EP3012445A1 - Control device for a combustion engine - Google Patents

Abstract

Control devices for internal combustion engines having an intake passage (12), an exhaust gas recirculation passage (16) opening into the intake passage (12), a housing (10) in which the intake passage (12) and at least one orifice (14) of the exhaust gas recirculation passage (16) are formed, serving as a rotation axis (38) shaft (36) disposed in the housing (10) with respect to the air flow upstream of the mouth (14) of the exhaust gas recirculation passage (16) and outside the flow cross section and perpendicular to the central axes (20, 34 ) of the intake passage (12) and the exhaust gas recirculation passage (16), a control body (42) eccentrically fixed to the shaft (36) and via which the control body (42) is rotatable in the intake passage (12), a first one Valve seat (50) on which the control body (42) rests in a first end position in which the control body (42) closes the intake passage (12) and a second valve seat (72) on which the control body (42) in a second E Establishment is present, in which the control body (42) closes the exhaust gas recirculation passage (16) are known. However, these have the disadvantage that no appreciable changes in the amount of recirculated exhaust gas are recorded over a wide control range of the control body. In order to solve this problem, the invention proposes that a plane (74) spanned by the first valve seat (50) encloses an angle of 70 ° to 80 ° with respect to the center axis of the intake duct (12).

Description

The invention relates to a control device for an internal combustion engine having an intake passage, an exhaust gas recirculation passage, which opens into the intake passage, a housing in which the intake passage and at least one mouth of the exhaust gas recirculation passage are formed, serving as an axis of rotation upstream in the housing with respect to the air flow is arranged at the mouth of the exhaust gas recirculation passage and outside the flow cross section and perpendicular to the center axes of the intake passage and the exhaust gas recirculation passage, a control body eccentrically fixed to the shaft and via which the control body is rotatable in the intake passage, a first valve seat on which the control body rests in a first end position, in which the control body closes the intake passage and a second valve seat against which the control body rests in a second end position in which the control body closes the exhaust gas recirculation passage.

Control devices are used in internal combustion engines to regulate exhaust or air quantities that are to be removed or supplied to combustion. Combinations of these control valves, in which two valve bodies are actuated via a common actuating device, are known. In particular, combinations of an exhaust gas recirculation valve with a throttle valve have been disclosed. In these embodiments, the exhaust gas recirculation channel opens immediately downstream of serving as a throttle valve in the air intake passage. When desired increase in the exhaust gas recirculation rate is then with opening the Exhaust gas recirculation valve to the same extent the throttle valve closed, which has an increase in the pressure gradient in the exhaust gas recirculation channel result, whereby the proportion of exhaust gas compared to the intake air quantity is increased. Such an arrangement is for example in the DE 27 03 687 A1 disclosed.

From the DE 10 2012 101 851 B4 is also known such a control device, are operated in the two parallel flaps on a common rotary shaft, so that with rotation of the two flaps, the first flap away from the valve seat of the air intake while the second flap the valve seat of the exhaust gas recirculation channel, perpendicular to the valve seat is disposed of the air intake duct, approaches until the air intake passage is fully opened and the exhaust gas recirculation passage is completely closed. Both for the second flap, which controls the exhaust gas recirculation channel, and for the first flap, which dominates the air intake channel, the valve seats are each designed as circumferential stop members, against which the flaps rest circumferentially in their position closing the respective channel. The rotary shaft is disposed on a housing wall between the mouth of the exhaust gas recirculation passage and the valve seat in the air intake passage, so that the flow is not affected by the shaft.

Although a good regulation of the exhaust gas recirculation system is achieved by minimizing the costs and components by these known arrangements, it has been found that in a central region of the opening angle of the two flaps over a control range of about 40% of Gesamtverstellweges virtually no regulation takes place and both the air mass flow as well as the recirculated exhaust gas flow remain essentially unchanged. Throttling the air intake duct thus has almost no influence on the traceable exhaust gas quantity.

As a result, the regulation reacts sluggishly in this setting range, and desired set-up times can sometimes not be maintained.

It is therefore an object of the invention to provide a control device for an internal combustion engine, with the most accurate and fast controllability of the air and exhaust gas flow over the largest possible proportion of the entire control range is made possible. For this purpose, a change in the gas flows should also be achieved in the middle control range.

This object is achieved by a control device for an internal combustion engine with the features of the main claim.

Due to the fact that a plane spanned by the first valve seat encloses an angle of 70 ° to 80 ° with respect to the center axis of the intake duct, the rotational angle range in which only a small volume flow change of the exhaust gas flow and the air flow can be detected can be reduced to approximately 20% of the control range , This allows a faster control of the recirculated exhaust gas amount and resulting pollutant emissions can be reduced.

Preferably, a plane spanned by the second valve seat is arranged parallel to the central axis of the intake passage and encloses an angle of 70 ° to 80 ° to the plane spanned by the first valve seat. Thus, the rotational angle range to be traveled is also about 70 ° to 80 °. This means that the adjustment range is reduced in comparison to known designs, but without the rotation angle ranges, in which anyway a good controllability present, would be reduced. In these areas, the slope of the control curve remains essentially unchanged.

In a preferred embodiment, the control body has a first flap cooperating with the first valve seat and a second flap cooperating with the second valve seat, the first flap being eccentrically secured to the shaft and the second flap being attached to the first flap is. Due to the design with two flaps, the arrangement of the valve seats to each other can be done with significantly inaccurate tolerances. Furthermore, the control body can be completely unscrewed from the flow-through area of the air intake duct.

It is advantageous if the second flap is arranged on a perpendicular to the two flaps extending holding axis which is fixedly connected to the first flap, wherein the second flap is axially loaded by a spring which surrounds the holding axis against a stop and the opening in the second flap for receiving the holding axis has a slightly larger diameter than the holding axis, in the portion where the second flap is arranged. This has the consequence that the second flap can tilt in comparison to the first flap and compared to the shaft on the holding axis and is thus pressed over the spring always flat on the second valve seat, whereby existing leaks are minimized in the closed state of the exhaust gas recirculation passage.

In a further development of the invention, the second flap extends parallel to the first flap. This design is particularly easy to produce. Furthermore, especially in the consequent vertical arrangement of the central axis of the air intake duct to the central axis of the exhaust gas recirculation channel particularly good, largely linear control curves can be achieved over a wide range of rotation angles.

Preferably, the first valve seat is formed by an axial end of a first housing part of the housing, which is inserted into a second housing part of the housing, on which the mouth of the exhaust gas recirculation passage is formed, wherein the first housing part is connected via a flange to the second housing part. Accordingly, can be dispensed with the formation of a valve seat, which must be generated mechanically in the interior of the housing. Also omitted complicated molds for producing a full-acting valve seat. The housing can thus be inexpensively manufactured and assembled with little effort.

In a further advantageous embodiment, the first housing part has a smaller circumference than the second housing part and the control body immersed in its the exhaust gas recirculation passage closing second end position in a recess in the second housing part, so that the flow area of the first housing part is fully opened. This has the consequence that with complete opening of the air intake duct no flow resistance is present and thus large amounts of air can be sucked. Even in the partially open position of the control body only smooth flow surfaces are realized without additional fittings and consequent flow resistance. This results largely linear control curves for the existing gas mass flows.

It is thus provided a control device with which both the air mass flow in the intake passage and the exhaust gas mass flow of the exhaust gas recirculation loop over a very large adjustment angle range can be controlled quickly and accurately along a largely linear characteristic. The area in which only slight mass flow changes are achieved when the shaft is actuated is significantly reduced. Thus, the controllability of the recirculated exhaust gas mass flow is significantly improved.

An embodiment of a control device according to the invention is shown in the figures and will be described below.

The FIG. 1 shows a side view of a control device according to the invention with a control body in a first end position in a sectional view.

The FIG. 2 shows a side view of the control device according to the invention FIG. 1 with a rule body in a central position in a sectional representation.

The FIG. 3 shows a side view of the control device according to the invention FIG. 1 with a control body in a second end position in a sectional view.

The FIG. 4 shows a characteristic of the resulting control curve of the control device according to the invention.

The control device according to the invention consists of a housing 10 which limits an intake passage 12 and in which an opening 14 of an exhaust gas recirculation passage 16 is formed. The intake passage 12 extends substantially in a straight line, while the exhaust gas recirculation passage 16 opens perpendicular to the intake passage 12 in this.

The housing 10 consists of a first substantially tubular housing part 18, whose downstream end is inclined is formed and includes an angle α of about 75 ° to a central axis 20 of the intake passage 12. This first housing part 18 is arranged in the interior of a second housing part 22, or is inserted into the second housing part 22 until a flange 24, via which the first housing part 18 is fastened by means of screws 26 on the second housing part 22. The second housing part 22 has an opening 28 which is arranged in the flow direction at a short distance behind the oblique end of the first housing part 18 and which serves as a receptacle for a third housing part 30, which forms the mouth 14 of the exhaust gas recirculation passage 16, the central axis 34 perpendicular is arranged to the central axis 20 of the intake passage 12.

In the housing 10, a shaft 36 is rotatably mounted, which can be actuated via a non-visible actuator. The axis of rotation 38 of this shaft 36 is perpendicular to the central axes 20, 34 and is located between the shaft 36 to the downstream mouth 14 of the exhaust gas recirculation passage 16 and the axial end of the first housing part 18 and immediately downstream of the first housing part 18. The flow cross-section of the first housing part 18 is smaller than that of the second housing part 22 of the intake passage 12, wherein the first housing part 18 is secured to the second housing part 22, that in the region of the mouth of the exhaust gas recirculation passage 16 formed recess 40 is disposed outside of the flow cross-section, in which the shaft 36 the second housing part 22 is arranged penetrating.

At this eccentrically arranged in the intake passage 12 shaft 36, a control body 42 is fixed, which consists of a first flap 44 and a fortified via a holding axis 46 on the first flap 44 second flap 48. The first flap 44 extends straight from the shaft 36 and dominates the flow area of the Intake passage 12. For this purpose, the first flap 44 cooperates with the axial end of the first housing part 18, which serves as a first valve seat 50 on which the flap 44 in the intake passage 12 occluding state, as in FIG. 1 is shown, is applied.

In the first flap 44, a bore 52 is formed in the central region, in which the holding axis 46 is fixed. This extends to the first housing part 18 opposite side perpendicular to the first flap 44. The holding axis 46 has a plurality of axially successive sections of different diameter, of which the first portion 54, the bore 52 penetrates and is formed in the rear region to produce a rivet and the second, larger portion 56 rests flat against the flap 44. A third axial section 58 has a smaller diameter than the second section 56, followed by a fourth section 60, again of reduced diameter. On this fourth section 60, the second flap 48 is arranged, which has a central opening 62 through which the support shaft 46 penetrates, wherein the diameter of this opening 62 is slightly larger than the diameter of the fourth portion 60, whereby the second flap 48 on the Halteachse 46 can be easily tilted. A spring 64 also surrounds the fourth section 60 and presses the flap 48 against a spherical shoulder serving as a stop 65 between the third section 58 and the fourth section 60. The abutment for this spring 64 is a disk 66 which is mounted on a fifth section 68 the retaining axis 46 is arranged, where it is fixed by forming, a disc 66 penetrating following portion 70 of the support shaft 46. This attachment of the second flap 48 results in that upon rotation of the shaft 36 in a second end position, as in FIG. 3 is shown, in which the second flap 48 rests on the second valve seat 72 serving as the mouth 14 of the exhaust gas recirculation passage 16, a complete tight closure of the exhaust gas recirculation passage 16 takes place because the flap 48 can adjust its position by the possible tilting movement to the position of the second valve seat 72, even if it is not formed completely parallel to the central axis 20 of the intake passage 12.

It follows from this that between a plane 74, which is spanned by the first valve seat 50 and a second plane 76, which is spanned by the second valve seat 72, an angle of 75 ° is included, which simultaneously the total rotation angle of the shaft 36 and the Regulating body 42 between the two end positions corresponds. By this measure, to reduce the rotation angle in comparison to known embodiments in such a way, it is achieved that over approximately 80% of the total rotation angle, an approximately linear regulation of the recirculated exhaust gas mass flow and the air flow is achieved, as in FIG. 4 can be seen. Only in the central rotation angle range 80, for example between approximately 25 ° and 40 °, is it possible to detect almost no change in the exhaust gas mass flow 82 and the air intake flow 84. In the other areas, however, in particular the exhaust gas flow is almost linearly adjustable to the rotation angle of the control body 42. In versions with valve seats, which are arranged at 90 ° to each other, the proportion in which there are virtually no volume flow changes, about 40% of the controlled system, which corresponds to a rotation angle of about 35 °. Thus, a significant improvement in the controllability is achieved.

The described control device is thus suitable for the very exact metering of an exhaust gas mass flow into an air mass flow and for the exact control of the air mass flow with only one actuator. The production of this control device is inexpensive and easy to install.

It should be understood that the scope of the present application is not limited to the embodiment described. In particular, the position of the valve seats in the range between 70 ° and 80 ° can be selected to achieve appropriate results. Also, various modifications with respect to the assembly and the formation of the housing parts and the two flaps are conceivable. It should also be clear that various characteristics can be achieved by appropriate shaping of the valve body and the surrounding channel walls.

Claims (7)

Control device for an internal combustion engine with an intake duct (12),
an exhaust gas recirculation passage (16) opening into the intake passage (12),
a housing (10) in which the intake passage (12) and at least one orifice (14) of the exhaust gas recirculation passage (16) are formed, a shaft (36) serving as an axis of rotation (38) in the housing (10) upstream of the air flow the orifice (14) of the exhaust gas recirculation passage (16) is arranged outside the flow cross section and is arranged perpendicular to the center axes (20, 34) of the intake passage (12) and the exhaust gas recirculation passage (16),
a control body (42) which is eccentrically mounted on the shaft (36) and over which the control body (42) in the intake passage (12) is rotatable,
a first valve seat (50) against which the control body (42) rests in a first end position in which the control body (42) closes the intake duct (12),
a second valve seat (72) against which the control body (42) rests in a second end position in which the control body (42) closes the exhaust gas recirculation passage (16),
characterized in that
a plane defined by the first valve seat (50) plane (74) to the central axis of the intake passage (12) forms an angle of 70 ° to 80 °. Control device for an internal combustion engine according to claim 1,
characterized in that
a plane (76) spanned by the second valve seat (72) is arranged parallel to the central axis (20) of the intake passage (12) and encloses an angle of 70 ° to 80 ° with the plane (74) spanned by the first valve seat (50). Control device for an internal combustion engine according to one of claims 1 or 2,
characterized in that
the regulating body (42) has a first flap (44) cooperating with the first valve seat (50) and having a second flap (48) cooperating with the second valve seat (72), the first flap (44) being eccentric the shaft (36) is fixed and the second flap (48) is attached to the first flap (44). Control device for an internal combustion engine according to claim 3,
characterized in that
the second flap (48) is disposed on a support axis (46) extending perpendicularly to the two flaps (44, 48) fixedly connected to the first flap (44), the second flap (48) being via a spring (64), which surrounds the holding axis (46), is axially loaded against a stop (65) and the opening (62) in the second flap (48) for receiving the holding axis (46) has a slightly larger diameter than the holding axis ( 46), in the portion (60) on which the second flap (48) is arranged. Control device for an internal combustion engine according to one of claims 3 or 4,
characterized in that
the second flap (48) extends parallel to the first flap (44). Control device for an internal combustion engine according to one of the preceding claims,
characterized in that
the first valve seat (50) is formed by an axial end of a first housing part (18) of the housing (10), which is inserted into a second housing part (22) of the housing (10), at which the mouth (14) of the exhaust gas recirculation channel (10). 16) is formed, wherein the first housing part (18) via a flange (24) with the second housing part (22) is connected. Control device for an internal combustion engine according to claim 6,
characterized in that
the first housing part (18) has a smaller circumference than the second housing part (22) and the control body (42) in its exhaust gas return passage (16) closing the second end position in a recess (40) in the second housing part (22) is immersed, so that the Throughflow cross section of the first housing part (18) is fully open.

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