DE10144683B4 - Four-stroke internal combustion engine with direct injection - Google Patents

Abstract

Four-cycle internal combustion engine with spark ignition, direct injection of a fuel with an injection nozzle (22) by means of an injection jet (24) in a combustion chamber (28), at least one an air flow (26) into the combustion chamber inlet passage (16) with inlet valve, at least one outlet channel (18) with exhaust valve, wherein inlet valve and exhaust valve are arranged on opposite sides of the combustion chamber (28) and the injection nozzle (22) is arranged inlet valve side, and a piston (10) having a piston head (12) and in the direction of movement of the piston (10) has extending central longitudinal axis (38), wherein the piston head (12) has a fuel well (34) and an air trough (36), which are separated from a bump (40) of the piston head (12), which forming a highest point of the piston crown (12), wherein the injection jet (24) in the fuel well (34) at one of the elevation (40) opposite lying side and the air flow (26) in the opposite direction with respect to the injection jet (24) in the air trough (36) at one of the elevation (40) opposite side occurs, characterized in that the elevation (40) in the circumferential direction about a part the fuel trough (34) extends around, that the air flow (26) forms a Tumbleströmung (64) and two flank flows (68) upon entry into the air well (36), the latter being directed in the circumferential direction, that the flank flows (68) in the region of the entry of the fuel jet (24) into the fuel trough (34) and form a resulting flow (70) into the fuel trough (34) into it.

Description

The invention relates to a direct-injection four-stroke internal combustion engine according to the preamble of claim 1.

For generating a suitable mixture of air and fuel in a combustion chamber of a four-stroke internal combustion engine with direct injection, it is known to provide special tumble or swirl flow generating inlet ducts and form piston crowns with corresponding wells and baffles. In a swirling flow, a cylinder charge rotates about the cylinder axis, for example, due to the intake passage, while in a tumble flow rotation about an axis parallel to the crankshaft is observed.

So describe the DE 197 13 030 A1 , the DE 197 13 029 A1 and the DE 197 13 028 A1 each a spark-ignition, direct-injection four-cycle internal combustion engine, wherein a piston surface of each piston of a cylinder has an H-shaped, T-shaped or U-shaped baffle arrangement, respectively.

From the EP 0 639 703 A1 and the EP 0 694 682 A1 In each case a further embodiment of an internal combustion engine with direct injection is known, in which by the formation of the intake ports, a swirl flow is generated in the cylinder chamber. The piston surface here has a pronounced depression with a surrounding squish surface, the depression being arranged eccentrically such that the spark plug located centrally in the combustion chamber and the radially arranged injection valve are located respectively at the edge of the depression. The fuel is injected selectively against the molded for this purpose bowl edge. The piston surface has here so the task to atomize the fuel jet in the first place. The swirling flow has the task of transporting the atomized fuel from the trough to the spark plug.

From the EP 0 558 072 A1 another embodiment of an engine is known in which the shape and arrangement of the inlet channels, a reverse tumble motion of the combustion chamber flow is generated, which is reinforced by a ski-like formation of the piston surface. This piston surface also serves to deflect the injection jet to the spark plug, which is arranged in the center of the cylinder. Injection jet and combustion chamber flow stroke in the same direction over the piston surface. However, the injection jet or the mixture cloud resulting therefrom after deflection on the piston can spread in all directions almost unhindered after hitting the cylinder head wall near the spark plug. An effort to maximize the concentration of the mixture cloud after the deflection of the piston is therefore not recognizable. Further, the jump formed on the piston surface creates a nip under the exhaust valves. While this generates during the compression of the engine shortly before top dead center, a desired additional flow movement. However, this reverses after passing through the dead center, resulting in a tearing apart of the mixture concentration built up during the compression.

The AT 001 257 U1 shows a piston of an internal combustion engine whose piston end face has a Leitrippenanordnung. This should support the formation and maintenance of a tumble flow and prevent or reduce the emergence of secondary flows.

From the JP 10317974 A a piston of an internal combustion engine is known which has a cavity. In this cavity, injected fuel is concentrated by interaction with a tumble flow, bringing it near a spark plug. Further, the piston has a recessed location to reduce the compression ratio.

The publication by Stiebels et al .: Tools for the development of the FSI engine of Volkswagen in Combustion - Current Problems and Modern Approaches (5th Meeting), 13./14.03.2001, pages 483 to 500 - ISSN ISBN 3-931901 Fig. 17-3 shows an internal combustion engine with a piston having a boss. This promotes the formation of a tumble flow.

In the AT 001 974 U1 is an internal combustion engine with flank currents in the combustion chamber described. The formation of the flank flows is achieved by a survey on the combustion chamber side surface of a piston.

All of these arrangements also have the disadvantage that optimum mixture formation does not take place over an entire map range of a four-stroke internal combustion engine.

The present invention is based on the object, an internal combustion engine o. G. To provide art with improved piston, the above-mentioned disadvantages are overcome.

This object is achieved by a four-stroke internal combustion engine o. G. Art solved with the features characterized in claim 1. Advantageous embodiments of the invention are specified in the dependent claims.

For this purpose, it is provided according to the invention that the survey extends in the circumferential direction around a portion of the fuel bowl around, that the air flow forms a Tumbleströmung and two flank flows when entering the air well, the latter being directed in the circumferential direction, that the flank flows in the area the entry of the fuel jet into the fuel well and form a resulting flow into the fuel well into it.

This has the advantage that improved tuning of a double-bore piston geometry with respect to mixture transport and mixture preparation is achieved with a tumble-assisted direct-injection engine. Smoothness and consumption are thus better reproducible for different engines.

In a preferred embodiment, in a cutting plane which intersects the injector, intake port, exhaust passage and center longitudinal axis, the fuel bowl has a maximum depth with respect to a 6mm fuel bowl rim facing the elevation, the air cavity having a maximum depth opposite one of the elevation 3.18 mm air well rim and the air cavity a maximum depth with respect to the elevation of 6.38 mm. Further, a tangent of a Kraftstoffmuldenwandung at one of the collection opposite fuel trough edge with the central longitudinal axis at an angle of 60 degrees, a tangent Luftmuldenwandung at one of the collection opposite Luftmuldenrand with the central longitudinal axis an angle of 62.4 degrees, a tangent of a Kraftstoffmuldenwandung to the Elevation with the central longitudinal axis an angle of 14.1 degrees and a tangent of a Luftmuldenwandung at the elevation with the central longitudinal axis an angle of 52 degrees. In a sectional plane intersecting the injector, intake passage, exhaust passage and center longitudinal axis, a lowest point of the fuel well is 9.5 mm from the central longitudinal axis and the projection is from a lowest point of the fuel run on a circular section having a radius of 18 , 3 mm formed. In a direction perpendicular to the cutting plane, the fuel bowl has a maximum diameter of 36 mm and the air cavity a maximum diameter of 69.1 mm.

Further features, advantages and advantageous embodiments of the invention will become apparent from the dependent claims, and from the following description of the invention with reference to the accompanying drawings. These show in

1 a part of a preferred embodiment of a four-stroke internal combustion engine according to the invention in a schematic sectional view,

2 A preferred embodiment of a piston for a four-stroke internal combustion engine according to the invention in a perspective view,

3 according to the piston 2 in supervision,

4 according to the piston 2 in a sectional view along line AA of 3 wherein the line AA defines a cutting plane which intersects the injector, the intake port, the exhaust port and the central longitudinal axis,

5 according to the piston 2 in a sectional view along line BB of 3 .

6 according to the piston 2 in a sectional view taken along line CC of 3 and

7 a perspective view of the piston according to 2 with a schematic representation of the flow conditions of the air flow.

In the 1 illustrated preferred embodiment of a four-stroke internal combustion engine according to the invention comprises a piston 10 with piston bottom 12 which is in a cylinder 14 can be moved up and down, an inlet channel 16 , an outlet channel 18 and a spark plug 20 , By means of an injection nozzle 22 is fuel in an injection jet 24 in the direction of an injection axis 25 injected. Through the inlet channel 16 fresh air flows as airflow 26 in the form of a tumble flow into a combustion chamber 28 one. In the inlet channel is a separating plate 30 as well as a switching flap 32 arranged, which optionally a part of the inlet channel 16 closes.

In the piston bottom 12 is a fuel well 34 as well as an air well 36 educated. The piston 10 defines a central longitudinal axis 38 , As is immediately apparent 1 results is the injector 22 inlet channel side and below the inlet channel 16 arranged. There may also be two or more inlet and outlet channels 16 . 18 be provided. These are then formed, for example, with separate inlet channel shutdowns. The hollows 33 . 36 as well as the arrangement of the inlet and outlet channels 16 . 18 as well as the injector 22 is inventively chosen such that there is a Tumbleströmung in conjunction with oppositely directed flank currents. The arrangement with several outlet channels 18 is preferably thai.

1 illustrates predetermined flow conditions in a piston according to the invention 10 with double trough 34 . 36 which from a survey 40 be separated from each other. Injection jet 24 and airflow 26 enter from opposite directions in the double trough 34 . 36 a, be from the survey 40 deflected and mixed above this and form in a similar manner an ignitable mixture at the ignition of the spark plug 20 , The geometry of the hollows 34 . 36 and the survey 40 as well as the exact tuning of the elevation flank angle as well as the position of the injection angle of the fuel affect quite decisively the mixture formation.

The 2 to 6 illustrate a preferred embodiment of a geometry of a piston crown 12 for an internal combustion engine according to the invention. The fuel well 34 is about part of its scope from the survey 40 Surrounded by the air well 36 from the fuel well 34 separates. The survey is essentially in the circumferential direction. The essential parameters of the geometry of the design of the piston crown 12 in the form of the double trough 34 . 36 especially results 4 , 4 represents a view in a sectional plane which the injection nozzle 22 , the inlet channel 16 , the outlet channel 18 and the central longitudinal axis 38 cuts. The following parameters result in this section plane:
The fuel well 34 has a maximum depth with respect to one of the survey 40 opposite fuel bowl rim 42 of 6 mm. The air well 36 has a maximum depth with respect to one of the survey 40 opposite air trough edge 44 of 3.18 mm and with respect to the survey 40 of 6.38 mm. The piston bottom 12 defines a level 46 , which are perpendicular to the central longitudinal axis 38 stands (section line AA in 3 ). With this level 46 closes a tangent 48 a Kraftstoffmuldenwandung at one of the survey 40 opposite fuel bowl edge with the central longitudinal axis 38 an angle of 30 degrees, ie with the central longitudinal axis closes this tangent 48 an angle of 60 degrees. A tangent 50 a Luftmuldenwandung at one of the survey 40 opposite air trough edge closes with the plane 46 an angle of 27.6 degrees, ie this tangent 50 closes with the central longitudinal axis 38 an angle of 62.4 degrees. A tangent 52 a Kraftstoffmuldenwandung at the survey 40 closes with the central longitudinal axis 38 an angle of 14.1 degrees. A tangent 54 a Luftmuldenwandung at the survey 40 closes with the plane 46 an angle of 38 degrees, ie this tangent 54 closes with the central longitudinal axis 38 an angle of 52 degrees. A deepest point of the fuel well 34 is at a distance 56 of 9.5 mm from the central longitudinal axis 38 remotely trained. The assessment 40 is starting from the lowest point of the fuel trough 34 on a circular section with a radius 58 formed by 18.3 mm. The fuel well 34 has a maximum diameter in a direction perpendicular to the cutting plane 60 from 36 mm to ( 3 ). The air well 36 has a maximum diameter in a direction perpendicular to the cutting plane which intersects the injector, the intake port, the exhaust port and the central longitudinal axis 62 of 69.1 mm. By training the increase 40 is the air well 36 Banana-shaped or in the form of a partial ring and the fuel bowl 34 partially formed surrounding.

This special geometric design of the piston crown 12 or the hollows 34 . 36 with increase 40 Optimized for fuel consumption, emission and running stability. Furthermore, one turns out 7 apparent, particularly advantageous flow combination. When the air flow hits the air intake 36 the air flow becomes a tumble flow 64 and two flank currents 68 divided up. The flank currents 68 Run substantially in the circumferential direction of the air well 36 following in the opposite direction and meet at the entry point of the fuel jet in the fuel tank on each other, so that one in the fuel tank 34 directed resulting flow 70 results. This resulting flow 70 supports the transport of the fuel mass to the spark plug and causes by the additional turbulence a more favorable treatment of the rich in this area mixture. The advantage of the so constructed secondary air duct in the fuel tank 34 is thus an improvement in terms of consumption, emission and running stability. Furthermore, the illustrated geometry of the piston crown forms a minimized piston surface, so that a low heat loss ensures a better burning of the flame in the combustion chamber. This minimized piston surface therefore has a favorable influence on consumption and emissions.

In particular, the design of the geometry of the fuel well is essential 34 , like out 4 seen. Starting from the survey 40 in the direction of the fuel bowl rim 42 has the fuel well 34 in cross-section a radius 72 of 10.75 mm and then a radius 74 of 32.5 mm.

Claims (12)

Four-stroke internal combustion engine with spark ignition, direct injection of a fuel with an injection nozzle ( 22 ) by means of an injection jet ( 24 ) in a combustion chamber ( 28 ), at least one air flow ( 26 ) in the combustion chamber conducting inlet channel ( 16 ) with inlet valve, at least one outlet channel ( 18 ) with exhaust valve, wherein inlet valve and exhaust valve on opposite sides of the combustion chamber ( 28 ) are arranged and the injection nozzle ( 22 ) is arranged inlet valve side, and a piston ( 10 ), which has a piston head ( 12 ) as well as in the direction of movement of the piston ( 10 ) extending central longitudinal axis ( 38 ), wherein the piston head ( 12 ) a fuel trough ( 34 ) and a flow or air trough ( 36 ) of a survey ( 40 ) of the piston crown ( 12 ) separated from each other, which a highest point of the piston crown ( 12 ), wherein the injection jet ( 24 ) in the fuel well ( 34 ) in one of the surveys ( 40 ) opposite side and the air flow ( 26 ) in the opposite direction with respect to the injection jet ( 24 ) in the air well ( 36 ) in one of the surveys ( 40 ) opposite side, characterized in that the survey ( 40 ) in the circumferential direction around a part of the fuel trough ( 34 ) that the air flow ( 26 ) when entering the air well ( 36 ) a tumble flow ( 64 ) as well as two flank currents ( 68 ), the latter being directed in the circumferential direction in such a way that the flank flows ( 68 ) in the region of the entry of the fuel jet ( 24 ) in the fuel well ( 34 ) and a resulting flow ( 70 ) in the fuel well ( 34 ). Four-stroke internal combustion engine according to claim 1, characterized in that in a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ) cuts, the fuel well ( 34 ) a maximum depth with respect to one of the survey ( 40 ) opposite fuel trough edge ( 42 ) of 6 mm. Four-stroke internal combustion engine according to claim 1 or 2, characterized in that in a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ) cuts, the air well ( 36 ) a maximum depth with respect to one of the survey ( 40 ) opposite air trough edge ( 44 ) of 3.18 mm. Four-stroke internal combustion engine according to at least one of the preceding claims, characterized in that in a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ) cuts, the air well ( 36 ) a maximum depth with respect to the survey ( 40 ) of 6.38 mm. Four-stroke internal combustion engine according to at least one of the preceding claims, characterized in that in a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ) intersects a tangent ( 48 ) a Kraftstoffmuldenwandung at one of the collection opposite fuel trough edge ( 42 ) with the central longitudinal axis ( 38 ) includes an angle of 60 degrees. Four-stroke internal combustion engine according to at least one of the preceding claims, characterized in that in a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ) intersects a tangent ( 50 ) of a Luftmuldenwandung at one of the survey ( 40 ) opposite air trough edge ( 44 ) with the central longitudinal axis ( 38 ) includes an angle of 62.4 degrees. Four-stroke internal combustion engine according to at least one of the preceding claims, characterized in that in a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ) intersects a tangent ( 52 ) a Kraftstoffmuldenwandung at the survey ( 40 ) with the central longitudinal axis ( 38 ) includes an angle of 14.1 degrees. Four-stroke internal combustion engine according to at least one of the preceding claims, characterized in that in a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ) intersects a tangent ( 54 ) a Luftmuldenwandung at the survey ( 40 ) with the central longitudinal axis ( 38 ) includes an angle of 52 degrees. Four-stroke internal combustion engine according to at least one of the preceding claims, characterized in that in a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ), a lowest point of the fuel trough ( 34 ) from the central longitudinal axis ( 38 ) 9.5 mm away. Four-stroke internal combustion engine according to at least one of the preceding claims, characterized in that in a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ), the survey ( 40 ) starting from a lowest point of the fuel trough ( 34 ) on a circular section with a radius ( 58 ) of 18.3 mm is formed. Four-stroke internal combustion engine according to at least one of the preceding claims, characterized in that the fuel trough ( 34 ) in a direction perpendicular to a cutting plane, which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ) cuts, a maximum diameter ( 60 ) of 36 mm. Four-stroke internal combustion engine according to at least one of the preceding claims, characterized in that the air intake ( 36 ) in a direction perpendicular to a sectional plane which the injection nozzle ( 22 ), the inlet channel ( 16 ), the outlet channel ( 18 ) and the central longitudinal axis ( 38 ) cuts, a maximum diameter ( 62 ) of 69.1 mm.

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