EP0202216A2 - Method of scavenging a two-stoke reverse-flow scavenged engine, and engine working according to this method - Google Patents

Abstract

1. A method of scavenging a two-stroke reverse-flow scavenged engine comprising a piston-controlled exhaust passage and two or more primary as well as secondary scavenge passages on either side of the said exhaust passage, through which the fresh charge is delivered to the cylinder by means of a crankcase pump, a flow being generated at the beginning of the scavenging process by the primary scavenge passages located on either side of the exhaust passage in the immediate vicinity of the latter, which will prevent the fresh charge from entering the exhaust passage, wherein during the downward stroke of the piston the intake ports of the two or more primary scavenge passages are uncovered at a time when the pressure in the cylinder still is higher than in the crankcase, inducing the exhaust gas to flow into said scavenge passages and to force back the fresh charge contained therein without entering the crankcase itself, and wherein upon a drop of the pressure in the cylinder below the pressure level in the crankcase a connection is established between the primary scavenge passages and the crankcase, the intake ports of the two or more secondary scavenge passages being uncovered at the same time, such that the cylinder is scavenged and filled with fresh charge, the exhaust gas admitted into the primary scavenge passages before being discharged again due to a reversal of pressures, forming a barrier against the escape of fresh charge through the exhaust port, upon which the fresh charge will be discharged through the said primary scavenge passages.

Description

The invention relates to a method for changing the charge in two-stroke internal combustion engines with reverse purge, with the piston-controlled outlet channel and at least two overflow channels arranged on both sides of the outlet channel, via which the fresh charge is introduced into the cylinder by means of a crankcase pump, and to a two-cycle - Internal combustion engine to carry out the process.

A two-stroke internal combustion engine, in which the method mentioned at the outset is used, is known from US Pat. No. 4,253,433. This internal combustion engine has two groups of overflow channels, which connect the crankcase designed as a crankcase pump to the cylinder. An inlet, through which the internal combustion engine is supplied with the fuel-air mixture, is connected directly to an overflow channel opposite the outlet channel, the opening of the inlet in this approximately midway between the inlet slot of the overflow channel in the cylinder and its opening into the Crankcase is done. Another inlet, through which air is supplied to the internal combustion engine, opens into the crankcase. Two further overflow channels are located on both sides of a plane containing the cylinder axis and intersecting the first overflow channel and the outlet channel in the middle. When the internal combustion engine is operating, the piston in the downward movement compresses the air in the crankcase, causing it to pass through all overflow channels into the cylinder arrives and entrains the previously introduced mixture from the first overflow channel. The air emerging simultaneously from the other overflow channels separates the mixture from the outlet slot, as a result of which the short-circuit loss of charge via the outlet channel is reduced. This should aim at lower fuel consumption and better combustion due to mixing with the air. The disadvantage here is the relatively high design effort, given by the two inlet openings, which are provided with valves and two controlled throttle devices.

According to DE-OS 26 50 834 a two-stroke internal combustion engine is known, in which between the outlet channel and the inlet slots of overflow channels designed as storage spaces, which lead to a rich mixture, inlet slots of further overflow channels are arranged, which introduce a lean mixture, the lean mixture being Purge gas acts. During the combustion cycle, the piston moves down, as a result of which the lean fuel-air mixture is pre-compressed and enters the overflow channels and the storage spaces previously filled with the rich fuel-air mixture. As soon as the piston clears the inlet slots, a lean fuel-air mixture flows from the overflow channels and a rich mixture flows into the cylinder from the storage spaces. The lean mixture purges the residual gases from the cylinder, while the rich mixture from the storage spaces mixes with the lean mixture, so that an ignitable fuel-air mixture is formed. Because the inlet slots of the overflow channels lie between the inlet slots of the storage spaces and the outlet channel, a rich mixture cannot get into the outlet channel and be lost for combustion. A disadvantage of this internal combustion engine is the considerable design effort, given by an additional auxiliary carburetor, or by at least one separate air inlet.

From AT-PS 138.547 it is known to prevent the undesired outflow of fresh gas through the exhaust port during the purging in two-stroke internal combustion engines with cross-purging by the cylinder being purged with exhaust gas and fresh gas one after the other. This takes place through a chamber which is connected to the cylinder chamber at the end of the expansion stroke before reaching the dead position, so that part of the combustion gases enter the chamber. The outlet slots are then opened so that the cylinder is pre-rinsed by the combustion gases stored in the chamber, after which the fresh charge finally enters the cylinder through the inlet slots. The upper edge of the outlet channel is lower than the upper edge of all flushing channels. This is intended to reduce the flushing losses that occur during the initial phase of the flushing. However, it is disadvantageous that the mixture losses occurring during the further progress of the flushing cannot be influenced by these measures. The structural effort for this machine is also higher than that of comparable conventional two-stroke internal combustion engines.

The object of the present invention is to provide a method for changing the charge in two-stroke internal combustion engines, which can be used with structurally simple, inexpensive precautions and guarantees good washing results, an improvement in terms of low-pollutant and more economical operation compared to conventional two-stroke internal combustion engines being achieved.

This object is achieved in that when the piston moves downward, the inlet slots of at least two first overflow channels, which are adjacent to the outlet channel on both sides, are opened at a time when the pressure in the cylinder is still higher than in the crankcase, so that exhaust gas flows into these overflow channels and pushes the fresh charge back into it without penetrating into the crankcase itself, and that as a result the inlet slots overflow at least two second ones channels are released, which are also arranged on both sides of the outlet channel and are further away from it than the first overflow channels, whereby the cylinder is flushed and filled with fresh charge, with the previously introduced exhaust gas emerging from the first overflow channels because of reversal of the pressure conditions and forms a barrier against the overflow of fresh charge. to the outlet slot and then also fresh charge flows out through it. As a result, an exhaust gas-fresh gas stratified flushing process is implemented which does not require any additional auxiliary carburetor or fresh air inlets, any additional inlet control elements which would have to be coordinated with one another being eliminated. The method according to the invention requires considerably less design effort and also has good purge and charge properties, the exhaust gas barrier, which prevents a short-circuit loss of charge directly via the outlet, ensuring low-pollutant, economical operation of the internal combustion engine.

The method according to the invention can be used particularly advantageously if, at the same time as the second overflow channels, at least one third overflow channel which opens at the wall of the cylinder opposite the outlet slot is opened or closed. This enables particularly good purging results to be achieved, in particular when using two or three channels, the gas kinetics being able to be influenced in a favorable manner in particular by freely selecting the inflow angles.

A two-stroke internal combustion engine for practicing the method according to the invention consists in that the upper edge of the inlet slots of at least two first overflow ducts, which are adjacent to the outlet duct and lie on both sides of a plane containing the cylinder axis through the middle of the outlet duct or the outlet duct parts, is higher than the upper edge of the inlet slots of at least two second overflow channels, which are each arranged next to the first overflow channels, whereby Exhaust gas reaches the first overflow channels, and that these first overflow channels have dimensions and / or control devices such that penetration of the exhaust gases into the crankcase is prevented. This represents a first structurally simple way to open the first overflow channels at a time when the outlet slots are also already open, but the pressure in the cylinder is still higher than in the crankcase, as a result of which the exhaust gas required as sealing gas is introduced into these first overflow channels reached.

An advantageous variant of a two-stroke internal combustion engine for carrying out the method according to the invention is given in that the control edge of the piston is lower in the area of the first overflow channels, which are adjacent to the outlet channel, than in the area of the second overflow channels, which are each adjacent to the first, so that Exhaust gas reaches the first overflow channels and that these first overflow channels have dimensions and / or control devices such that penetration of the exhaust gases into the crankcase is prevented. This provides a second option for filling the first overflow channels with exhaust gas. In both design variants, overflow of the exhaust gases into the crankcase must be prevented, either by certain dimensions, the length and the cross section of the first overflow channels having to be matched to the dimensions of the cylinder, or by control devices in these channels.

According to one embodiment of the invention, it is provided that a control device preventing the penetration of exhaust gases into the crankcase is formed by the crank web, which for this purpose has a recess which interacts with the confluence of each first overflow channel in the crankcase. The purpose of this is to prevent the exhaust gases returning into the first channels from penetrating too quickly or too far in the direction of the crankcase and still to achieve an adequate filling of the channels with exhaust gas before the purging begins.

• Figur 1 eine erfindungsgemäße Zweitakt-Brennkraftmaschine teilweise schematisch in der Phase 1 des erfindungsgemäßen Verfahrensablaufes teilweise geschnitten nach der Linie I-I .in Fig. 3,
• Figur 2 einen Schnitt nach der Linie 11-11 in Fig. 1 und
• Figur 3 einen Schnitt nach der Linie III-III in Fig. 1, sowie in gleicher Schnittführung bei der selben Brennkraftmaschine, die
• Figuren 4, 5 und 6 die Phase 2 des Verfahrensablaufes, die
• Figuren 7, 8 und 9 die Phase 3 des Verfahrensablaufes, die
• Figuren 10, 11 und 12 die Phase 4 des Verfahrensablaufes, weiters die
• Figuren 13 und 14 eine andere Zweitakt-Brennkraftmaschine in der Phase 1 in einer Schnittführung entsprechend Fig.1 und 2, die
• Figuren 15, 16 und 17 die Phasen 2, 3 und 4 des Verfahrensablaufes entsprechend Fig. 5, 8 und 11 und
• Figur 18 ein Kurbelwinkeldiagramm.

The invention is explained in more detail with reference to the drawings. Show it:

• 1 shows a two-stroke internal combustion engine according to the invention, partly schematically in phase 1 of the process flow according to the invention, partially cut along line II in FIG. 3,
• Figure 2 is a section along the line 11-11 in Fig. 1 and
• Figure 3 shows a section along the line III-III in Fig. 1, and in the same cut in the same internal combustion engine, the
• Figures 4, 5 and 6, phase 2 of the process, the
• Figures 7, 8 and 9, phase 3 of the process, the
• Figures 10, 11 and 12, phase 4 of the process, further the
• Figures 13 and 14 another two-stroke internal combustion engine in phase 1 in a sectional view corresponding to Fig.1 and 2, the
• Figures 15, 16 and 17, phases 2, 3 and 4 of the process sequence corresponding to Fig. 5, 8 and 11 and
• Figure 18 is a crank angle diagram.

The same parts are provided with the same reference numerals.

The two-stroke internal combustion engine shown in FIGS. 1 to 12 has a cylinder 1 with a cylinder head 2 and a crankcase 3 with a crankshaft 4. In the cylinder 1, the piston 6, which is connected to the crankshaft 4 via the connecting rod 5, moves in the cylinder head 2 intended. The cylinder 1 is connected to the crankcase 3 via a group of first overflow channels 8, a group of second overflow channels 9 and a group of third overflow channels 10, the group of first overflow channels 8 inlet slots 12, the group of second overflow channels 9 inlet slots 13 and the group of third overflow channels 10 has inlet slots 14 in the cylinder 1. The group of the first and the second overflow channels 8 and 9 each comprise two channels on both sides of a plane E containing the cylinder axis 15 and intersecting the outlet channel 16 in the middle. Both groups can, however, also have several channels on both sides of this plane E. In the region 11 'of the first overflow channels 8, the control edge 11 of the piston 6 has a depression. The group of the third overflow channels 10 also has two channels with inlet slots 14 which are diametrically opposite the outlet channel 16 with the outlet slot 17. However, this group can also have only one or more than two channels 10. The first overflow channels 8 have a common opening 18 in the crankcase 3. The opening of the second overflow channels 9 in the crankcase is denoted by 19. By coordinating the volume of the overflow channels 8 with that of the cylinder 1, exhaust gases from the cylinder 1 are prevented from penetrating into the crankcase 3 during operation of the internal combustion engine. The fresh charge indicated by dots is supplied via the carburetor 23, which is connected to the crankcase 3 via the supply duct 24, which has the check valve 25.

In the operation of the two-stroke internal combustion engine, the charge change takes place according to the method described with reference to FIGS. 1 to 12. In phase 1 of the process sequence (FIGS. 1 to 3), the inlet slits 12, 13, 14 and the outlet slit 17 are not yet moved by the downwardly moving piston 6 or by its control edge 11, which has a lowering in the region 11 ' released and cylinder 1 is filled with exhaust gas. The crankshaft 4 rotates according to the direction of rotation indicated by the arrow 28.

At the same time, the fresh charge located in the crankcase 3 is compressed by the piston 6, the overflow channels 8, 9, 10 being closed by the piston. At this time there is only exhaust gas in cylinder 1.

In phase 2 of the process sequence (FIGS. 4 to 6), the piston 6 has moved further downward and now gives both the outlet slot 17 of the outlet channel 16 and the inlet slots 12 of the first overflow channels 8 through a control edge of the piston which is lowered in the region 11 ' 6 free. These channels thus open earlier than the second overflow channels 9 and so early that the cylinder pressure is still higher than the purge pressure in the crankcase 3 and the channels 8, so that exhaust gas strikes back in the upper part 21 of these channels and the fresh charge in the lower part 22 repressed. The overflow channels 8 are so long that penetration of the exhaust gases into the crankcase 3 is avoided with certainty. The expansion of the exhaust gases along the arrows 29 and 30 in FIGS. 4 and 5 can be clearly seen. The upper parts 21 of the overflow channels 8 filled with exhaust gas can also be seen from FIG. 6.

In phase 3 of the process sequence (FIGS. 7 to 9), in which the piston 6 is at its bottom dead center, the overflow channels 9 and approximately at the same time the overflow channels 10 present here in order to achieve a better washing result and flush the cylinder 1 with them Fresh load. At the same time, the direction of flow reverses according to arrow 31 in FIG. 7 or 32 in FIG. 8 in channel 8 due to the pressure drop in cylinder 1, and the exhaust gas now emerging in the cylinder acts as a barrier (sealing gas) for the fresh charge flow from the channels 9 and 10. In this way the short-circuit loss of fresh charge is prevented directly into the outlet channel 16. Only towards the end of the rinsing phase does fresh charge emerge from the overflow channels 8.

At the end of the rinse in phase 4 of the procedure Running (Fig. 10 to 12), the cylinder 1 is ideally filled with fresh charge, without a part of it being lost in the outlet channel 16. As a result, the fresh charge with which the cylinder 1 is now completely filled (see FIGS. 11 and 12) is compressed by the piston 6 moving upward.

Different control times for the group of the first overflow channels 8 and the group of the second overflow channels 9 can also be achieved in that the upper edges 12 'of the inlet slots 12 of the channels 8 are higher than the upper edges 13' of the inlet slots 13 of the channels 9, the Control edge 11 of the piston 6 does not have a lowered area 11 ', or by a combination of different high top edges 12', 13 'with lowered areas 11'.

13 to 17 show a variant of the two-stroke internal combustion engine specified at the outset, which differs from the first-mentioned embodiment in that a control device 20 for the first overflow channels 8 is present. This control device 20, consisting of separate openings 33 of the channels 8 in the crankcase 3 and a respective cooperating recess 27 on the circumference of each crank web 26, prevents the exhaust gases from penetrating into the crankcase 3.

In phase 1 of the process sequence (FIGS. 13 and 14), all the inlet slots 12, 13, 14 and the outlet slot 17 and the opening 33 in the crankcase 3 are closed and the cylinder 1 is filled with the exhaust gas.

15 to 17 show the phases 3 to 4 of the process sequence, which come about by rotating the crankshaft 4 according to arrow 28 and are identical to FIGS. 5, 8 and 11 of the first-mentioned example with regard to the piston position and the gas exchange.

15, the overflow channels 8 are at their A Orifices 33 in the crankcase 3 are still closed by the crank web 26, at the same time, as indicated by the arrow 30, exhaust gas flows from the cylinder 1 into the latter, but cannot reach the crankcase 3.

When crankshaft 4 continues to rotate according to arrow 28 to bottom dead center of piston 6 (FIG. 16), overflow channels 9 are also cleared, so that fresh charge penetrates cylinder 1. By reversing the pressure conditions and releasing the opening 33 through the recess 27, exhaust gas acting as sealing gas passes through the overflow channel 8 according to arrow 32 into the cylinder 1 and prevents the fresh charge from flowing out into the outlet channel 16. Towards the end of the charging process, the overflow channels 8 also pass through Fresh charge in cylinder 1.

Phase 4 of the process sequence (FIG. 17) shows the internal combustion engine after the charge has been changed. As shown, the control device 20 effectively prevents the exhaust gas front from penetrating into the crankcase 3, as a result of which there is more freedom in coordinating the dimensions of the overflow channels 8.

• α₀.... Öffnungsbeginn des Auslaßkanals in °KW n.OT
• α₁.... öffnungsbeginn der Gruppe der ersten Uberströmkanäle 8 in °KW n.OT
• α_2,3.. öffnungsbeginn der Gruppe der zweiten und der Gruppe der dritten überströmkanäle 9, 10 in °KW n.OT
• α₄.... öffnungsbeginn der Steuereinrichtung 20 in °KW n.OT
• α₅.... öffnungsschluß der Steuereinrichtung 20 in °KW n.OT
• D₀.... öffnungsdauer des Auslaßkanals in °KW
• D₁.... Öffnungsdauer der Gruppe der ersten Uberströmkanäle 8 in ^oKW
• D_2,3.. öffnungsdauer der Gruppe der zweiten und der Gruppe der dritten Überströmkanäle 9, 10 in ^oKW

A control diagram for the individual channels 8, 9, 10, 16 and for the control device 20 is shown in summary in FIG. 18 for both design variants. The top and bottom dead center is referred to as OT or UT. The angular range in which the control device 20 keeps open is designated SE to SS. The other abbreviations in the crank angle diagram mean:

• α ₀ .... start of opening of the exhaust duct in ° KW n.OT
• α ₁ .... opening of the group of the first overflow channels 8 in ° KW n.OT
• α _2,3 .. opening of the group of the second and the group of the third overflow channels 9, 10 in ° KW n.OT
• α ₄ .... opening of the control device 20 in ° KW n.OT
• α ₅ .... opening of the control device 20 in ° KW n.OT
• D ₀ .... opening time of the exhaust duct in ° KW
• D ₁ .... opening time of the group of the first overflow channels 8 in ^o KW
• D _2,3 .. opening time of the group of the second and the group of the third overflow channels 9, 10 in ^o KW

The overflow ducts and the outlet duct are controlled in the following chronological sequence: the opening start α _{o of} the outlet duct is before the opening beginning α _{1 of} the overflow ducts 8, followed by the opening beginning α _{2,3 of} the overflow ducts 9 and 10, which have the shortest opening duration D _2,3 and close first. Then the channels 8, which have an average opening time D ₁ and finally the outlet channel with the opening time D _0, close.

The opening start α _{4 of} the control device 20 lies between the opening start α _{0 of} the outlet channel 16 and the bottom dead center (UT) of the piston, the opening end α ₅ approximately between the bottom dead center of the piston and the outlet end.

Claims (5)

1. Process for changing the charge in two-stroke internal combustion engines with reverse purge, with the piston-controlled outlet channel and at least two overflow channels arranged on both sides of the outlet channel, via which the fresh charge is introduced into the cylinder by means of a crankcase pump, characterized in that the downward movement of the Piston, the inlet slots of at least two first overflow channels, which are adjacent to the outlet channel on both sides, are opened at a time when the pressure in the cylinder is still higher than in the crankcase, so that exhaust gas flows into these overflow channels and pushes the fresh charge back into it without itself penetrate the crankcase, and that as a result, the inlet slots are released at least two second overflow channels, which are also arranged on both sides of the outlet channel and are farther away from it than the first overflow channels, whereby the cylinder is flushed with fresh charge d is filled, with the previously introduced exhaust gas initially emerging again because of reversal of the pressure conditions from the first overflow channels and forming a barrier against the overflow of fresh charge to the outlet slot and then likewise fresh charge flowing out through the latter. 2. The method according to claim 1, characterized in that approximately simultaneously with the second overflow channels at least a third overflow channel, which opens on the wall opposite the outlet slot of the cylinder, is opened or closed. 3. Two-stroke internal combustion engine for performing the method according to claim 1 or 2, characterized in that the upper edge (12 ') of the inlet slots (12) at least two first overflow channels (8) which are adjacent to the outlet channel (16) and on both sides one the Zy Linderachse (15) containing through the center of the outlet channel (16) or the outlet channel parts plane (E) are higher than the upper edge (13 ') of the inlet slots (13) of at least two second overflow channels (9), each next to the first overflow channels (8) are arranged, whereby exhaust gas reaches the first overflow channels (8) and that these first overflow channels (8) have dimensions and / or control devices (20) that prevent the exhaust gases from penetrating into the crankcase (3) is. 4, two-stroke internal combustion engine for performing the method according to claim 1 or 2, or according to claim 3, characterized in that the control edge (11) of the piston (6) in the region (11 ') of the first overflow channels (8), which is the outlet channel (16) are deeper than in the area of the second overflow channels (9), which are each adjacent to the first, whereby exhaust gas enters the first overflow channels (8) and that these first overflow channels (8) have such dimensions and / or control devices (20) that penetration of the exhaust gases into the crankcase (3) is prevented. 5. Two-stroke internal combustion engine according to claim 3 or 4, characterized in that the penetration of exhaust gases into the crankcase (3) preventing control device (20) is formed by the crank arm (26), for this purpose one with the junction (33rd ) Each first overflow channel (8) in the crankcase (3) cooperating recess (27).

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