The invention relates to a supercharged internal combustion engine with exhaust gas recirculation and a first group of cylinders and a second group of cylinders which operates in accordance with the spender cylinder principle wherein specifically exhaust gas from the second group of cylinders is recirculated. The engine includes an exhaust gas collection duct having a first section connected to the first group of cylinders and a second section connected to the second group of cylinders for receiving exhaust gas therefrom and conducting it to the turbine or, respectively, via an exhaust gas recirculation line, to a charge air line supplying fresh gas to the cylinders.
An internal combustion engine with these features is disclosed in U.S. Pat. No. 4,249,382. In a first embodiment, an internal combustion engine with six cylinders and an exhaust gas turbocharger is shown wherein one cylinder is used as a recirculation exhaust gas supply cylinder (spender cylinder). The exhaust gas of the other cylinders is combined in a first section of the exhaust gas collection line and is supplied via an exhaust gas collection line to the turbine of the exhaust gas turbocharger. The exhaust gas of the recirculation exhaust gas supply cylinder is collected in a second section of the exhaust duct and is returned, via an exhaust gas recirculation cooler to the charge air intake duct. With this arrangement, a constant exhaust gas recirculation rate of 16% is provided.
In the arrangement described in following description more than one cylinder can be used for returning exhaust gas to the intake duct or directing it, selectively to the turbine.
In a second embodiment of the state of the art referred to above, the first and the second groups of cylinders comprise each the same number of cylinders. Additionally, at the point of connection to the exhaust recirculation line there is a branch off line leading to the first exhaust gas line. The branch-off line includes an electrical control device by which the exhaust gas flow from the exhaust gas recirculation line to the first exhaust gas line can be controlled.
With this design, a maximum exhaust gas recirculation rate of 50% is obtainable. Because of the higher exhaust gas back pressure in the exhaust gas recirculation line an exhaust gas recirculation supply cylinder has to perform a greater exhaust gas discharge work which results in a higher fuel consumption and a higher thermal load. This applies particularly to high-pressure exhaust gas recirculation as it is required for supercharged engines. With exhaust gas recirculation rates of for example 20% in this arrangement, 50% of the cylinders are operated with an increased exhaust gas back pressure which has a detrimental effect on the fuel consumption. In practice, it is attempted to find a compromise between, on one hand, the necessary exhaust gas recirculation rate and consequently, the number of cylinders in the second group of cylinders and, on the other hand, the fuel consumption. A further disadvantage of the second embodiment described above resides in the fact that an exhaust gas recirculation rate of 0% cannot be established over the whole operating range, for example, when the pressure level in the charge air supply line is lower than the pressure level in the second exhaust gas line.
It is the object of the present invention to provide a supercharged internal combustion engine with exhaust gas recirculation, which includes a first cylinder group and a second cylinder group for which an exhaust gas recirculation rate of 0% can be set over a large operating range and the second cylinder group always includes only a minimum number of cylinders.
In an internal combustion engine with at least one turbo-charger including a compressor and a turbine, a charge air supply line for supplying compressed air from the compressor to the engine cylinders which are divided into a first group and a second group, an exhaust gas collection line having a first section connected to the first group of cylinders and a second section connected to the second group of cylinders, a first exhaust gas line which connects the first section of the exhaust gas collection line to the turbine, a recirculation line for returning exhaust gas from the second section of the exhaust gas collection line to the charge air supply line, and a first control device for controlling the exhaust gas flow from the second section to the first section of the exhaust gas collection line, a second control device is arranged in the first exhaust gas line for controlling the exhaust gas flow to the turbine and a third control device is arranged in the exhaust gas recirculation line for controlling the exhaust gas flow recirculated to the charge air supply line.
For large exhaust gas recirculation rates of for example 50%, the exhaust gas spender cylinder concept is combined with a high pressure exhaust gas recirculation arrangement. To this end, the internal combustion engine comprises, in addition to the control arrangement known from the state of the art by which the exhaust gas flow between the two sections of the exhaust gas collection line is determined, a second and a third control device. The second control device is arranged in the first exhaust gas line, which interconnects the first section of the exhaust gas collection line of the first cylinder group and the turbine of the exhaust gas turbocharger. By way of the second control device, the exhaust gas of the first cylinder group can be backed up. The backed-up exhaust gas than flows via the first control device to the second section of the exhaust gas collection line to which the exhaust gas from the second cylinder group is directed (spender cylinder), whereby the exhaust gas recirculation rate is increased. The third control device is arranged in the exhaust gas recirculation line which connects the second section of the exhaust gas collection line of the second cylinder group to the charge air supply line. By the third control device, the recirculation line can be closed, that is, an exhaust gas recirculation rate of 0% is provided.
A control device in the sense of the invention is an electrically mechanically or pneumatically operable control valve whose setting is determined by an electronic engine control unit via performance graphs depending on engine speed power output or ambient conditions. Ambient conditions are barometric pressure intake air temperature and operating state of the internal combustion engine, here meaning either a transient or stationary engine operation.
Using the three control devices, three different types of operation can be established: In the first type, an exhaust gas recirculation rate of 0% is provided and the exhaust gas of the second cylinder group is supplied to the first section of the exhaust gas collection line. Since now all of the exhaust gas is available for driving the turbocharger, the charging of the cylinders and the acceleration behavior of the supercharged internal combustion engine is improved; for example, in connection with an internal combustion engine-generator unit, this is advantageously used during a load increase.
In the second type of operation the exhaust gas recirculation rate is adjusted to a value in the area between zero and a certain limit value which is determined by the ratio of the number of cylinders in the second cylinder group and the total number of cylinders of the internal combustion engine. If the engine comprises for example sixteen cylinders and the first cylinder group comprises thirteen cylinder and the second cylinder group comprises three cylinders, the limit value for the exhaust gas recirculation rate is calculated as 19%. In the practice, this exhaust gas recirculation rate is set during normal operation above a predetermined power output value for example at an average pressure of 6 bar.
In the third type of operation, an exhaust gas recirculation rate exceeding the limit value is set, for example, up to 50%. The third type of operation permits an HCCI operation of the internal combustion engine.
In a particular embodiment of the invention, for an internal combustion engine with V-shaped cylinder arrangement a first cylinder bank (A-bank) includes cylinders of the first and the second group and the second cylinder bank (B-bank) includes only cylinders of the first group of cylinders. In this embodiment, then the exhaust gas collection line of the second cylinder bank is directly and exclusively connected to the turbine of the exhaust gas turbocharger via a second exhaust gas line. To prevent non-uniform loading a compensation line extending between the two exhaust gas lines of the two cylinder banks is provided.
In one alternative embodiment, the exhaust gas collection line of the second cylinder bank is in communication, via the second exhaust gas line, with the turbine and a fourth control device is arranged in the second exhaust gas line for controlling the exhaust gas flow while the exhaust gas collection line of the second cylinder bank (B-bank) is additionally in communication with the exhaust gas recirculation line via a connecting line which includes a throttle.
Preferred embodiments of the invention will be described below on the basis of the accompanying drawings.
The first cylinder bank A1 to A8 comprises a first cylinder group 6 and a second cylinder group 7. The first cylinder group 6 comprises the cylinders A1 to A5 whose exhaust gases are collected in the first section 9 of the exhaust gas collection line 8A. The second cylinder group 7 includes the cylinders A6 to A8 the exhaust gases of which are collected in the second section 10 of the exhaust gas collection line 8A. The second cylinder group 7 operates in accordance with the spender cylinder principle. By way of a first exhaust gas line 13, the exhaust gas is supplied to the turbine 4A of the turbocharger 2A. For the exhaust gas recirculation, an exhaust gas recirculation line 11 is provided, which is connected to the charge air supply lines 5A and 5B downstream of the charge air cooler 18 at the connecting points A and B. In the recirculation line 11, a heat exchanger 23 is arranged. The second cylinder bank B1 to B8 comprises exclusively cylinders of the first cylinder group 6. Their exhaust gases are collected together in the exhaust gas collection line 8B and conducted to the turbine 4B of the exhaust gas turbocharger 2B via a second exhaust gas line 16. The second cylinder bank B1 to B8 therefore does not contribute to the exhaust gas recirculation. Via a compensation line 17 however, a compensation between the exhaust gas flows can be achieved ahead of the turbines 4A and, respectively, 4B of the two exhaust gas turbochargers 2A and 2B can be achieved.
For setting the exhaust gas recirculation rate, three control devices 12, 14 and 15 are provided. A control device herein is to be understood to be an electrically, mechanically or pneumatically operated control arrangement whose setting is determined by an electronic engine control unit via performance graphs depending on engine operating parameters such as engine speed, engine power output, intake air temperature and operating state of the internal combustion engine, that is, in this case, a transient or stationary operating state. The control device 12 may also be in the form of fixed throttle whereby the construction expenditures are reduced. Further explanations of features shown in
The arrangement has the following functions:
In a first operating mode, an exhaust gas recirculation rate AGRR of zero is set by the electronic engine control unit, for example, during start-up operation of an internal combustion engine-generator arrangement which is provided as an emergency power supply unit. In the first operational phase, the first control device 12 is deactivated (normally open) so that the exhaust gas can flow, without restriction, from the second section 10 of the exhaust gas collection line 8A to the first section 9 thereof. The second control device 14 is also deactivated (normally open) so that the exhaust gas can flow from the exhaust gas collection line 8A of the first cylinder bank A1 to A8 without restriction to the turbine 4A of the exhaust gas turbocharger 2A. The third control device 15 is also deactivated (normally closed) whereby the exhaust gas recirculation line 11 is blocked.
In a second operating mode, an exhaust gas recirculation rate AGRR in a range larger than zero and smaller than a limit value GW (0≦AGRR≦GW) is set. The limit value GW is determined by the ratio of the number of cylinders of the second cylinder group 7 and the total number of cylinders. For the example shown in
In a third mode of operation, the so-called HCCI (Homogeneous Charge Compression Ignition) operation an exhaust gas recirculation rate AGRR larger than the limit value GW is set by the electronic engine control unit. In the HCCI operating mode, an exhaust gas recirculation rate of up to 50% is set. In
The
The advantages of the invention are:
Number | Date | Country | Kind |
---|---|---|---|
10 2007 011 680 | Mar 2007 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
4249382 | Evans et al. | Feb 1981 | A |
5517976 | Bachle et al. | May 1996 | A |
6752132 | Remmels et al. | Jun 2004 | B2 |
7165403 | Sun et al. | Jan 2007 | B2 |
20050274366 | Sato | Dec 2005 | A1 |
20060174621 | Chen et al. | Aug 2006 | A1 |
20100024416 | Gladden et al. | Feb 2010 | A1 |
20100077747 | Pierpont et al. | Apr 2010 | A1 |
Number | Date | Country |
---|---|---|
10 2004 015 018 | Oct 2005 | DE |
10 2005 018 221 | Oct 2006 | DE |
07293262 | Nov 1995 | JP |
Number | Date | Country | |
---|---|---|---|
20080216475 A1 | Sep 2008 | US |