EP2888468A1

EP2888468A1 - Exhaust gas recirculation system for an internal combustion engine

Info

Publication number: EP2888468A1
Application number: EP13730869.8A
Authority: EP
Inventors: Michael Breuer
Original assignee: Pierburg GmbH
Current assignee: Pierburg GmbH
Priority date: 2012-08-21
Filing date: 2013-06-19
Publication date: 2015-07-01
Also published as: WO2014029522A1; DE102012107649A1; DE102012107649B4

Abstract

Exhaust gas recirculation systems for an internal combustion engine are known which comprise an exhaust gas line (20), an aspiration line (12), a turbocharger (16) with a compressor (14) that is arranged in said aspiration line (12) and a turbine (22) that is arranged in the exhaust gas line (20), an exhaust gas recirculation line (30) which branches off from the exhaust gas line (20) downstream of the turbine (22) and opens into the aspiration line (12) downstream of the compressor (14), and means for raising the pressure of the exhaust gas in said exhaust gas recirculation line (30). In order to overcome the drop in pressure, actively-operated exhaust gas recirculation pumps tend to be used. According to the invention, to be able to recirculate cleaned exhaust gas back into the high-pressure aspiration region in the most energy-efficient manner possible, it is suggested that a pressure wave supercharger (32) is arranged in the exhaust gas recirculation line (30) as a means for increasing pressure.

Description

DESCRIPTION

Exhaust gas recirculation system for an internal combustion engine

5

The invention relates to an exhaust gas recirculation system for an internal combustion engine having an exhaust pipe, an intake pipe, a turbocharger with a compressor disposed in the intake pipe and a turbine disposed in the exhaust pipe, o an exhaust gas recirculation pipe branching from the exhaust pipe downstream of the turbine and opens into the suction line downstream of the compressor and means for increasing the pressure of the exhaust gas in the exhaust gas recirculation line.

Various exhaust gas recirculation systems for pollutant reduction for turbocharged engines are known. The most commonly used systems have a low pressure exhaust gas recirculation branch or a high pressure exhaust gas recirculation branch. In the case of low-pressure exhaust gas recirculation, the exhaust gas is taken off behind the turbine and the exhaust gas purification system and returned to the compressor. This has the advantage that clean and already slightly cooled exhaust gas is recycled, whereby a sooting of the compressor and the intercooler is avoided and the turbine is the full exhaust gas flow available. However, it must be prevented that condensed combustion water causes damage to the compressor due to drop impact, so that the water must first be removed from the exhaust gas. Furthermore, the regulation of the low-pressure exhaust gas recirculation is relatively sluggish due to the long distances. The high-pressure exhaust gas recirculation, in which exhaust gas is taken in front of the turbine and fed back to the suction line downstream of the compressor, has the advantage of rapid controllability, but has, among other things, the problems that either the exhaust gas is introduced downstream of the charge air cooler, which leads to a reduced filling by increased temperatures or sooting of the intercooler arises. For this reason, mixing systems have been developed that are equipped with both a low-pressure exhaust line and a high-pressure exhaust line. However, this leads to an increased piping and thus installation effort, so that significantly higher costs. From DE 10 2009 027 639 AI an exhaust gas recirculation system with a high-pressure line and another exhaust gas recirculation line is known, which branches off behind an exhaust gas purification device and thus behind the turbine of the turbocharger and opens downstream of the compressor in the intake. In order to be able to deliver sufficient exhaust gas via this exhaust gas line, an exhaust gas pump driven by an electric motor is arranged in the exhaust gas recirculation train to overcome the pressure gradient. For example, clean exhaust gas can be made available to the internal combustion engine in a cooled state without fear of excessive inertia of the mass flow and temperature control. The disadvantage, however, is that additional drive power for the EGR pump must be introduced into the system, which reduces the overall efficiency.

Furthermore, the use of pressure wave chargers has been tested as an alternative to the supercharging of internal combustion engines by exhaust gas turbochargers, which are particularly resistant to contamination by the exhaust gas, because due to the operation of a regular flushing of the chambers takes place by the fresh air to be compressed, so that a growing sooting not is afraid. Such a pressure wave loader is described for example in DE 10 2010 049 361 AI. Due to the high pressure in the Exhaust line can be compressed in the chambers of the pressure wave supercharger exhaust gas to almost the pressure in the exhaust pipe so at the outlet of the cylinder. Special exhaust gas recirculation systems for such engines are not yet known.

It is therefore the object to provide an exhaust gas recirculation system, cooled with the most purified exhaust gas can be returned to the engine downstream of the compressor, the necessary energy input should be minimized. The pressure in the intake pipe as well as the temperature of the charge air through the exhaust gas recirculation should not be reduced, so that the filling of the cylinder is maintained compared to states without exhaust gas recirculation.

This object is achieved by an exhaust gas recirculation system having the features of claim 1. Characterized in that a pressure wave supercharger is arranged as means for increasing the pressure in the exhaust gas recirculation line, no additional drive energy is required to increase the pressure of the exhaust gas to the charge air level. Thus, high volume flows of clean exhaust gas can be promoted.

Preferably, a delivery inlet of the pressure wave supercharger is connected via the exhaust gas recirculation line to the exhaust pipe downstream of the turbine, a delivery outlet connected via the exhaust gas recirculation line to the intake line downstream of the compressor, a pressure inlet via a bypass line to the exhaust line upstream of the turbine and a pressure wave outlet via the bypass line with the Exhaust pipe connected downstream of the turbine. Accordingly, the pressure in the Abgasauslassleitung the cylinder is used to increase the pressure in the pressure wave supercharger to a to obtain corresponding pressure increase of the exhaust gas from the low pressure side to a pressure above the charge air line.

In a further embodiment, the exhaust gas recirculation line connected to the delivery inlet of the pressure wave supercharger branches off from the exhaust gas line downstream of a particle filter, thus ensuring that particles of free exhaust gas are mixed with the charge air. This reduces the load on the subsequent components and cables and thus increases their service life.

Accordingly, the exhaust gas recirculation line connected to the delivery inlet of the pressure wave supercharger also branches off from the exhaust line downstream of a catalyst, so that clean exhaust gas is returned. Deposits of hydrocarbons on cool walls of subsequent parts, such as the intercooler be significantly reduced in this way.

It is particularly advantageous if the exhaust gas recirculation line connected to the delivery outlet of the pressure wave supercharger opens into the intake line upstream of a charge air cooler, so that the entire combustion gas is mixed and fed to the combustion process at a uniform temperature. Furthermore, a charge air cooler is sufficient for cooling the exhaust gas and the air. Thus, high fillings can be achieved by low temperatures of the cylinder fresh air charge.

To reduce the emissions of the exhaust gas discharged, the bypass line of the pressure wave supercharger connected to the pressure wave outlet opens into the exhaust gas line upstream of the particle filter. Accordingly, the exhaust gas used to increase the pressure is cleaned before leaving the engine. Preferably, a cellular wheel of the pressure wave supercharger is driven by an electric motor. The energy input in this arrangement is extremely low, since no significant power must be transmitted, 5 but only the gas-dynamic processes in the individual cells are synchronized. Thus, the system can be set to varying speeds of sound in the gas.

In an alternative embodiment, the cell wheel of the o Druckwelienladers is driven via the crankshaft or the camshaft of the internal combustion engine. This creates a synchronous drive to the gas exchange processes, without any external energy input. It is thus an exhaust gas recirculation system with an exact controllability created in the clean exhaust gas is fed back directly into the charge air line without having to make an increased energy input. On additional coolers or piping can be omitted. The efficiency of the internal combustion engine is improved by the introduction of the air exhaust mixture with low temperature and elevated pressure level.

An embodiment of an exhaust gas recirculation system according to the invention is shown in the figures and will be described below.

Figure 1 shows a circuit diagram of the air and exhaust system of a supercharged internal combustion engine with an exhaust gas recirculation system according to the invention in a schematic representation. Figure 2 shows a development of a Druckwelienladers in the exhaust gas recirculation system according to the invention of Figure 1 in a schematic representation. FIG. 1 shows an internal combustion engine 10 which is supplied with combustion gas via an intake line 12. In the intake passage 12, a compressor 14 of a turbocharger 16 is arranged. Downstream of the compressor 14 is located in the intake manifold 12, a charge air cooler 18 for reducing the temperature of the combustion gases. The combustion gases leave the internal combustion engine 10 via an exhaust pipe 20, in which a turbine 22 of the turbocharger 16 is arranged. Downstream of the turbine 22 are located in the exhaust pipe 20, a particulate filter 24 and a catalytic converter 26, from which the exhaust gas continues to flow and leaves the exhaust pipe 20 via an exhaust gas outlet 28.

To reduce pollutants branches off from the exhaust pipe downstream of the catalyst 26 and the particulate filter 24 from an exhaust gas recirculation line 30, which opens downstream of the compressor 14 and upstream of the charge air cooler 18 in the intake passage 12.

Since the exhaust gas is removed cleaned behind the particulate filter 24 and the catalyst 26, there is no Versottungsproblem the charge air cooler 18. Also, there is the advantage that the compressor 14 is not charged with condensate-containing exhaust gas. However, it is problematic that a pressure gradient from the mouth of the exhaust gas recirculation line 30 to the diversion of the exhaust gas recirculation line 30 is made. Therefore, it is necessary to actively promote the exhaust gas toward the intake pipe 12. It is therefore according to the invention in the exhaust gas recirculation line 30, a pressure wave supercharger 32 is arranged. This pressure wave supercharger 32 is driven by an electric motor 34, this drive not giving off any power for compressing the exhaust gas, but merely synchronizing the 5 gas-dynamic processes in the cells 36 of the pressure wave supercharger 32. This means that it only applies a drive power for moving a cellular wheel 38 of the pressure wave supercharger 32, but without spending energy for compressing the exhaust gas. Compared to a belt or chain drive of the cellular wheel 38 of the lo blast loader 32 when driving with the electric motor 34 is possible to optimally adapt its speed to the variable sound velocities of the exhaust gas. Such pressure wave chargers 32 are known as Suprex or Hyprexlader.

In contrast to the known interconnection of a pressure wave supercharger 32 for compressing the intake air, in the present invention, however, the exhaust gas is both conveyed and used to increase the pressure. For this purpose, a delivery inlet 40 of the pressure wave loader 32 is connected to the exhaust gas recirculation line 30, which of the exhaust pipe 20th

20 downstream of the catalyst 26 and the particulate filter 24 branches off. A delivery outlet 42 is connected to the intake passage 12 downstream of the compressor 14 via the exhaust gas recirculation line 30. On the approximately axially opposite to the feed inlet 40 side of the cellular wheel 38 is the pressure wave loader 32 with a pressure wave outlet

25 44 which leads into a bypass line 46, which opens into the exhaust pipe 20 downstream of the turbine 22 and upstream of the particulate filter 24, so that this exhaust gas is cleaned in the following. This bypass line 46 branches from the exhaust pipe 20 in front of the turbine 22 thus at a position at which there is a high exhaust gas pressure, and is connected to 0 a pressure wave inlet 48 of the pressure wave supercharger 32, which is arranged approximately axially opposite to the delivery outlet 42 of the pressure wave supercharger 32.

The mode of operation of the pressure wave loader 32 will be explained below with reference to FIG. In this case, a single cell 36 is considered, which was initially filled with clean exhaust gas from the delivery inlet 40. Upon rotation of the cell 36, this reaches the opening of the pressure wave inlet 48. At the pressure wave inlet 48, the pressure of the non-purified exhaust gas in the high-pressure region thus lies upstream of the turbine 22. This significantly increased pressure compared to exhaust gas from the low pressure area in the cell 36 causes a pressure wave to propagate in the cell 36 to the right, resulting in compression of the clean gas present in the cell 36. When this pressure wave has spread so far that the clean gas has been compressed so much that it has substantially the same pressure as the gas coming from the pressure wave inlet 48, the outlet window opens to the delivery outlet 42. The clean exhaust gas flows out and enters the suction line 12. The further rotation of the cell wheel 38, the delivery outlet 42 is closed before the non-purified exhaust gas can flow out. Instead, the pressure wave outlet 44 arranged on the same side as the pressure wave inlet 48 is opened in the following. This means that the cell 38 reaches the pressure wave outlet 44, whereby the untreated exhaust gas can flow back into the area behind the turbine 22 via the bypass line 46 and is subsequently cleaned in the particle filter 26 and in the catalytic converter 28. This extension leads to a vacuum wave in the cell 36. By further rotation of the cell wheel, the cell 36 is in communication with the delivery inlet 40, through which the cell 36 is again filled with clean exhaust gas due to the vacuum wave, while the uncleaned exhaust gas is ejected becomes. Now, the cell 36 is again filled with clean exhaust gas, so that the process described starts again.

It follows that clean exhaust gas is increased to a pressure level which is above the pressure level of the air behind the compressor 14. Accordingly, there is a pressure gradient, which means that a sufficient amount can flow into this high-pressure region of the suction line 12. This exhaust gas can be cooled in the following in the intercooler 18 together with the compressed air and the internal combustion engine 10 are provided as a fresh charge available. The non-purified exhaust gas stream of the high-pressure region which provides the pressure wave is then fed to the cleaning process.

This means that the exhaust gas purified with minimum power to be applied can be made available to the combustion process in a timely manner, so that rapid system controllability is achieved. Furthermore, a pressure wave charger is very robust and has a long service life in an aggressive atmosphere compared to pumps. Thus, at the same time very good emission levels and a high efficiency of the internal combustion engine can be achieved.

It should be understood that the scope of protection is not limited to the described embodiment. Thus, various exhaust and intake systems are conceivable, for the use of a pressure wave supercharger for the purpose of promoting recirculated exhaust gas may be useful. Also, the drive of the pressure wave supercharger can take place via the camshaft or the crankshaft of the internal combustion engine.

Claims

P A T E N T A N S P R E C H E

Exhaust gas recirculation system for an internal combustion engine with an exhaust pipe (20),

an intake pipe (12),

a turbocharger (16) having a compressor (14) disposed in the intake passage (12) and a turbine (22) disposed in the exhaust passage (20),

an exhaust gas recirculation line (30) which branches off from the exhaust gas line (20) downstream of the turbine (22) and into the intake line

(12) downstream of the compressor (14) opens and

Means for increasing the pressure of the exhaust gas in the exhaust gas recirculation line

(30)

characterized in that

as means for increasing the pressure in the exhaust gas recirculation line (30) a pressure wave loader (32) is arranged.

Exhaust gas recirculation system for an internal combustion engine according to claim 1,

characterized in that

a delivery inlet (40) of the pressure wave supercharger (32) is connected via the exhaust gas recirculation line (30) to the exhaust line (20) downstream of the turbine (22), downstream of a delivery outlet (42) via the exhaust gas recirculation line (30) to the intake line (12) compressor (14), a Druckwelleneiniass (48) via a bypass line (46) with the exhaust pipe (20) upstream of the turbine (22) is connected and a Druckwelienauslass (44) via the bypass line (46) with the exhaust pipe (20 ) is connected downstream of the turbine (22). 3, exhaust gas recirculation system for an internal combustion engine according to claim 2,

characterized in that

the exhaust gas recirculation line (30) connected to the delivery inlet (40) of the pressure wave supercharger (32) branches off from the exhaust gas line (20) downstream of a particulate filter (24).

4. exhaust gas recirculation system for an internal combustion engine according to claim 2 or 3,

characterized in that

the exhaust gas recirculation line (30) connected to the delivery inlet (40) of the pressure wave supercharger (32) branches off from the exhaust gas line (20) downstream of a catalytic converter (26). 5. Exhaust gas recirculation system for an internal combustion engine according to one of claims 2 to 4,

characterized in that

the exhaust gas recirculation line (30) connected to the delivery outlet (42) of the pressure wave supercharger (32) opens into the intake line (12) upstream of an intercooler (18).

6. exhaust gas recirculation system for an internal combustion engine according to one of claims 2 to 5,

characterized in that

the bypass line (46) of the pressure wave supercharger (32) connected to the pressure wave outlet (44) opens into the exhaust gas line (20) upstream of the particle filter (24).

7. exhaust gas recirculation system for an internal combustion engine according to any one of the preceding claims,

characterized in that a cellular wheel (38) of the pressure wave supercharger (32) is driven via an electric motor (34).

8. exhaust gas recirculation system for an internal combustion engine according to any one of claims 1 to 6,

characterized in that

the cellular wheel (38) of the pressure wave supercharger (32) is driven via the crankshaft or the camshaft of the internal combustion engine (10).