from D2 to E2 exhaust gas pass into the intake manifold 36 of the cylinder 1 and are stored there. From E3 to D3 is via the suction pipe 36 of the first Cylinder and the overflow.

Line 34 against the direction of the arrow gas into the cylinder space 38 of the Cylinder 2 is also sucked in. The intake valve of cylinder 1 is during these times closed.

By choosing the position of D - E you can start or end the Injection a richer mixture can be generated. The mixture density can also be used through the overflow cross-section and thus the amount of compression gas and finally can be influenced by its point of entry into the cylinder. This can be achieve a very specific stratified charge. For example, towards the end of the Injection push the compressed mixture through the overflow line into the cylinder. This results in a very ignitable, fuel-rich layer, which is ignited first and which in turn is the less fuel-intensive one Layers ignite.

Is the injection nozzle 39, 40 (shown in dashed lines in Fig. 3) in the Combustion chamber or cylinder chamber 38, 41 attached, a shut-off device is expedient 42, 43 to be installed in the respective overflow line 34, 44 from the machine is controlled so that there is a connection only between the compression stroke and intake stroke the cylinder in question releases, but otherwise interrupts this connection.

Claims (15)

Claims 1. A method for fuel preparation in multi-cylinder injection internal combustion engines by means of compressed gas, characterized in that the one to be injected into one cylinder Hot fuel jet taken wholly or partially through another cylinder Pressurized gas is atomized. 2. The method according to claim 1, characterized in that a compression gas from the other cylinder to atomize the fuel jet is removed. 3. The method according to claim 2, characterized in that by Amount, overflow time and point of entry of the compression gas the mixture density is influenced in the cylinder so that a certain stratified charge results. 4th Method according to Claim 1, characterized in that for atomizing the fuel jet an expansion gas is taken from the other cylinder. 5. Procedure after a of claims 1 to 4, characterized in that by the pressurized gas of the other Cylinder atomized fuel jet is injected in the intake stroke of the assigned cylinder will. 6. The method according to claim 1 to 5, characterized in that that the compressed gas from the other cylinder directly to the injection nozzle for the fuel jet to be injected is directed. 7. The method according to claim 2, 3, 5 and 6, characterized in that with a four-cylinder engine with the firing order 1-3-4-2 Compression gas from the cylinders preceding in the firing order in the intake stroke of the subsequent cylinders in the firing order to the injection nozzles is routed into the intake lines of the second-named cylinder in each case. B. procedure according to claims 4, 5 and 6, characterized in that in the case of a four-cylinder engine with the firing order 1-3-4-2 expansion gas from cylinders preceding in the firing order in the intake stroke the one following in the firing sequence by one crankshaft revolution Cylinders to the injection nozzles in the intake lines of each of the latter Cylinder is directed. 9. According to the method according to claim 1 to 8 working Multi-cylinder injection internal combustion engine, characterized in that the cylinders of the machine in each case by means of one directly or indirectly controlled by the piston of the same Overflow line connected to an injection nozzle assigned to another cylinder is. 10. Internal combustion engine according to claim 9, characterized in that the in the overflow line branching off the cylinder wall is controlled by the upper edge of the piston will. 11. Internal combustion engine according to claim 9, characterized in that that the overflow line branching off in the cylinder wall through a control bore is controlled in the piston. 12. Internal combustion engine according to claim 9 to 11, characterized characterized in that the overflow line opens out coaxially to the injection nozzle. 13th Internal combustion engine according to claim 12, characterized in that the injection nozzle is sheathed by the overflow line. 14. Internal combustion engine according to claim 9 to 13, characterized in that the overflow line to one in the suction pipe of the associated Cylinder arranged injector leads. 15. Internal combustion engine according to claim 9 to 13, characterized in that the overflow line to one in the combustion chamber arranged injector leads.