DE2909183C2 - Internal combustion engine - Google Patents

Description

25th

The invention relates to a valve controlled reciprocating piston combustion engine according to the preamble of claim 1. Such is known from DE-OS 20 62 323 is known _Μ

In internal combustion engines, the problem of improving the arises particularly recently thermal efficiency with a simultaneous reduction in the proportion of pollutants in the exhaust gases. To the effective reduction of the pollutants in the exhaust gases, it has proven to be beneficial to the machine to supply a lean air / fuel mixture. The problem then arises that the flame propagation speed is very low in the mixture and therefore the burning rate is small so that there is no high thermal efficiency As a result, the machine cannot perform well. To at Improving thermal efficiency in such operating conditions is the main one To increase flame propagation speed. For this purpose, from DE-OS 20 62 323 known internal combustion engine in the cylinder head a secondary chamber formed by a compressor is constantly supplied with a relatively rich fuel gas mixture. During the compression stroke of the Internal combustion engine opens the auxiliary valve that closes the secondary chamber from the combustion chamber, so that the mixture flowing from the secondary chamber into the combustion chamber to the mixture already present there, lean mixture layers

The outlined effort to achieve the ignition and spread of the family Stratified charge is considerable. The invention is based on the object of providing an internal combustion engine of the initially mentioned specified type, in which the stratified charge without the aid of a pressure charger can build up.

This object is achieved by the characterizing features of claim 1. An advantageous one The embodiment of the invention is the subject of the dependent claim.

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65 From the invention thus an internal combustion engine is provided in which, in contrast to the known a reciprocating Herströmen of gas from the combustion chamber into the secondary chamber and back occurs, the machine operates with just one fuel gas supply system, namely that which lean mixture through the inlet valve In order to build up a stratified charge, a portion of this gas filling is pressed into the secondary chamber and temporarily stored there during the combustion cycle, the exhaust cycle and the subsequent intake cycle and at the same time converted into a rich mixture by means of the additional fuel injected there - this is now comparable with the method in the known machine - is used to build up a stratified charge during the compression stroke of the subsequent work cycle.

The invention is intended below with reference to embodiments shown in the drawings are explained in more detail. It shows

F i g. 1 shows a longitudinal section through a first embodiment;

F i g. Figure 2 is a view of the cylinder head of the engine according to FIG. 1 from below;

F i g. 3 is a graphic representation of the timing of the intake valve, exhaust valve and auxiliary valve between the combustion chamber and the loading chamber;

Fig. 4 is a graph of the air / fuel ratio of mixtures generated in the combustion chamber and in the loading chamber;

F i g. 5 shows a longitudinal section through a second embodiment.

The F i g. 1 and 2 show a cylinder block 1 with a piston 2 guided in a cylinder bore 3, one on the cylinder block 1 with the interposition of a gasket 5 fixed cylinder head 4 and one Combustion chamber 6, which is delimited by piston 2 and cylinder head 4. Furthermore are a Inlet valve 7, an outlet valve 8, an inlet channel 9 and an outlet channel 10 can be seen. Also shown are a carburetor 11, a throttle valve 12 and a spark plug 13. As in FIG. 1 shows is in the cylinder head 4 a secondary chamber 14 is formed which is connected to the combustion chamber 6 via a channel 16 Adjacent chamber 14 and the channel 16, an auxiliary valve 15 is arranged that of a not shown here Drive can be actuated As shown in FIGS. 1 and 2 can be seen, the channel 16 opens into the wedge-shaped trained combustion chamber 6 in the direction of the central area. The sub chamber 14 is a fuel injector 17 which is attached to the cylinder head 4 and is connected to a fuel pump 18 driven by an engine The amount of fuel injected into the sub chamber 14 is controlled by a controller 19 influenced

3 shows the timing of the opening of the inlet valve 7, the outlet valve 8 and the auxiliary valve 15 between the secondary chamber and the combustion chamber. In Fig. 3, the ordinate L shows the valve lift and the abscissa the crank angle of the crankshaft that is driven by the piston 2. A stands for the inlet valve 7, B for the auxiliary valve 15 and C for the outlet valve 8. In FIG. 3 it can be seen that the auxiliary valve 15 opens approximately at the beginning of the compression stroke and closes again at the end of this stroke. In Fig. 3, the arrow D continues to indicate the duration of the fuel injection. Point of time

the fuel injection is set so that the Fuel injection begins immediately after the auxiliary valve 15 is closed, as shown in FIG. 3 shown is

In operation, a lean air / fuel mixture or a mixture with a high proportion of recirculated exhaust gases is introduced into the combustion chamber 6 via the inlet valve 7 during the intake stroke. When the piston 2 then begins to compress this gas mixture, the auxiliary valve 15 opens. In _{] 0 of} the secondary chamber 14 there is a combustible gas mixture which is under high pressure and which has been introduced into the secondary chamber 14 from the compression stroke of the previous work cycle. On the other hand, the pressure in the combustion chamber 6 is lower than the external atmospheric pressure at the beginning of the compression stroke. Therefore, the pressure difference between the gases in the secondary chamber Ϊ4 and in the combustion chamber 6 is very large and when the auxiliary valve 15 is now opened, the combustible mixture retained in the secondary chamber 14 flows at high speed into the combustion chamber 6. When the piston 2 moved upwards and the pressure in the combustion chamber 6 becomes higher than that in the secondary chamber 14, then combustible mixture is again pressed into the secondary chamber 14. With increasing compression, the pressure rises both in the combustion chamber 6 and in the secondary chamber 14, which is still open. At the end of the compression stroke, the auxiliary valve 15 closes. The combustible gas mixture in the combustion chamber 6 is then ignited by the spark plug 13 and combustion begins

Like F i g. 3 shows, on the other hand, fuel is supplied by the Injection device 17 is injected into secondary chamber 14 after auxiliary valve 15 is closed. There an adiabatic compression takes place in the secondary chamber 14 during the compression stroke, the The temperature of the combustible mixture in the secondary chamber 14 is relatively high and evaporates as a result the fuel injected into the sub chamber 14 is instantaneous. In the secondary chamber 14 is therefore a Combustion gas mixture is produced, which is richer than that in the combustion chamber 6. During the first half of the This richer mixture then enters the combustion chamber 6 as the compression stroke of the subsequent work cycle left out. At this point in time, the piston 2 is in a lower position. The top of the Combustion chamber 6 is therefore filled with a richer mixture than the lower area. In the combustion chamber 6 is a stratified charge available. The inflow lasts during the first half of the compression cycle richer mixture from the secondary chamber 14 into the combustion chamber 6. Shortly after the As the richer mixture flows out of the secondary chamber 14, the fuel gas mixture is in the combustion chamber 6 ignited by the spark plug 13. Because the time interval between the completion of the build-up of a stratified charge in the combustion chamber and the ignition is short, the stratified state remains in the combustion chamber upright until the ignition takes place Pa the space ^ o around the electrode path of the spark plug 13 at the time of ignition with a relatively rich mixture is fulfilled, a good ignition is achieved. The gas flow flowing out of the secondary chamber 14 calls a strong turbulence in the combustion chamber 6 {, 5 which results in an increase in the rate of combustion.

F i g. 4 shows the relationship between the air / fuel ratio of the fuel gas mixture in the combustion chamber 6 and the air / fuel ratio of the fuel gas mixture in the secondary chamber 14, ie between the amount of fuel that has been supplied by the carburetor 11 and the amount of fuel that has been supplied by the injection device 17 in FIG. 4, the ordinate AJF stands for the air / fuel ratio and the abscissa indicates the ratio between the amount of fuel supplied by the injector 17 to the amount of fuel supplied by the carburetor 11 and the injector 17 together. Accordingly, zero percent means that fuel is only supplied by the carburetor 11, while 100 percent means that fuel is only supplied by the injection device 17. In addition, FIG. 4 the curve F shows the mean value of an air / fuel ratio of the mixture which is formed in the combustion chamber 6, while the curve G shows an air / fuel ratio of a mixture which is formed in the auxiliary chamber 14. In an internal combustion engine according to the exemplary embodiments, the fuel quantities supplied by the carburetor 11 and the injection device 17 are controlled so that the mean value of the air / fuel ratios of the mixtures formed in the combustion chamber 6 and the secondary chamber 14 is approximately 16: 1, as is the case with the dashed line in FIG. 4 shows

In order to improve the evaporation of the fuel supplied from the injector 17, it is advantageous if the injection of the fuel by the injection device 17 immediately after Closing of the auxiliary valve 15 takes place, as indicated by the arrow Din F i g. 3 is shown

5 shows a further embodiment of the in F i g. 1 shown machine. According to FIG. 5 is a long channel 24 with a small cross-section in FIG Cylinder head 4 and formed in the outer wall of the exhaust pipe 23. The side chamber consists of two Partial chambers 14, 25 which are connected via this long channel 24. This flows into the during operation The front sub-chamber 14 pushes suction gas at high speed through the channel 24 into the rear Partial chamber 25 during the second half of the compression stroke. This gas then flows into the first Half of the compression stroke of the subsequent work cycle at high speed through the Channel 24 and through the front sub-chamber 14 back into the combustion chamber 6. Since that Suction gas flows in the channel 24 at high speed, the flow energy is transferred to this Intake gas and, as a result, the evaporation of the injected fuel is improved. To the To further promote evaporation of the fuel, the long channel 24 runs close to the outlet channel 10 to from to benefit from the waste heat. The good evaporation of the fuel results in a good one Ignition and combustion.

In addition to the advantages already described, it should be mentioned that the machine also has good cold start properties The temperature of the suction gas introduced into the sub-chamber rises quickly. This favors the evaporation of the fuel that is introduced into the secondary chamber, even before the machine is fully warmed up. In this way you get good ignition even when it is relatively cold Machine. Since the evaporation of the fuel is remarkably improved as a whole, there are differences has no effect on the volatility of fuels

the ignition and combustion properties. The machine can thus be used for a wide variety of fuels. Since the pressure in the sub-chamber is between 5 and 6 kg / cm ² , a low-pressure valve can be used as the fuel injector or an automatically opening fuel valve can be used.

For this purpose 3 sheets of drawings

Claims (2)

Patent claims: 1.Valve-controlled, externally ignited, lean fuel gas mixture sucking in reciprocating piston internal combustion engine for stratified charge operation with a secondary chamber in the cylinder head, which is provided with a fuel injection device and can be locked against the combustion chamber by means of an auxiliary valve that opens at the beginning of the compression cycle, in the vicinity of which the spark plug electrodes are arranged _{in the combustion chamber! 0} are, characterized in that the secondary chamber (14; 14, 24, 25) apart from the openings for the auxiliary valve (15) and the fuel injection device (17), is closed on all sides, and that they are immediately closed after the closing which takes place towards the end of the compression stroke of the auxiliary valve (15) the fuel is injected 2. Internal combustion engine according to claim 1, characterized in that the secondary chamber consists of two Partial chambers (14, 25) which are connected to one another by a long connecting channel (24), which runs near the outlet channel (10)