DE102017200221A1 - Exhaust manifold for an internal combustion engine - Google Patents

Abstract

Exhaust manifold (5) for an internal combustion engine (2) comprising at least two separate exhaust gas flows (6, 7), at least one receiving opening (8) for a flow control device (9), wherein at least one flow path (10) by means of the flow control device (9) between different of the at least two exhaust gas flows (6, 7) can be opened or closed, and wherein the receiving opening (8) on an outer side (12) of the exhaust manifold (5) is arranged.

Description

The invention relates to an exhaust manifold for an internal combustion engine.

There are internal combustion engines are known, whose cylinders are connected to a plurality of separate exhaust gas lines. In such internal combustion engines, it is also known, depending on the operating state, to connect the separate exhaust gas strands at least temporarily with each other. This can in particular have an influence on a function of an exhaust gas turbocharger. In known devices for opening and closing the connection between separate exhaust strands assembly and maintenance often require a considerable amount of work. Even with a defect of the devices due to the design regularly replace the entire exhaust gas turbocharger, which can result in significant costs.

On this basis, it is the object of the present invention to continue to solve or at least reduce the technical problems described in connection with the prior art. In particular, an exhaust manifold for an internal combustion engine will be presented, which can enable a particularly simple and cost-effective installation and maintenance of the internal combustion engine.

This object is achieved with an exhaust manifold according to the features of claim 1. Further advantageous embodiments of the exhaust manifold are given in the dependent formulated claims. The features listed individually in the patent claims can be combined with one another in any technologically meaningful manner and can be supplemented by explanatory facts from the description, wherein further embodiments of the invention are shown.

• - mindestens zwei voneinander getrennte Abgasfluten,
• - mindestens eine Aufnahmeöffnung für eine Strömungsleitvorrichtung, wobei mittels der Strömungsleitvorrichtung mindestens ein Strömungsweg zwischen verschiedenen der mindestens zwei Abgasfluten geöffnet oder geschlossen werden kann, und wobei die Aufnahmeöffnung an einer Außenseite des Abgaskrümmers angeordnet ist.

According to the invention, an exhaust manifold for an internal combustion engine is presented. The exhaust manifold comprises at least:

• at least two separate exhaust gas flows,
• at least one receiving opening for a flow-guiding device, wherein at least one flow path between different ones of the at least two exhaust-gas floods can be opened or closed by means of the flow-guiding device, and wherein the receiving opening is arranged on an outer side of the exhaust manifold.

The internal combustion engine may be suitable in particular for a motor vehicle. The internal combustion engine preferably has a plurality of cylinders as combustion chambers, in which fuel can be burned with air. Preferably, air from the environment of the internal combustion engine can be introduced via an intake pipe into the combustion chambers. In this case, a compression of the air via a turbocharger can preferably take place. The turbocharger is preferably driven via the exhaust gas of the internal combustion engine (exhaust gas turbocharger). For this purpose, the turbocharger preferably has an exhaust area, which is integrated in an exhaust system of the internal combustion engine and within which the exhaust gas can cause a drive of the turbocharger. Furthermore, the turbocharger preferably has a compression region, which is integrated into the intake manifold of the internal combustion engine and within which air can be compressed. The exhaust region of the turbocharger preferably comprises at least one exhaust gas turbine, which can be driven by the exhaust gas. A resulting rotational movement of the exhaust gas turbine is preferably transmitted (for example by a drive shaft) to a compression device in the compression region of the turbocharger. By the compression device, the air can be compressed in the compression area.

Preferably, the internal combustion engine comprises two (or more) groups of cylinders, wherein cylinders of different groups are connected to different ones of the exhaust gas flows. The internal combustion engine is preferably set up in such a way that exhaust gas is discharged from cylinders of a group at times which are as far apart as possible. For example, in a four-cylinder internal combustion engine, it is preferable that the cylinders (two in this case) of a group are out of phase with each other by 360 degrees. This means, for example, that air is sucked into one of the two cylinders of the group (intake stroke), while in the other cylinder of the group an ignited fuel-air mixture expands and performs work (power stroke).

Furthermore, it is preferred that exhaust gas is discharged from the different groups at as far apart time points. For example, in a four-cylinder internal combustion engine, it is preferable that the groups (two in this case) are out of phase with each other by 180 degrees.

The turbocharger can be powered by either a boost charge or a jam charge. In the case of supercharging, the turbocharger is driven by so-called pre-impulse blows. If the exhaust valve of a cylinder is opened, the exhaust gas exits the cylinder initially under great pressure and thus abruptly. This is called a Vorlassstoß. Are at one Combustion engine with four cylinders, the cylinders of a group phase-shifted by 360 ° to each other and the groups phase-shifted by 180 ° to each other, so meet Vorlassstöße at equal intervals on the exhaust gas turbine, the Vorlassstöße originate from the two groups alternately. In this way, the turbocharger can be particularly continuously driven by shock charging. About the supercharging the turbocharger can be driven in particular at low speeds of the internal combustion engine. In this case, successive Vorlassstöße are temporally spaced from each other. It is preferred that the exhaust gas flows are completely separated from each other. This allows the energy of the Vorlassstöße be exploited particularly well for the shock charge.

By contrast, the turbocharger can be driven in particular at high rotational speeds of the internal combustion engine via the accumulation charge. In this case, particularly large exhaust gas mass flows can occur. Due to the fast successive Vorlassstöße results in a total of a pulsating flow, which breaks off at any time completely. If such a large exhaust gas mass flow were conducted through an exhaust gas flow alone, a large flow velocity would set, so that a particularly large flow resistance would result. A pressure spike by a Vorlassstoß could slow down only slowly. Through the connection between the exhaust gas flows, a flow cross-section available for a pre-discharge joint can be increased. The pre-discharge shock can therefore spread with open connection between the exhaust gas flows with a particularly low flow resistance. In addition, with the connection between the exhaust gas flows open, the exhaust gas turbine can be fully pressurized (i.e., over both exhaust gas flows) with the pre-discharge shock. Thus, the energy of the Vorlassstoßes can be used particularly efficiently for driving the turbocharger.

It is therefore preferred that the exhaust gas flows are optionally completely separated or interconnected depending on the operating state of the internal combustion engine. Thus, the turbocharger can be adapted to a respective prevailing Aufladungsart, so that a corresponding exhaust gas flow can be particularly efficiently exploited to drive the turbocharger.

In particular, the described exhaust manifold may allow exhaust of the cylinders of different groups to be selectively directed to separate or at least partially connected flow paths to the turbocharger (and in particular to the exhaust turbine). The exhaust manifold preferably includes an inlet port for each of the cylinders. If more than one exhaust manifold is provided in an internal combustion engine, each of the exhaust manifolds preferably includes an inlet port for at least a portion of the cylinders. To the inlet ports of cylinders of a group are preferably connected lines that converge within the exhaust manifold. In addition, the exhaust manifold preferably has an outlet opening for each group of cylinders. The entirety of conduits between the intake ports of cylinders of a group and the respective exhaust port preferably forms an exhaust gas surge.

The exhaust gas leaving the outlets of the exhaust manifold is preferably directed to the exhaust region of the turbocharger. So that the exhaust gas from the cylinders of different groups can in any case flow separately from one another to the exhaust gas turbine, the exhaust gas flows of the exhaust manifold are preferably fundamentally separate from one another.

The connection between different exhaust gas flows can preferably be released and blocked in the described exhaust manifold via the flow guide. For this purpose, the exhaust gas flows are preferably designed such that when the flow guide device is mounted, the flow path between the various of the at least two exhaust gas flows can be opened or closed. Preferably, a Strömungsleitvorrichtung is mounted on the exhaust manifold, which can be brought at least in two positions. In a first position of the flow-guiding device, the flow path between the various of the at least two exhaust-gas flows is preferably opened. In a second position of the flow-guiding device, this flow path is preferably closed. It is also preferred that no further (intermediate) positions of the flow guiding device are provided in addition to these two positions. Alternatively, however, it is preferred in one embodiment, in any number of intermediate positions between the first and second position can be brought.

The exhaust manifold and in particular the receiving opening and the exhaust gas flows are preferably designed such that in any case two of the exhaust gas passages are accessible through the receiving opening. This can for example be realized in that the receiving opening is arranged at a position of the exhaust manifold, are separated at the two exhaust gas flows only by a partition. For example, in this case, an opening in the partition wall may be opened or closed by the flow guiding device. Also, the receiving opening may for example be formed perpendicular to the partition, so that the receiving opening is divided by the partition. In that case, the flow path between the Exhaust gas flows through the flow guide.

The described inlet openings and outlet openings of the exhaust manifold are not a receiving opening in the sense of the definition of a receiving opening used here. In particular, the inlet openings and the outlet openings are preferably each connected to only one exhaust gas flow. Therefore, by mounting a flow guide on one of the inlet openings or on one of the outlet openings (which is not provided in the exhaust manifold described here), no flow path between different exhaust gas flows could be formed.

The flow guide can be mounted from the outside to the exhaust manifold. In this way, the flow-guiding device can be particularly well accessible, in particular for installation and / or maintenance. In case of a defect of the flow guiding device (for example due to wear), the flow guiding device can be easily exchanged. It can be done without disassembly of the exhaust manifold and / or the turbocharger. In particular, in the event of a defect of the flow-guiding device, the (entire) turbocharger need not be replaced. As a result, a considerable work and expense can be avoided.

Preferably, the Strömungsleitklappe be adjusted from outside the exhaust manifold. For this purpose, for example, an electric motor or a mechanical and / or pneumatic adjusting device may be provided inside the flow guiding device and / or outside the exhaust manifold. The adjusting device can preferably be controlled via a control unit according to an operating situation of the internal combustion engine.

In a preferred embodiment of the exhaust manifold, the receiving opening can be closed by receiving the flow-guiding device.

For forming the flow path between different exhaust gas flows, it is preferred that in any case two of the exhaust gas flows are accessible through the intake opening. If the internal combustion engine were operated without a flow guide device mounted on the exhaust manifold (which is not provided in the exhaust manifold described here), then exhaust gas (from both of these, in any case, two exhaust gas flows) of the intake opening could escape into the environment. Also, to avoid such leakage of exhaust gas, the receiving opening may preferably be closed by receiving the flow guide. If the flow guiding device is mounted, preferably no exhaust gas can escape from the receiving opening into the environment. The exhaust manifold preferably has a sealing surface surrounding the receiving opening with a seal, so that the receiving opening can be closed in a gastight manner with the flow-guiding device.

In a further preferred embodiment of the exhaust manifold, a connecting chamber adjoins the receiving opening within the exhaust manifold, wherein the connecting chamber is fluidly connected to the at least two exhaust gas flows.

For example, the connection chamber may form part of a first one of the exhaust gas flows, wherein a second one of the exhaust gas flows is separated from the connection chamber by a partition wall. In that case, it is preferable that an opening is provided in the partition wall which can be opened or closed by the flow guiding device. Also, the connection chamber may be partitioned by a partition wall into different regions, each of the regions being part of another exhaust gas flow. Also in the case, it is preferable that an opening is provided in the partition wall which can be opened or closed by the flow guide.

Preferably, the flow guide device can be mounted to the exhaust manifold so that the flow guide can engage in opening and closing the opening through the receiving opening into the connecting chamber.

In a further preferred embodiment of the exhaust manifold, a flow-guiding device is arranged at the receiving opening, wherein the flow-guiding device comprises a flow-guiding flap, by means of which an opening in a first of the exhaust-gas flows can be closed, whereby the first exhaust-gas flow can be separated from a second exhaust-gas flow.

In this embodiment, the exhaust manifold is preferably in the assembled state, d. H. in particular with mounted flow guide. The opening in the first exhaust gas flow is preferably formed in a partition wall between the first exhaust gas flow and the second exhaust gas flow. The opening and closing of the opening can preferably take place via the flow-guiding flap. In the first position of the flow-guiding device, the flow-guiding flap is preferably arranged such that the flow-guiding flap does not obstruct the opening. In the second position of the flow-guiding device, the flow-guiding flap is preferably arranged such that the flow-guiding flap bears against the dividing wall and obstructs the opening.

In a further preferred embodiment of the exhaust manifold, the Strömungsleitklappe is adapted to be adjusted in the connecting chamber and thereby to close or open the opening in the first exhaust gas flow.

In particular, the flow-guiding device, the flow-guiding flap and the connecting chamber are preferably designed in such a way that the flow-guiding flap does not protrude into the connecting chamber in the first position. In that case, in the first position, the flow guiding device closes only the receiving opening towards the surroundings of the exhaust manifold. In the second position, the flow guide flap can protrude into the connecting chamber and close the opening there.

In a further preferred embodiment of the exhaust manifold, the flow-guiding flap is mounted in a cover of the flow-guiding device.

The cover of the flow guiding device is preferably designed to close the receiving opening to the surroundings of the exhaust manifold. The flow-guiding flap is preferably mounted in the cover such that the flow-guiding flap does not project into the connecting chamber in the first position of the flow-guiding device.

In yet another preferred embodiment of the exhaust manifold, the flow guide is verschraubbar with the outside of the exhaust manifold.

In this embodiment, in particular, a particularly simple assembly and / or disassembly (for example, for maintenance) of the flow guiding device take place.

As a further aspect of the invention, a motor vehicle is presented. The motor vehicle comprises at least one exhaust manifold, which is designed as described. The particular advantages and design features described above for the exhaust manifold are applicable to the motor vehicle described and transferable.

• 1: ein Kraftfahrzeug mit einer Verbrennungskraftmaschine und einem Abgaskrümmer,
• 2: eine perspektivische Darstellung des Abgaskrümmers aus 1, und
• 3: eine Schnittdarstellung des Abgaskrümmers aus den 1 und 2.

The invention and the technical environment will be explained in more detail with reference to FIGS. The figures show particularly preferred embodiments, to which the invention is not limited. In particular, it should be noted that the figures and in particular the illustrated proportions are only schematic. Show it:

• 1 a motor vehicle with an internal combustion engine and an exhaust manifold,
• 2 : A perspective view of the exhaust manifold 1 , and
• 3 : A sectional view of the exhaust manifold from the 1 and 2 ,

1 shows a motor vehicle 1 having an internal combustion engine 2 connected to a turbocharger 16 connected to compress air. The turbocharger 16 can with exhaust gas of the internal combustion engine 2 are driven. The compressed air from the turbocharger 16 may be for combustion in the internal combustion engine 2 be used.

The turbocharger 16 includes a compression area 18 and an exhaust area 19 , Via an intake pipe 17 can air from the environment of the motor vehicle 1 be sucked in and in the compression area 18 of the turbocharger 16 via a compacting device 20 be compacted. From the compression area 18 of the turbocharger 16 The compressed air can continue through the intake pipe 17 in cylinders 3 a first group and in cylinders 4 a second group of the internal combustion engine 2 are introduced, which the combustion chambers of the internal combustion engine 2 form. Cylinders of a group are operated at particularly spaced intervals in time. The groups undergo staggered cycles.

For discharging exhaust gas from the internal combustion engine 2 an exhaust manifold 5 is provided. Exhaust from the cylinders 3 The first group may have a first exhaust gas flow 6 the exhaust manifold 5 from first inlet openings 23 to a first outlet opening 25 stream. Exhaust from the cylinders 4 the second group can have a second exhaust gas flow 7 the exhaust manifold 5 from second inlet openings 24 to a second outlet opening 26 stream. The first exhaust tide 6 and the second exhaust tide 7 are basically separated from each other, wherein by means of a flow guide 9 a flow path 10 between the first exhaust flow 6 and the second exhaust gas flow 7 can be opened or closed.

After exiting the first outlet opening 25 and the second outlet opening 26 can the exhaust gas in the exhaust area 19 of the turbocharger 16 be introduced where there is an exhaust gas turbine 21 can drive. A generated thereby rotational movement of the exhaust gas turbine 21 can be via a drive shaft 22 on the compaction device 20 in the compression area 18 be transmitted. After passing the exhaust area 19 of the turbocharger 16 can the exhaust gas (preferably after an exhaust treatment not shown here) in the environment of the motor vehicle 1 be delivered.

2 shows a perspective view of the exhaust manifold 5 out 1 , In particular, the first inlet openings can be seen here 23 the first exhaust gas flow 6 and the second inlet openings 24 the second exhaust gas flow 7 , Furthermore, the flow guide 9 to recognize that at a receiving opening 8th on an outside 12 the exhaust manifold 5 is mounted by screwing. The receiving opening 8th is by the inclusion of the flow guide 9 (to the environment of the exhaust manifold 5 closed).

3 shows a sectional view of the exhaust manifold 5 from the 1 and 2 , To recognize here are in particular the first exhaust gas flow 6 and the second exhaust tide 7 , Furthermore, it can be seen that the receiving opening 8th through the flow guide 9 (to the environment of the exhaust manifold 5 closed). Inside the exhaust manifold 5 borders a connection chamber 14 to the receiving opening 8th at. The connection chamber 14 is fluidically to the first exhaust gas flow 6 and to the second exhaust gas flow 7 tethered. The flow guide 9 includes a flow baffle 11 , by means of which an opening 13 in the first flood of the exhaust 6 can be closed, causing the first exhaust gas flow 6 from the second exhaust 7 can be separated. The opening 13 is in a partition 27 between the first exhaust flow 6 and the second exhaust gas flow 7 intended. The flow baffle 11 is set up in the connection chamber 14 to be adjusted and thereby the opening 13 in the first flood of the exhaust 6 to close or open. The flow baffle 11 is in a lid 15 the flow guide 9 stored.

In the schematic representation shown is the flow guide 11 in two positions 28 . 29 located. In fact, the flow baffle can 11 only in one of the two marked positions 28 . 29 to be at the same time. In a first position 28 the flow guide 9 is the flow baffle 11 arranged such that the Strömungsleitklappe 11 does not protrude into the connecting chamber 14 and the opening 13 not locked. In a second position 29 the flow guide 9 is the flow baffle 11 arranged such that the Strömungsleitklappe 11 on the partition 27 abuts and the opening 13 blocked. The flow baffle 11 can also in other positions (especially in intermediate positions between the first position 28 and the second position 29 ) to be brought.

LIST OF REFERENCE NUMBERS

1

motor vehicle

2

Internal combustion engine

3

Cylinder first group

4

Cylinder second group

5

exhaust manifold

6

first exhaust gas flow

7

second exhaust gas flow

8th

receiving opening

9

flow director

10

flow

11

A flow

12

outside

13

opening

14

connecting chamber

15

cover

16

turbocharger

17

intake

18

compression region

19

exhaust area

20

compacting device

21

exhaust turbine

22

drive shaft

23

first inlet opening

24

second inlet opening

25

first outlet opening

26

second outlet opening

27

partition wall

28

first position

29

second position

Claims (8)

Exhaust manifold (5) for an internal combustion engine (2) comprising at least: at least two separate exhaust gas flows (6, 7), at least one receiving opening (8) for a flow-guiding device (9), wherein at least one flow path (10) between different of the at least two exhaust-gas floods (6, 7) can be opened or closed by means of the flow-guiding device (9), and wherein the receiving opening (8 ) is arranged on an outer side (12) of the exhaust manifold (5). Exhaust manifold (5) after Claim 1 wherein the receiving opening (8) can be closed by receiving the flow guiding device (9). Exhaust manifold (5) according to one of the preceding claims, wherein within the exhaust manifold (5) a connecting chamber (14) adjacent to the receiving opening (8), and wherein the connecting chamber (14) is fluidly connected to the at least two exhaust gas flows (6, 7) , Exhaust manifold (5) according to one of the preceding claims, wherein at the receiving opening (8) has a flow guide (9) is arranged, and wherein the flow guide (9) comprises a Strömungsleitklappe (11), by means of which an opening (13) in a first of Exhaust gas flows (6) can be closed, whereby the first exhaust gas flow (6) can be separated from a second exhaust gas flow (7). Exhaust manifold (5) after Claim 4 wherein the Strömungsleitklappe (11) is adapted to be adjusted in the connecting chamber (14) and thereby to close or open the opening (13) in the first exhaust gas flow (6). Exhaust manifold (5) after Claim 4 or 5 , wherein the flow-guiding flap (11) is mounted in a cover (15) of the flow-guiding device (9). Exhaust manifold (5) according to one of the preceding claims, wherein the flow guide (9) with the outside (12) of the exhaust manifold (5) is screwed. Motor vehicle (1) comprising at least one exhaust manifold (5) according to one of the preceding claims.

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