WO2018046198A1 - Internal combustion engine and method for operating an internal combustion engine - Google Patents

Abstract

An internal combustion engine having a combustion engine (10), an exhaust train and an exhaust turbine (26) which is integrated into the exhaust gas train, wherein the internal combustion engine (10) forms at least two combustion chambers (14), to each of which at least two outlet valves (46, 48) are assigned, and wherein the outlet valves (46, 48) can be actuated by means of a valve drive, wherein first outlet valves (46) which are assigned to the combustion chambers (14) are connected to the exhaust gas turbine (26) in an exhaust-gas-conducting fashion via a first common stream of exhaust gas (42), and second outlet valves (48) which are assigned to said combustion chambers (14) are connected to said exhaust gas turbine (26) in an exhaust-gas-conducting fashion via a second common stream of exhaust gas (44), is characterized in that the valve drive is embodied in such a way that said valve drive - activates the first outlet valves (46) and the second outlet valves (48) with, in each case, an opening period which is less than the ignition interval of the combustion chambers of bracket (14) or corresponds at maximum thereto, and - activates the first outlet valve (46) and the second outlet valve (48) of each combustion chamber (14) with a phase offset with respect to one another.

Description

 description

Internal combustion engine and method for operating an internal combustion engine

The invention relates to an internal combustion engine and a method for operating such an internal combustion engine.

In supercharged internal combustion engines with multi-cylinder internal combustion engines leads a common exhaust manifold of the exhaust line, which connects the exhaust ports with the exhaust gas turbine, to a so-called crosstalk of an exhaust stroke of an exhaust gas

ejecting combustion chamber on the remaining cylinders. This can, especially in an operation of the internal combustion engine with increased load to an undesirable influence of the

Operating behavior lead, since it can come to the backflow of exhaust gas from the exhaust manifold into the combustion chambers. This can be associated with an increased residual gas rate in these combustion chambers and thus for example in gasoline engines with an increased tendency to knock and consequent reduction of the combustion efficiency and the torque that can be generated.

In internal combustion engines with turbocharger and separate exhaust gas flows, each connecting only a portion of the combustion chambers with the exhaust gas turbine of the exhaust gas turbocharger, the strength of crosstalk depends to a considerable extent on the design of the exhaust gas turbine. A segmented turbine, for example, allows a significant reduction of the

Crosstalk compared to a combination of a simple exhaust gas flow with a conventional exhaust gas turbine, because a merging over the various

Exhaust gas flows guided exhaust gas flows only in the turbine wheels of the segmented turbines, wherein the exhaust gas streams are also introduced into different, usually offset by 180 ° with respect to the rotational axes peripheral portions of the turbine wheels in this. Segment turbines, however, cause in a combination with separate exhaust gas flows inherently a high exhaust backpressure, since the expelled in the individual exhaust strokes from the combustion chambers exhaust gas flows through only a portion of the total provided by the exhaust gas flows and the exhaust gas flow volumes. High exhaust back pressures generally result in high discharge losses, increased

Residual gas rates and thereby increased knock tendencies of internal combustion engines. Using separate exhaust gas flows in combination with a twin scroll turbine of an exhaust gas turbocharger also allows a reduction of crosstalk between the combustion chambers; However, this in a smaller compared to a segment turbine dimensions, because in twin-scroll turbochargers, the separated exhaust gas flows only axially offset with respect to the rotational axis of the turbine runner, but at the same time each usually about (approximately) the full circumference of the turbine runner and thus parallel in the

Turbine runner be initiated. Since, even with a combination of separate exhaust gas flows and twin scroll turbine, the individual exhaust gas flows through only a portion of the flow volumes provided by the exhaust gas flows and the exhaust gas turbine (inlet side), such a combination also leads to an increased exhaust back pressure, which, however, usually is slightly less than a segment turbine.

It is possible, in an internal combustion engine with separate exhaust gas flows and segment turbine, the exhaust back pressure as a function of the operating state of

To reduce internal combustion engine to a level that is typical for twin scroll turbines by a connecting line between the exhaust gas is opened by means of a valve provided as required. The individual exhaust gas streams can then flow over the entire circumference in the turbine runner. When open connection line is due to a lying relatively close to the outlet channels of the internal combustion engine fluid-conducting

However, connection between the exhaust fumes the crosstalk between the cylinders then considerably.

In DE 10 2014 007 310 A1 is an internal combustion engine with an even number of cylinders having internal combustion engine and with an exhaust line, in a

Twinscroll- or segmented turbine is integrated disclosed. Each cylinder is a first, closable by means of an exhaust valve outlet opening and a second by means of a

Outlet valve associated closable outlet opening, wherein the second outlet openings are larger than the first outlet openings. The first outlet openings of a first half of the cylinders and the second outlet openings of the second half of the cylinders are connected to the twin scroll or segment turbine via a first exhaust gas flow of the exhaust gas line, while the second outlet openings of the first half of the cylinders and the first outlet openings of the second half of the cylinders are connected via a second exhaust gas flow of the exhaust line to the twinscroll or segment turbine. In an operation of the internal combustion engine with relatively low speeds, either the first or the second outlet openings are to be kept permanently closed by means of the outlet valves associated therewith. From WO 2014/195256 A1 is an internal combustion engine with two exhaust valves each

Combustion chamber known at the first exhaust ducts via a first exhaust gas flow and second

Outlet passages are connected via a second exhaust gas flow to an exhaust gas turbine of an exhaust gas turbocharger. The two exhaust gas flows are connected to geometrically different sections of the exhaust gas turbine.

EP 2 620 631 A1 describes an internal combustion engine having two exhaust valves per combustion chamber, in which first exhaust passages are connected via a first exhaust gas flow to an exhaust gas turbocharger of an exhaust gas turbocharger and second exhaust passages are connected via a second exhaust gas flow to a bypass to the exhaust gas turbine.

EP 2,198,888 A2 discloses a bi-turbo internal combustion engine with a

Combustion engine and two exhaust valves per combustion chamber, with the individual

Outlet valves of the combustion chambers are actuated with phase offset. In this case, it is provided that the exhaust ducts which can be closed via first exhaust valves of the combustion chambers are connected to the turbine of a first exhaust gas turbocharger via a first exhaust gas flow and the exhaust ducts which can be closed via second exhaust valves of the combustion chambers are connected to the turbine of a second exhaust gas turbocharger via a second exhaust gas flow.

The invention had the object of specifying a charged by means of an exhaust gas turbocharger internal combustion engine, in which the problem of crosstalk of a

Exhaust stroke of an exhaust gas emitting combustion chamber is eliminated as far as possible to the other combustion chambers. At the same time as low as possible by the exhaust gas turbine of the exhaust gas turbocharger integrated in an exhaust line of the internal combustion engine generated

Exhaust back pressure can be achieved.

This object is achieved by means of an internal combustion engine according to the patent claim 1. A method for operating such an internal combustion engine is the subject of

Claim 8. Advantageous embodiments of the internal combustion engine according to the invention and preferred embodiments of the method according to the invention are objects of the other claims and / or will become apparent from the following description of the invention.

According to the invention, an internal combustion engine with an internal combustion engine, a

Intake exhaust system and an exhaust gas turbine integrated into the exhaust line, wherein the internal combustion engine forms at least two combustion chambers, each of which at least two Outlet valves are assigned. The exhaust valves are actuated by means of a valve train. In each case a first of the exhaust valves of the (all) combustion chambers is via a (first exhaust valves common) first exhaust gas flow and a second of the exhaust valves of the (all) combustion chambers is via a (common to the second exhaust valves) second exhaust gas flow of the exhaust gas line with the exhaust gas turbine in exhaust gas conducting connection.

According to the invention, such an internal combustion engine is characterized in that the valve drive is designed such that it

 the first exhaust valves and the second exhaust valves are each actuated with an opening duration which is less than or equal to the firing interval of the combustion chambers, and

 - The first exhaust valve and the second exhaust valve of each combustion chamber with a

 Phase set pressed to each other.

A method for operating an internal combustion engine, the at least one

Combustion engine, an exhaust system and an exhaust gas turbine integrated into the exhaust line, wherein the internal combustion engine forms at least two combustion chambers, each of which at least two exhaust valves are assigned, and wherein the exhaust valves are actuated by a valve train, wherein the combustion chambers associated first exhaust valves via a common first exhaust gas flow and the combustion chambers associated second exhaust valves via a common second exhaust gas flow of the exhaust line with the exhaust gas turbine are in exhaust gas conductively connected, according to the invention is characterized in that

 - the first exhaust valves and the second exhaust valves are each operated with an opening duration which is smaller than the firing interval of the combustion chambers or corresponds to this maximum, and

 - The first exhaust valve and the second exhaust valve of each combustion chamber with a

 Phase offset to each other are actuated.

Both in an internal combustion engine according to the invention as well as in a

The method according to the invention may preferably be provided such that the phase offset is dimensioned such that the valve lift curves of the outlet valves associated with a combustion chamber still overlap, in particular by at least 50% of the respective opening duration.

The invention is based on the idea of assigning each combustion chamber of the internal combustion engine at least two exhaust valves, wherein in each case a first exhaust valve and a second exhaust valve of the individual combustion chambers from each other separate exhaust gas are assigned, which are as far as possible separated out and in particular only in the transition into a turbine wheel receiving impeller space of the exhaust gas turbine are brought together again. Due to the separated exhaust gas flows, a crosstalk of an exhaust pulse of a combustion chamber emitting exhaust gas to the remaining combustion chambers can in principle be kept low. Since, however, in an internal combustion engine according to the invention, all of the combustion chambers are connected to each of the exhaust gas flows via at least one exhaust valve, the possibility of crosstalk which continues to exist is thereby minimized according to the invention in that the opening duration of the individual

Exhaust valves is dimensioned so short that a crosstalk between the combustion chambers is largely prevented over all exhaust valves each associated exhaust valves. However, since the opening duration of the individual exhaust valves is too short to ensure a largely complete expulsion of the exhaust gas from the individual combustion chambers, a phase shift for the opening times of the first exhaust valve and the second exhaust valve of the individual combustion chambers is provided according to the invention, so that through the combination of the staggered opening times of the two exhaust valves for the individual combustion chambers results in a sufficiently long overall opening duration. As a result, due to the sufficiently short individual opening duration of the exhaust valves crosstalk within the individual exhaust gas flows is kept low or avoided and by the separation of the exhaust gas flows to the exhaust gas turbine and a crosstalk between the guided over the exhaust gas flows exhaust gas flows, so that a total crosstalk prevents or can be kept low. On the other hand, according to the invention, the exhaust gas ejected from the individual combustion chambers per exhaust stroke is guided via both flow volumes made available by the two exhaust gas flows to the exhaust gas turbine where it is introduced into the turbine runner, whereby the lowest possible exhaust back pressure caused by the exhaust gas turbine can be achieved.

According to the invention, the opening duration of the individual exhaust valves is then dimensioned sufficiently short in order to avoid crosstalk within the individual exhaust-gas floods if this is smaller than or equal to the maximum (uniform) firing interval of the combustion chambers. In a modification of an internal combustion engine according to the invention, the opening duration of the individual exhaust valves may also be greater than the ignition interval if a relevant crosstalk within the individual exhaust gas floods can be accepted. It basically applies that the crosstalk is the lower, the closer the

Opening duration at the firing interval lying is dimensioned. As "firing interval" is the angular range, based on the rotation of an output shaft and in particular a crankshaft of the internal combustion engine understood, which results from the fact that the rotation angle of the output shaft, this principle performs between two desired firing processes in each of the combustion chambers, by the number In a four-stroke reciprocating engine, in which the invention can be used with particular preference, the angle of rotation of the crankshaft (output shaft), which this principle performs between two desired combustion processes in each of the combustion chambers, is 720 ° For example, in the case of a four-stroke reciprocating engine with, for example, six cylinders or combustion chambers, the ignition interval is "only" 120 ° CA. In a four-stroke reciprocating engine with

For example, three cylinders or combustion chambers, the ignition distance is 240 ° KW.

Usually, for the exhaust valves of four-stroke reciprocating engines each one

Opening period provided, which may be greater than 180 ° KW and regularly up to 260 ° KW. It follows that the invention can be particularly preferably used in an internal combustion engine and in particular reciprocating engine, which has at least four and therefore in particular exactly four, five, six, eight, ten, twelve or sixteen combustion chambers, because then the ignition distance is inherently so small that in principle the problem of crosstalk between the combustion chambers can be relevant. At a

On the other hand, an internal combustion engine with only three combustion chambers can already be relatively problematic as a result of the relatively large ignition interval, and it is not excluded that an embodiment according to the invention can also be advantageous in such an internal combustion engine.

According to the invention, the term "opening period" is understood to mean the complete opening period resulting from the fact that an outlet valve is moved with the aim of opening.When considering a conventional valve lifting curve, the very flat rising or falling sections should also be used at the beginning and at the end Valve lift curve includes.

An internal combustion engine according to the invention can basically still have one

Include fresh gas train, by means of which the combustion chambers of the internal combustion engine

Fresh gas can be supplied. The fresh gas can then be mixed in the combustion chambers or previously with a fuel to an ignitable fresh gas-fuel mixture train. The internal combustion engine can in particular be charged and accordingly have a compressor integrated into the fresh gas train for compression of the fresh gas. The compressor and the exhaust gas turbine of an internal combustion engine according to the invention may in particular be components of an exhaust gas turbocharger, in which a rotation of a turbine wheel of the turbine is transmitted directly or indirectly, in particular via a shaft, to a compressor impeller of the compressor, wherein this rotation of the compressor impeller the compression of the fresh gas causes.

In a preferred embodiment of an internal combustion engine according to the invention, it may be provided that the exhaust gas turbine is a segment turbine or a twin scroll turbine, because these are absorbed by the turbine runner as a result of a transition only at the transition

Impeller space of the exhaust gas taking place merging of the two exhaust gas flows keep a crosstalk between the guided over the exhaust gas flows exhaust gas flows as low as possible. In this case, the use of a segment turbine may be particularly preferably provided, since in a segment turbine in comparison to a twin scroll turbine, an introduction of the guided over the exhaust gas flows exhaust flows takes place in at least partially and preferably completely different peripheral portions of the turbine wheel.

In a further preferred embodiment of an internal combustion engine according to the invention as well as in a preferred embodiment of a method according to the invention, it can be provided that the phase offset is between 50 ° CA and 70 ° CA and particularly preferably about 60 ° CA. Such a phase offset can prove to be advantageous, in particular in the case of an internal combustion engine having four combustion chambers, in spite of the comparatively short opening duration of the individual exhaust valves as a result of optimally sized total opening duration for each combustion chamber

To realize exhaust valves. In the case of an internal combustion engine having more than four combustion chambers, it can preferably be provided that the phase offset is tended to be greater than for an internal combustion engine having four combustion chambers because, as a result of the shorter ignition intervals, the opening duration of the individual exhaust valves is also selected to be shorter or should be selected.

For an internal combustion engine according to the invention may further be preferably provided an embodiment such that exhaust gas mass flows per exhaust stroke for a (each) combustion chamber on the first exhaust gas flow (as a result of opening the first exhaust valves) on the one hand and the second exhaust gas flow (due to opening of the second exhaust valves) on the other hand, are as equal as possible. This can be on the one hand with regard to the achievement the lowest possible exhaust gas back pressure advantageous effect. On the other hand, this can have a particularly advantageous effect when using a segmented turbine as an exhaust gas turbine of an internal combustion engine according to the invention, since in this way radial alternating loads for the turbine runner of the segmented turbine can be avoided or minimized. Namely, such radial load cells could be over at the various

Exhaust gas flows guided unequal exhaust gas mass flow as a result of only taking place over a peripheral portion entry of the exhaust gas mass flows into the turbine runner occur. As a result of the invention provided for the opening of the exhaust valves of the individual combustion chambers phase offset can achieve the same as possible

Exhaust gas mass flows a different interpretation of the two exhaust gas flows (including their mouths in the impeller space of the exhaust gas turbine) and / or the exhaust valves as well as required to be closed by these outlet ducts of the internal combustion engine, because the pressure of the exhaust gas tends to increase in the combustion chambers when opening the first opening exhaust valve than when opening the subsequently opening exhaust valve, which is at an otherwise comparable boundary conditions to an increased

Exhaust gas mass flow through the first opened exhaust valve compared to the only subsequently opened exhaust valve can lead. In this case, the term "interpretation" according to the invention is widely understood and is therefore not merely a geometric

Include sizing. For example, for the exhaust valves, this also includes an interpretation of the respective opening duration and / or the (maximum) opening stroke.

In order to achieve the same as possible exhaust gas mass flows via the exhaust gas flows, it can be provided in particular that the opening duration and / or the opening stroke of the first exhaust valve and the second exhaust valve are different and / or the average (that is to say the averaged over the longitudinal extents of the exhaust gas) flow cross sections and / or

Longitudinal extents of the exhaust gas flows are different and / or the peripheral sections, via which the exhaust gas flows introduce exhaust gas streams into a turbine runner of the exhaust gas turbine, are different. In this case, provision can be made in particular for the design of that exhaust gas flow which is associated with the first opening exhaust valves and / or these first opening exhaust valves to be compared to those which subsequently open and / or compared to the exhaust gas flow associated with these later opening exhaust valves achieving a reduced exhaust mass flow (due to a relatively large flow resistance) is designed to compensate for the relatively high pressure of the exhaust gas when opening these first opening exhaust valves. In a preferred embodiment of an internal combustion engine according to the invention can also be provided that the engine is a gasoline engine, because in such a gasoline engine crosstalk between the combustion chambers and / or increased exhaust back pressure can have a particularly negative effect. In particular, a pronounced crosstalk and a relatively large exhaust backpressure in each case result in an increased residual gas rate in the combustion chambers, which in a gasoline engine to an increased tendency to knock and consequent, especially because then usual anti-knock measures, such as a retardation of the ignition angle, would have to be initiated , can lead to a deterioration of the efficiency and the power generated by the gasoline engine.

The indefinite articles ("one", "one", "one" and "one"), in particular in the

Claims and in the claims generally explaining the description are to be understood as such and not as numerical words. Correspondingly thus concretized

Components are thus to be understood that they are present at least once and may be present more than once.

The present invention will be explained in more detail with reference to an embodiment shown in the drawings. In the drawings shows:

1 shows an internal combustion engine according to the invention in a schematic representation; and

2 shows a diagram of exemplary curves for the valve lifts (H) of the intake valves and the exhaust valves and for the thereby caused

 Gas mass flow (GMS) above the crankshaft angle.

Fig. 1 shows a schematic representation of an internal combustion engine according to the invention with a running on the Otto principle internal combustion engine 10 (gasoline engine), as

Reciprocating engine with four cylinders 12 is formed. The cylinders 12, together with pistons (not shown) guided therein and downwards, and a cylinder head (not shown) define combustion chambers 14 in which fresh gas (air) is combusted together with fuel during operation of the internal combustion engine (ignition sequence 1-4-2-3 ). The fuel is injected, controlled by a control device 16 (engine control), by means of injectors 18 directly into the combustion chambers 14. The burning of the fuel-fresh gas mixture leads to cyclical upward and downward movements of the piston, which in turn in a known manner via connecting rods, not shown, (not shown) on a crankshaft, also not shown be transferred, whereby the crankshaft is driven in rotation. The fresh gas is supplied to the engine 10 via a fresh gas train and to a via

Suction port sucked from the environment, cleaned in an air filter 20 and

then into a compressor 22, which is part of an exhaust gas turbocharger, out. The fresh gas is compressed by means of the compressor 22, then cooled in a charge air cooler 24 and metered by inlet valves 50 fed to the combustion chambers 14. The drive of the

Compressor 22 by means of an exhaust gas turbine 26 of the exhaust gas turbocharger, which in a

Exhaust line of the internal combustion engine is integrated. Exhaust gas, which has formed during the combustion of the fuel fresh gas mixture in the combustion chambers 14 of the internal combustion engine 10, is discharged via the exhaust line from the internal combustion engine 10 and flows through the exhaust gas turbine 26. This results in a known manner to a rotating drive of a turbine runner 28th which is non-rotatably connected via a shaft 30 to a compressor impeller (not shown) of the compressor 22. The rotary drive of the turbine runner 28 is thereby transmitted to the compressor runner.

Downstream of the compressor 22 is in the charge air passage, i. in the located between the compressor 22 and the engine 10 portion of the fresh gas line, a likewise controllable by the control device 16 control valve 32 (throttle) integrated.

In the exhaust gas turbine 26 is a so-called segment turbine, the housing 34 formed spirally guided and separated from each other inlet channels 36, each radially outwardly (with respect to a rotation axis 38 of the turbine runner 28) in the turbine wheel 28 receiving impeller space 40 of the exhaust gas turbine 26, wherein the mouths of the inlet channels 36 each cover a peripheral portion of nearly 180 ° of the impeller space 40 and thus also rotatably mounted therein the turbine impeller 28 and centers of the orifices are located in a radial plane. In this case, the circumferential sections of the openings of the inlet channels 36 are arranged offset by 180 ° to each other, so that together cover substantially the entire circumference of the impeller space 40 and thus also of the turbine wheel 28.

Each of the inlet channels 36 of the exhaust gas turbine 26 represents a portion of an exhaust gas flow 42, 44. The exhaust gas flows 42, 44 form a portion of the exhaust gas line and connect the combustion chambers 14 of the internal combustion engine 10 fluidically with the impeller space 40 of FIG

Exhaust gas turbine 26, wherein a first exhaust gas flow 42, the combustion chambers 14 via a respective first exhaust valve 46 of each combustion chamber 14 with one of the inlet channels 36 and a second Exhaust gas flow 44 connects the combustion chambers 14 via a respective second outlet valve 48 of each combustion chamber 14 with the other of the inlet channels 36.

The exhaust valves 46, 48 as well as the intake valves 50 may be formed in a known manner as poppet valves, the spring-loaded one in the cylinder head of the

Close internal combustion engine 10 trained exhaust port or inlet channel, if they are not actively operated. On actuation, on the other hand, according to an intended valve lift curve 52, 54, 56, they are lifted off the respectively associated valve seat of the outlet or inlet channel, as a result of which it is temporarily released. An actuation of the exhaust valves 46, 48 and the inlet valves 50 can in particular in

conventionally by means of one or more, in particular by means of two camshafts of a valve drive.

2 shows in a diagram for an inventive internal combustion engine according to FIG. 1 exemplary curves curves for the valve lifts (H) of the intake valves 46, 48 and the exhaust valves 50, which are the same for all of the different combustion chambers 14 gas exchange valves, and for fresh gas and exhaust gas mass flow (GMS) caused by the valve lift above the relative rotational angle of the crankshaft (° CA).

It can be seen that the two exhaust valves 46, 48 (valve lift curves 52, 54) associated with each of the combustion chambers 14 are each actuated with an opening duration that is approximately 180 ° CA, the operating times of the two associated with a combustion chamber 14 Outlet valves 46, 48 also have a phase offset of about 60 ° CA in the present embodiment. By a combination of the staggered opening times of each of a combustion chamber 14 associated exhaust valves 46, 48, a total opening time is achieved for this, which is for a substantially complete expulsion of exhaust gas from the

Combustion chambers 14 is required and approximately the opening duration of the intake valves 50th

(Valve lift curve 56) corresponds.

While a largely complete expulsion of the exhaust gas from the combustion chambers 14 is ensured by the phase offset of the opening times of the two exhaust valves 46, 48 of each combustion chamber 14, the fluid-conducting connection of all first, first-opening

Exhaust valves 46 with the first exhaust gas flow 42 and the fluid-conducting connection of all the second, later opening exhaust valves 48 with the second exhaust gas flow 42 due to the relatively short (single) opening duration of the exhaust valves 46, 48 that a crosstalk of

Exhaust pulses within the two exhaust gas flows 42, 44 is effectively suppressed. In addition the completely separated exhaust gas flows 42, 44 cause a separation of the guided through these exhaust gas streams until they enter the turbine runner 28 and these exhaust flows due to the design of the exhaust gas turbine 26 as a segment turbine also flow into different peripheral sections of the turbine wheel 28, is also a crosstalk of exhaust pulses between the two exhaust gas flows 42, 44 avoided, so that no total or only a very low crosstalk for the internal combustion engine according to the invention can be realized. At the same time, the exhaust backpressure generated by the exhaust gas turbine 26 is comparatively low, because through the opening of both

Exhaust valves 46, 48 of each combustion chamber 14 in each exhaust stroke in the operation of

Internal combustion engine 10, the exhaust gas ejected thereby can flow through the entire available flow volumes of the two exhaust gas flows 42, 44 and the exhaust gas turbine 26.

It can also be seen from FIG. 2 that a relatively high exhaust gas mass flow is initially emitted when the respective first (first opening) exhaust valve 46 is opened (compare with curve 58 of the exhaust gas mass flow emitted via a first exhaust valve 46 from a combustion chamber 14) which is then still due to relatively high pressures in the combustion chambers (outlet shock). By contrast, the maximum value of the exhaust gas mass flow conducted via the second exhaust ducts as a result of opening the respective second (later opening) exhaust valves 48 (compare with curve 60 of the exhaust gas mass flow emitted via a respective second exhaust valve 48 from a combustion chamber 14) is due to an opening of the second exhaust valve 48 present significantly reduced pressure levels in the associated combustion chamber 14 well below the maximum value for the exhaust gas mass flow caused by the opening of the first exhaust valve 46.

In the example according to FIG. 2 provided for example identical (only

out of phase) valve lift curves 52, 54 could cause the exhaust stroke with substantially identical design of the two exhaust gas flows 42, 44 that on average a higher exhaust gas mass flow per exhaust stroke of a combustion chamber 14 via the first exhaust gas flow 42 in

Compared to the guided over the second exhaust gas flow 44 averaged exhaust gas mass flow. As a result, a non-uniform radial load and as a result of the cyclical repetition of this non-uniform load, a radial alternating load for the turbine runner 28 and in particular for its pivotal mounting in the housing 34, which can adversely affect the expected life of the exhaust gas turbine 26. To avoid this, it may be provided that the mean flow cross section, which the first exhaust gas flow 42 has, is smaller than that of the second exhaust gas flow 44 dimension, whereby the first exhaust gas flow 42 tends to be higher

Flow resistance as the second exhaust gas flow 44 causes. It can thereby be achieved that a little more exhaust gas is expelled via the second, later-opening exhaust valves 48 than would be the case with respect to the flow resistance identically formed exhaust gas flows 42, 44. As a result, it can be achieved overall that the exhaust gas mass flows, which are conducted via the two exhaust gas flows 42, 44, are substantially equal, whereby radial alternating loads for the turbine runner 28 can be avoided or reduced.

List of internal combustion engine

cylinder

combustion chamber

control device

injector

air filter

compressor

Intercooler

exhaust turbine

turbine impeller

Shaft of the exhaust gas turbine

control flap

Housing of the exhaust gas turbine

Inlet duct of the exhaust gas turbine

Rotation axis of the turbine runner

Impeller chamber of the exhaust gas turbine

first exhaust gas flow

second exhaust gas flow

first exhaust valve

second exhaust valve

intake valve

Valve lift curve of the first exhaust valve

Valve lift curve of the second exhaust valve

Valve lift curve of intake valves

Course of the over the first exhaust valve ejected from a combustion chamber exhaust gas mass flow

Course of the discharged via the second exhaust valve from a combustion chamber exhaust gas mass flow

Course of the over the intake valves in total flowing into a combustion chamber fresh gas mass flow

Claims

claims

1. Internal combustion engine with an internal combustion engine (10), an exhaust system and an exhaust gas turbine integrated into the exhaust line (26), wherein the internal combustion engine (10) at least two combustion chambers (14) is formed, each having at least two

 Exhaust valves (46, 48) are associated, and wherein the exhaust valves (46, 48) are actuated by means of a valve train, wherein the combustion chambers (14) associated first exhaust valves (46) via a common first exhaust gas flow (42) and the combustion chambers (14) associated second exhaust valves (48) via a common second exhaust gas flow (44) of the exhaust line with the exhaust gas turbine (26) in exhaust conductive connection, characterized in that the valve train is designed such that this

- The first exhaust valves (46) and the second exhaust valves (48) each operated with an opening duration which is smaller than the firing interval of the combustion chambers (14) or corresponds to this maximum, and

 - The first exhaust valve (46) and the second exhaust valve (48) of each combustion chamber (14) actuated with a phase offset to each other.

2. Internal combustion engine according to claim 1, characterized in that the

 Exhaust gas turbine (26) is a segment turbine or a twin-scroll turbine.

3. Internal combustion engine according to claim 1 or 2, characterized in that the internal combustion engine (10) has at least three combustion chambers (14).

4. Internal combustion engine according to one of the preceding claims, characterized

 characterized in that the phase offset is between 50 ° CA and 70 ° CA.

5. Internal combustion engine according to one of the preceding claims, characterized by an embodiment such that exhaust gas mass flows, which are discharged per exhaust stroke for a combustion chamber (14) via the first exhaust gas flow (42) on the one hand and the second exhaust gas flow (44) on the other hand, are substantially equal ,

6. Internal combustion engine according to claim 5, characterized in that the

 Opening period and / or the opening stroke of the first exhaust valve (46) to the

Opening duration and / or the opening stroke of the second exhaust valve (48) is different / and / or the average flow cross-sections and / or longitudinal extent of the Exhaust gas flows 42, 44 are different and / or the peripheral sections, via which the exhaust gas flows (42, 44) exhaust gas flows into a turbine runner (28) of the exhaust gas turbine (26), are different.

7. Internal combustion engine according to one of the preceding claims, characterized

 characterized in that the internal combustion engine (10) is a gasoline engine

8. A method for operating an internal combustion engine with an internal combustion engine (10), an exhaust system and an exhaust gas turbine integrated into the exhaust line (26), wherein the internal combustion engine (10) forms at least two combustion chambers, each of which at least two exhaust valves 46, 48) are assigned, and wherein the exhaust valves 46, 48) are actuated by means of a valve drive, wherein the first exhaust valves (46) associated with the combustion chambers (14) via a common first exhaust gas flow (42) and the

 Combustion chambers (14) associated second exhaust valves (48) via a common second exhaust gas flow (44) of the exhaust line with the exhaust gas turbine (26) are in exhaust gas conductive connection, characterized in that

 - the first exhaust valves (46) and the second exhaust valves (48) are each operated with an opening duration which is smaller than the firing interval of the combustion chambers (14) or corresponds to this maximum, and

 - The first exhaust valve (46) and the second exhaust valve (48) of each combustion chamber (14) actuated with a phase offset to each other.

9. The method according to claim 8, characterized in that the phase offset

 between 50 ° KW and 70 ° KW.