DE102010037743B4 - Operating procedure for a two-stroke engine - Google Patents

Abstract

Operating method for a two-stroke engine (1), in which - at a bottom dead center (BDC) of a piston (3) oscillating in a cylinder (2), fresh air (9) flows in rotatingly via an inlet opening (4) provided in a cylinder wall, - the incoming fresh air (9) displaces part of the exhaust gas via an outlet opening (6) arranged in the cylinder head (5), - after the inlet and outlet opening (4,6) have been closed, a central injection of fuel (13) through a central injection in the cylinder head arranged (injection) nozzle (7) takes place, - the injected fuel (13) initially mixes with the exhaust gas still present and evaporates due to its temperature, - the evaporated fuel (13), the exhaust gas and the rotating fresh air (9) mix before the piston (3) reaches top dead center (TDC) and thus the ignition point, characterized in that the fuel (13) is injected in such a way that it does not come into contact with the cylinder wall.

Description

The present invention relates to an operating method for a two-stroke engine. The invention also relates to a two-stroke engine operating according to this operating method.

From the DE 10 2006 047 515 A1 a two-stroke engine, in particular in a motor vehicle with at least one working cylinder is known in which a piston is arranged to be movable in an oscillating manner. In addition, an outlet channel is provided above a top dead center of the piston, which opens into the working cylinder, as well as at least two inlet channels, which open into the working cylinder adjacent above a bottom dead center of the piston, so that a direct current flushing of the working cylinder results when the two-stroke engine is in operation. One of the inlet channels is arranged or designed as a scavenging channel in such a way that a main vector of the movement of fresh air flowing from the scavenging channel into the working cylinder comes from a first vector running parallel to a central longitudinal axis of the working cylinder in the direction of the top dead center of the piston and from a perpendicular to the central longitudinal axis of the working cylinder along a line intersecting the central longitudinal axis of the working cylinder, the second vector is composed. In general, this should enable improved purging in stationary and dynamic operation as well as exhaust gas stoichiometry control.

From the DE 101 00 054 A1 , of the DE 35 10 770 C2 , of the EP 0 204 687 A2 and the EP 0 198 816 A2 A two-stroke engine is also known with a working cylinder, a piston moving in an oscillating manner in the working cylinder, an outlet duct located above top dead center for discharging exhaust gases and an inlet duct located above bottom dead center for flushing the working cylinder with direct current, the inlet duct or the inlet opening being designed in this way are that the fresh air flows rotatingly into the working cylinder. According to DE 101 00 054 A1 the fuel injected into the working cylinder initially mixes with the residual exhaust gas still present in the working cylinder and evaporates due to its temperature. Then the rotating fresh air, the residual exhaust gas and the evaporated fuel mix.

From the DE 10 2007 025 285 A1 a two-stroke engine with an internal gas mixture formation is known. In this case, an injection device only injects fuel into a cylinder of the two-stroke engine at the point in time at which the piston has closed an intake opening, an outlet opening and an opening on the combustion chamber side of the at least one transfer channel and there is no longer any connection between the combustion chamber and the crankcase . In particular, this is intended to improve the performance of the two-stroke engine and to achieve an increased exhaust quality.

The present invention is concerned with the problem of specifying an improved operating method for a two-stroke engine which, in particular, enables better combustion and thus increased performance as well as reduced pollutant emissions.

According to the invention, this problem is solved by the subjects of the independent claims. Advantageous embodiments are the subject of the dependent claims.

The present invention is based on the general idea of structuring a compression stroke in a two-stroke engine as follows: First, fresh air flows in rotatingly at a bottom dead center of a piston of the two-stroke engine oscillating in a cylinder via an inlet opening provided in a cylinder wall. This means that the fresh air flowing into the combustion chamber flows into the combustion chamber with a swirl. The incoming fresh air displaces some of the exhaust gas that is still in the combustion chamber via an outlet opening in the cylinder head. By moving the piston starting from bottom dead center in the direction of top dead center, the inlet opening is initially closed, whereupon the outlet opening arranged in the cylinder head is also closed. After the two openings have been closed, fuel is injected centrally through a nozzle, in particular an injection nozzle, arranged centrally in the cylinder head. The injected fuel initially mixes with the exhaust gas that is still present from the previous work cycle and immediately evaporates due to the high temperature of the exhaust gas that is still present in the combustion chamber. Due to the rotation of the incoming fresh air and the immediate evaporation of the fuel due to the hot exhaust gas, the evaporated fuel, the exhaust gas and the fresh air mix to form a homogeneous mixture of fuel, exhaust gas and fresh air before the piston reaches top dead center and thus ignition point. In this way, a particularly homogeneous thorough mixing of the aforementioned mixture and thus particularly powerful and clean combustion can be achieved. This offers the particular advantage that two-stroke engines working with the operating method according to the invention are more powerful and at the same time lower in emissions compared to conventional two-stroke engines.

The invention is further based on the general idea, one after the previous The two-stroke engine operating method described in the paragraph, with a piston oscillating in a cylinder, an inlet opening for supplying fresh air, which is arranged in a cylinder wall, an outlet opening arranged in the cylinder head and an injection nozzle arranged centrally in the cylinder head. The inlet opening is arranged above the bottom dead center, whereas the outlet opening in the cylinder head is arranged above the top dead center. The injection nozzle located centrally in the cylinder head results in a particularly homogeneous mixing with the hot exhaust gas still in the combustion chamber and thus sudden evaporation of the injected fuel without it coming into contact with the combustion chamber walls, for example. For this purpose, the injection nozzle arranged centrally in the cylinder head is essential to the invention.

In a further development of the two-stroke engine according to the invention, the piston is conical towards the combustion chamber. The conical design, in conjunction with the inlet opening, causes the inflowing fresh air to swirl, which results in particularly good mixing of the inflowing fresh air with the exhaust gas still in the combustion chamber and the injected fuel. This homogeneous mixing of the fuel-exhaust-gas-fresh air mixture is in turn the basis for an effective, even and complete combustion, which results in the increased efficiency and at the same time the reduced pollutant emissions. Of course, in this sense, the inlet opening is also designed in such a way that the fresh air can flow into the cylinder with a swirl. The fresh air flows in essentially tangentially in the cylinder.

Further important features and advantages of the invention emerge from the subclaims, from the drawings and from the associated description of the figures on the basis of the drawings.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the respectively specified combination, but also in other combinations or alone, without departing from the scope of the present invention.

Preferred exemplary embodiments of the invention are shown in the drawings and are explained in more detail in the following description, the same reference symbols referring to the same or similar or functionally identical components.

Show each schematically

• 1 a cylinder of a two-stroke engine according to the invention in a fresh air inflow phase,
• 2 a representation as in 1 , but during a compression phase,
• 3 a representation as in 2 , but immediately before an ignition point,
• 4th a diagram for the schematic representation of a work cycle with an expansion and a compression phase.

According to the 1-3 , has a two-stroke engine according to the invention 1 one in a cylinder 2 oscillating piston 3 on, which is between a top dead center OT and a bottom dead center UT moved back and forth. In a cylinder wall of the cylinder 2 is an inlet port 4th arranged, whereas in a cylinder head 5 of the cylinder 2 an outlet port 6th is provided. In the cylinder head 5 is also an injection nozzle at a central point 7th for injecting fuel 13 into a combustion chamber 8th arranged. If you look at the 1-3 so you can see that the piston 3 to the combustion chamber 8th is designed to be conical. In addition is the inlet port 4th in the wall of the cylinder 2 designed such that fresh air 9 with a twist in the cylinder 2 flows in. The inlet opening 4th is above bottom dead center UT arranged, whereas the outlet opening 6th above top dead center OT is arranged.

The two-stroke engine according to the invention 1 is operated according to an operating method according to the invention, which is also according to the 1-3 is shown. In the 1-3 are individual stages of the compression phase of the two-stroke engine 1 drawn.

According to the 1 fresh air flows in 9 via the inlet port 4th provided the piston 3 at bottom dead center UT or just above bottom dead center UT is located. The inflow of fresh air 9 takes place in such a way that it rotates into the combustion chamber 8th flows in and at the same time part of it is still in the combustion chamber 8th from the previous work cycle via the exhaust gas in the cylinder head 5 arranged outlet opening 6th repressed. According to the 1 is the combustion chamber 8th divided into two zones, namely an exhaust zone 10 below the cylinder head 5 and a fresh air zone 11 above the piston 3 and below the exhaust zone 10 .

According to the 2 has the piston 3 already so far from bottom dead center UT moved up that he opened the inlet port 4th has closed, the outlet opening 6th also from the valve 12 has already been closed. According to the 2 At this stage, fuel is already being injected 13 through the one centrally on the cylinder head 5 arranged injection nozzle 7th in such a way that the injected fuel 13 no wall of the cylinder at any point 2 meets. When injecting the fuel 13 this initially mixes with the exhaust gas still present in the exhaust gas zone 10 and evaporates immediately due to the high temperature of the exhaust gas that is still present. Here, after closing the outlet opening 6th through the valve 12 Both a single and a multiple injection take place during the mixture formation phase. The first fuel injected 13 mixes - as mentioned before - with that in the cylinder 2 retained hot exhaust gas before it meets the fresh air that has flown in 9 can mix. This also results in a chain reaction, as a result of which a certain amount of energy is converted, in particular, if desired, by the temperature in the cylinder 2 to increase. The residual gas in the cylinder 2 is both due to a pressure difference between the cylinder 2 and one to the outlet opening 6th subsequent outlet channel 14th determined, as well as by a cross-sectional area of the outlet opening 6th and finally by closing the valve 12 .

Due to the central arrangement of the injection nozzle 7th in the cylinder head 5 and the central injection of the fuel 13 this is optimal in the combustion chamber 8th distributed without the surrounding walls of the cylinder 2 to contact. According to the 3 is now the piston 3 shortly before reaching its top dead center OT shown, the combustion chamber 8th already greatly reduced in size and thus the exhaust-gas-fresh-air-fuel mixture contained therein is already highly compressed. At this stage, the evaporated fuel mixes 13 , the exhaust gas in the exhaust zone 10 as well as the rotating fresh air 9 to a homogeneous mixture before the piston 3 the top dead center OT and thus reached the ignition point. Injecting fuel 13 can continue even in this phase or at this stage, but must be ended early for the homogenization before the ignition. This homogeneous mixing of the fuel 13 , the exhaust gas and the rotating fresh air 9 particularly good combustion and thus also low pollutant emissions can be achieved. The injection quantity and the injection duration can be dependent on the load and / or speed. Due to the temperature of the still in the cylinder 2 Existing exhaust gas and the compression pressure of the piston 3 the fuel / exhaust / fresh air mixture can be heated to its auto-ignition temperature. In particular, however, the fuel / exhaust gas / fresh air mixture can be heated almost to its auto-ignition temperature and ignited by means of room ignition, for example by means of radiation from microwaves.

If you look at the 4th so you can see the movement of the piston between top dead center OT above bottom dead center UT and back to top dead center OT follow. A combustion phase 15th a gas exchange phase follows 16 as well as a compression phase 17th on. The combustion phase 15th is also referred to as the expansion phase. At the beginning of the gas exchange phase 16 takes place before the bottom dead center is reached UT of the piston 3 an opening of the valve 12 what as an outlet port AÖ is designated. The inlet opening opens a little later 4th what as an inlet port EÖ is designated. It takes place in the same way after the bottom dead center has been exceeded UT closing the inlet opening 4th what as inlet closure IT and then closing the outlet opening 6th what as an outlet closure AS is designated. Between the outlet opening AÖ and the outlet closing AS can have a variable exhaust timing 18th as well as a variable inlet opening area 19th as well as a variable outlet opening area 20th lie.

In general, with the two-stroke engine according to the invention 1 or the associated operating method according to the invention, a homogeneous mixture formation and thus a clean and powerful combustion of the mixture can be achieved, as well as reduced pollutant emissions.

Claims (8)

Operating method for a two-stroke engine (1) in which - at a bottom dead center (BDC) of a piston (3) oscillating in a cylinder (2), fresh air (9) flows in rotatingly via an inlet opening (4) provided in a cylinder wall, - the incoming fresh air (9) displaces part of the exhaust gas via an outlet opening (6) arranged in the cylinder head (5), arranged (injection) nozzle (7) takes place, - the injected fuel (13) initially mixes with the exhaust gas still present and evaporates due to its temperature, - the evaporated fuel (13), the exhaust gas and the rotating fresh air (9) mix before the piston (3) reaches top dead center (TDC) and thus the ignition point, characterized in that the fuel (13) is injected in such a way that it does not come into contact with the cylinder wall. Operating procedures according to Claim 1 , characterized in that fuel (13) is injected until immediately before the ignition point is reached. Operating procedures according to Claim 1 or 2 , characterized in that an injection quantity and an injection duration are dependent on the load and / or speed. Operating procedure according to one of the Claims 1 to 3 , characterized in that the temperature of the exhaust gas still present in the cylinder (2) and the compression pressure of the piston (3) heats the fuel-exhaust-gas-air mixture almost to its auto-ignition temperature. Operating procedure according to one of the Claims 1 to 4th , characterized in that a single or multiple injection of fuel (13) takes place during the compression phase (17) of the piston (3). With an operating procedure according to one of the Claims 1 to 5 operated two-stroke engine (1), with - a piston (3) oscillating in a cylinder (2), - an inlet opening (4) for supplying fresh air, which is provided in a cylinder wall, - an outlet opening (6) arranged in the cylinder head (5), - An (injection) nozzle (7) arranged centrally in the cylinder head (5). Two-stroke engine after Claim 6 , characterized in that the piston (3) is conical towards the combustion chamber (8). Two-stroke engine after Claim 6 or 7th , characterized in that the inlet opening (4) is designed such that the fresh air (9) flows into the cylinder (2) with a swirl.

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