DE2406803C3 - Internal combustion engine with a main and an auxiliary combustion chamber - Google Patents

Description

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The invention relates to an internal combustion engine with at least one piston leading Cylinder that forms a main combustion chamber, which is connected to an ignition device via a flame duct containing auxiliary combustion chamber is connected, with a main supply duct for supply a relatively lean fuel-air mixture into the main combustion chamber and an auxiliary supply duct for feeding a relatively rich fuel-air mixture into the auxiliary combustion chamber as well as with a periodically controlled auxiliary inlet valve dominating the auxiliary supply channel.

In internal combustion engines of this type, that supplied to the auxiliary combustion chamber becomes relatively rich The fuel-air mixture ignites in this chamber and creates a flame that passes through the flame channel relatively lean mixture ignites in the main combustion chamber. This results in an operation with a overall lean fuel-air mixture, which reduces the harmful components in the exhaust gases will. However, it has been shown that these advantageous properties in all operating states or cannot be realized in the same way under all possible load conditions, which is due to the fact that the mixture in the main combustion chamber is not in every operating state is ignited optimally. Internal combustion engines of the type considered here, such as, for example are known from DT-AS 11 71 670, so require in an improvement in this regard.

From DT-OS 22 24 666 it is known in an internal combustion engine that has compression ignition works and in which the fuel is preheated in a heating chamber and then combined with compressed air and is thereby ignited, depending on the connection between the heating chamber and a combustion chamber from the machine speed through an appropriately controlled valve with a variable cross-section Mistake. As a result, the ignition timing can be changed depending on the engine speed, so that its timing, regardless of the engine speed, always enables optimal auto-ignition.

From US-PS 15 50 104 an internal combustion engine with compression ignition is also known, in which the fuel is fed to the combustion chamber through a valve-controlled duct. For this purpose, a valve can be provided which fulfills two functions, namely on the one hand the supply of the Fuel into a collecting chamber upstream of the combustion chamber, on the other hand the opening of a Channel between the collecting chamber and the combustion chamber. The valve is controlled so that it directs the fuel into the combustion chamber at the correct time, so that a the best possible timing of the ignition point is achieved. It's just one timing of fuel delivery. Furthermore, in this known internal combustion engine the control valve does not change the cross-section of a connecting channel.

In internal combustion engines of the type mentioned at the outset that work with external ignition and where the auxiliary combustion chamber and the main combustion chamber are not one and the same mixture, but rather differently enriched or leaned mixtures are supplied, the ignition point is not determined by the inflow of fuel into a combustion chamber, but rather at the ignition device adjusted by external electrical control. Should this be the harmful components of the exhaust gases are reduced, the failure of the known internal combustion engines working with compression ignition measures taken, because the ignition point optimally set for spark ignition can not by influencing the supply of fuel into a combustion chamber by means of a valve to be changed.

Fs is the object of the invention, in an internal combustion engine, those with auxiliary combustion chamber and main combustion chamber as well as with different dimensioned mixtures works, the harmful components in the exhaust gases for all operating conditions or occurring load cases in the same way.

An internal combustion engine of the type mentioned at the beginning is according to the invention to achieve this object designed such that the auxiliary inlet valve has a device for the operating states of the Internal combustion engine dependent automatic change of the effective cross section of the flame channel includes.

The invention makes it possible to use the auxiliary inlet valve, which is the supply of an enriched Fuel-air mixture in the auxiliary combustion chamber

_20th

also makes use of the transverse

^m t ^r -M of the flame channel depending on the respective

• »« to set the conditions so that on the one hand the

The strength of the enriched vegetables in the

Combustion chamber regardless of high or

"elasticity is optimal, on the other hand a stable flame is passed through the nmkanal in every operating condition, which guarantees a reliable, lean mixture in the main concentration chamber. It is therefore not a matter of controlling the flow of a substance or a burning mixture of * f material and air in a combustion chamber, nrfern to the adaptation of a flame by a "^ combustion chamber in a Hauptverbrennungs-, ₅ L mmer leading connecting channel, through which it is I operation with an overall lean frtstoff As will be shown, the invention also has advantageous effects on the flow conditions in the auxiliary combustion chamber, which also facilitate the solution of the task at hand.

Fin embodiment of the invention is in are described on the basis of the figures. It shows

Fig. 1 is a sectional view of part of a Internal combustion engine according to the invention

Fig. 2 is a schematic plan view of the mechanism for turning the valve stem in the auxiliary feed

channel, ...

Fi R 3 the section 3-3 from Fig. 1 and

F i g. 4 shows a representation similar to FIG. 3 for another Desired position of the individual parts.

The figures show an internal combustion engine with a main combustion chamber 2, the wall of which is partially formed by a piston, not shown. An opening 3 in the cylinder head «Tent in connection with an auxiliary combustion chamber 4. A main inlet valve 5 controls the flow of a relatively lean fuel-air mixture to the main combustion chamber 2 from a carburetor which is passed through a feed channel 7. A not The outlet valve shown of the usual type is assigned to the main combustion chamber 2.

An auxiliary inlet valve 8 controls the flow of a relatively rich fuel-air mixture from an auxiliary carburetor 9 via a feed channel 0 to the auxiliary combustion chamber 4. A mechanism 11, which can be actuated by a cam Π, moves the main inlet valve 5 and the auxiliary inlet valve . The outlet valve, not shown, is also controlled by a cam mechanism of the usual type

The auxiliary combustion chamber 4 is formed by a stationary shell 13 which is arranged in the cylinder head. This shell 13 has a first opening 15 which is aligned with the opening 3 and a second opening 15 which is connected to a chamber 4a in which the electrodes of a spark plug 12 are arranged. A plate or a rim eil Λ7 fs' is attached to the plate 8a of the auxiliary inlet valve 8 and protrudes into the interior of the shell 13. De edge portion 17 has a curved outer surface and is _m "de nnenwand the shell 13 in contact with the _ ... .- U -:...". ,,, ape ™ ifi de in a position SE * grazing ta de7 It is aligned with the openings 3 and _5, 14, as shown in Fig. 3. Furthermore, adjustment can be achieved by rotation if the opening is partially misaligned, as shown in Fig. 4. If the parts are in the position shown in Fig. 3, the effective size or the cross-section of the flame channel formed by the openings 14 and 3 is not reduced. However, if the parts are in the position shown in Fig effective size or the cross section of the flame channel or its opening is reduced.

Above the auxiliary inlet valve 8, a cross rod 18 is mounted in the cylinder head; it can be moved in the direction of its longitudinal axis. An arm 19 is attached to this crossbar. An arm 20 fastened to the upper end of the valve stem 9b of the auxiliary inlet valve 8 carries an upright pin 211 which is guided between lugs 19a on the outer end of the arm 19. It can be seen from the description that an axial movement of the cross rod 18 rotates the auxiliary inlet valve 8 within its guide bushing 8c, whereby the edge part 17 is rotated between the positions shown in FIGS. 3 and 4 and the effective size of the flame channel is changed.

As can be seen from FIG. 2, there is a load evaluation device 22 is provided which comprises a housing 23 and a flexible membrane 24. This membrane is connected within the housing 23 with the lateral shaft 18 and divides the housing 23, so that a Vacuum chamber 25 is formed. A vacuum line 26 is connected to the chamber 25 and leads to an opening 28, in addition to two other openings in an electromagnetically actuated three-way valve is provided. The second opening 29 is connected to the atmosphere, the third opening 30 protrudes a collecting device 31 with main inlet channel 7 behind the throttle valve of the main carburetor in FIG Connection. The winding 27 ′ of the electromagnetically actuated valve 27 is connected to a voltage source 35 connected via a first switch 33 and a second switch 34. The first switch 33 speaks the speed of the internal combustion engine, the second switch 34 moves depending on the Movement of the main carburetor throttle 6.

When the load on the internal combustion engine increases, both switches 33 and 34 open so that the Winding 27 is switched off and the armature 32 of the valve closes the opening 30. This is how the Atmospheric pressure on the diaphragm 24 so that the chamber 25 expands and the cross rod 18 moves will. This results in a counterclockwise rotation of the arm 20 and thus also of the inlet valve 8 (Fig. 2). At the same time, the effective size or the cross-section of the flame channel is reduced, as shown in FIG. 4 is shown. As the load on the Internal combustion engine, both switches 14 and 34 are closed, the winding 27 'is switched on and pulls the anchor 32. This closes the opening and opens the opening 30, so that the Supply vacuum acts on the vacuum chamber and pulls the crossbar 18 back. This Movement of the cross rod 18 is transmitted via the arms and 20 so that the inlet valve 8 in the Clockwise (Fig. 2). As a result, the edge part 17 is also in the position shown in FIG brought.

During the intake stroke of the piston, the main inlet valve 5 and the auxiliary valve 8 opened, so that a relatively lean mixture of the Main carburetor 6 into the main combustion chamber and a relatively rich mixture from the auxiliary carburetor enters the auxiliary combustion chamber 4. At the end

of the compression stroke, the spark plug 12 is ignited, so that the mixture in the auxiliary combustion chamber 4 is ignited and a flame from the flame channel into the main combustion chamber 2 reaches, which also ignites the relatively lean mixture in S of this chamber. That way you can the internal combustion engine can be operated with an overall lean fuel-air mixture.

When the machine is working under less load, the feed vacuum acts on the Vacuum chamber 25 of the load evaluation device 22, so that the auxiliary inlet valve 8 in the in F i g. 3 position shown. The opening of the flame channel through the edge part 17 is not in this case decreased. Accordingly, the residual gases in the ij Auxiliary combustion chamber 4 can be conveyed into the main combustion chamber 2 during the intake stroke. Effective cleaning of the auxiliary combustion chamber 4 takes place in this way, and the chamber 4 is filled with a new mixture, which is produced by the κ> Spark plug 12 can then be easily ignited.

When the internal combustion engine is working at a high load, the atmospheric pressure acts the vacuum chamber 25 of the load evaluation device 22, whereby the auxiliary inlet valve 8 in the reaches the position shown in Figure 4, in which the opening of the flame channel is reduced. This reduces the flow of the fuel-air mixture during the compression stroke from the main combustion chamber 2 to the auxiliary combustion chamber 4, whereby the formation of a swirl in the auxiliary combustion chamber 4 is prevented. That way will the flame generated there is not blown out, so that an ignition and combustion of the mixture in the Auxiliary combustion chamber 4 is ensured.

During the suction stroke, the opening of the flame channel is reduced, but the purging does not take place significantly impaired, since a larger volume of mixture is supplied. The sizes of the openings 14 and 3 are chosen so that the required flow of the mixture is maintained even when the auxiliary inlet valve with its plate 8a is moved away from the valve seat 8din to the open position.

It can be seen that the invention makes it possible to determine the effective size of the flame duct 3 to change by turning the auxiliary inlet valve 8. By setting the effective size of the flame duct opening the ignitability of the mixture in the auxiliary combustion chamber is improved by a spark plug, regardless of whether the internal combustion engine is under high or low load is working. The internal combustion engine can at any point in time in an operation with a total lean fuel-air mixture.

The construction described for changing the effective size of the flame channel includes one an opening provided edge part which is attached to the plate of the auxiliary inlet valve. This construction makes a special actuating element within the auxiliary combustion chamber 4 superfluous. she is not only simple, but also avoids impairment of the sealing of the auxiliary combustion chamber 4, what would be feared in the presence of a special adjustment mechanism for the flame channel 3. The auxiliary combustion chamber 4 maintains its air seal by contact between the valve seat 8t / and the valve disk 8a of the auxiliary inlet valve 8. It has been shown that the possibility of changing the effective size of the flame channel depending on the operating conditions of the internal combustion engine the cleaning or rinsing effect and the ignitability of the mixture at any point in time and at any time The operating condition of the internal combustion engine is significantly improved. For all operating states between An overall lean fuel-air mixture is achieved with low and high loads.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Internal combustion engine with at least one cylinder leading a piston, the one Hauptverbrenntkarr.mer forms, which contain an ignition device via a flame channel Auxiliary combustion chamber is connected, with a main supply duct for supply a relatively lean fuel-air mixture into the main combustion chamber and an auxiliary supply duct for feeding a relatively rich fuel-air mixture into the auxiliary combustion chamber as well as with a periodically controlled auxiliary inlet valve dominating the auxiliary supply channel, characterized in that the auxiliary inlet valve (8) has a device (17) for automatic change depending on the operating states of the internal combustion engine of the effective cross section of the flame channel (3). 2. Internal combustion engine according to claim 1, characterized in that the device (17) is attached to a valve plate (8a) of the auxiliary inlet valve (8) and protrudes into the auxiliary combustion chamber (4). 3. Internal combustion engine according to claim 2, characterized in that the device (17) is an edge part which protrudes near the flame duct (3) into the auxiliary combustion chamber (4), and that an arrangement (20, 21, 19, 18) for rotating the auxiliary inlet valve (8) and thus the edge part in the A change in the effective size or cross-section of the flame duct (3) is provided. 4. Internal combustion engine according to claim 3, characterized in that the arrangement (20,21, 19,18) can be controlled by the negative pressure of the main feed channel (7).