This invention relates to internal combustion engines, and more particularly to such engines having one or more cylinders dedicated to production of recirculated exhaust.
In an internal combustion engine system having dedicated EGR (exhaust gas recirculation), one or more cylinders of the engine are segregated and dedicated to operate in a rich combustion mode. Because of the rich combustion, the exhaust gases from the dedicated cylinder(s) have increased levels of hydrogen and carbon monoxide. Rich combustion products such as these are often termed “syngas” or “reformate”.
Dedicated EGR engines use the reformate produced by the dedicated cylinder(s) in an exhaust gas recirculation (EGR) system. The hydrogen-rich reformate is ingested into the engine for subsequent combustion by the non-dedicated cylinders and optionally by the dedicated cylinder(s). The reformate is effective in increasing knock resistance and improving dilution tolerance and burn rate. This allows a higher compression ratio to be used with higher rates of EGR and reduced ignition energy, leading to higher efficiency and reduced fuel consumption.
A more complete understanding of the present embodiments and advantages thereof may be acquired by referring to the following description taken in conjunction with the accompanying drawings, in which like reference numbers indicate like features, and wherein:
The following description is directed to systems and methods for a vehicle, such as an automobile, having an engine with one or more dedicated EGR (D-EGR) cylinders. A D-EGR cylinder can operate at any equivalence ratio because, when its exhaust is recirculated, that exhaust will never exit the engine before passing through another cylinder operating at an air-fuel ratio for which the vehicle's exhaust aftertreatment system is designed. This allows the D-EGR cylinder to run rich, which produces hydrogen (H2) and carbon monoxide (CO) at levels that enhance combustion flame speeds, combustion, and knock tolerance of all the cylinders.
A feature of the invention is the recognition of further improvements that can be made to the fuel system of an engine having one or more D-EGR cylinders. Typically, D-EGR cylinders do not use a separate fuel system. To operate the D-EGR cylinders rich of stoichiometric while the main cylinders generally operate at a lean or stoichiometric A/F ratio, the pulse width (PW) of the injectors of the D-EGR cylinders are longer than the injectors of the main cylinders. In particular in a split intake manifold D-EGR engine, the D-EGR cylinder(s) can be operated at equivalence ratios greater than 2. This can result in a fuel pressure reduction in the common fuel rail. This in turn can lead to unwanted pressure oscillations in the common fuel rail, leading to unequal amounts of fuel being injected for the following cylinders. The inconsistency in fuel delivery within the different cylinders can lead to cylinder-to-cylinder imbalance, and imprecise fueling in individual cylinders. In consistent common rail pressure can further lead to deteriorated atomization, increased CO, HC, PM, PN, and NOx emissions, poor combustion and engine efficiency, less charge cooling, reduced over-fueling tolerance due to locally very rich and lean pockets causing poor ignitability, and a less than desired D-EGR cylinder fueling rate.
Thus, this description is further directed to an improved fuel system and method to improve the fuel delivery for all cylinders in a D-EGR engine or any other engine that uses a common fuel rail for cylinders with different fuel demands. It should be understood that the improved fueling method and system described herein is useful with any engine having one or more cylinders that are to be “over-fueled”, with D-EGR cylinders being an example of a type of “over-fueled” cylinder.
Conventional Dedicated EGR Systems (Prior Art)
The dedicated EGR cylinder 101d may be operated at any desired air-fuel ratio. All of its exhaust may be recirculated back to the intake manifold 102.
In the embodiment of
Engine 100 is equipped with a turbocharger, specifically a compressor 104a and a turbine 104b.
Although not explicitly shown, all cylinders 101 are in fluid communication with a fuel delivery system for introducing fuel into the cylinders. As described below in connection with
In the example of this description, the EGR loop 114 joins the intake line downstream the compressor 104a. A mixer 130 mixes the fresh air intake with the EGR gas. A main throttle 105 is used to control the amount of intake (fresh air and EGR) into the intake manifold 102.
In the embodiment of this description, a three-way valve 170 controls the flow of dedicated EGR to the EGR loop or to the exhaust system. Valve 170 may be used to divert all or some of the EGR from the EGR loop 114 to a bypass line 171 that connects to the exhaust line, downstream the turbine 104b and upstream the three-way catalyst 120. Other configurations for controlling EGR flow are possible, such as an EGR valve just upstream of mixer 130.
The four-cylinder dedicated EGR system 100 with a single dedicated cylinder can provide a 25% EGR rate. In other dedicated EGR systems, there may be a different number of engine cylinders 101, and/or there may be more than one dedicated EGR cylinder 101d. In general, in a dedicated EGR engine configuration, the exhaust of a sub-group of cylinders can be routed back to the intake of all the cylinders, thereby providing EGR for all cylinders. In some embodiments, the EGR may be routed to only the main cylinders.
After entering the cylinders 101, the fresh-air/EGR mixture is ignited and combusts. After combustion, exhaust gas from each cylinder 101 flows through its exhaust port and into exhaust manifold 103. From the exhaust manifold 103, exhaust gas then flows through turbine 104b, which drives compressor 104a. After turbine 104b, exhaust gas flows out to a main exhaust line 119 to a three-way catalyst 120, to be treated before exiting to the atmosphere.
As stated above, the dedicated EGR cylinder 101d can operate at any equivalence ratio because its recirculated exhaust will not exit the engine before passing through a non-dedicated EGR cylinder 101 operating at a stoichiometric air-fuel ratio. Because only stoichiometric exhaust leaves the engine, the exhaust aftertreatment device 120 may be a three-way catalyst.
To control the air-fuel ratio, exhaust gas may be sampled by an exhaust gas oxygen (EGO) sensor. Both the main exhaust line 122 and the EGR loop 114 may have a sensor (identified as 166a and 166b), particularly because the dedicated EGR cylinder may be operated at a different air-fuel ratio than non-dedicated cylinders. If a dedicated EGR cylinder is run rich of stoichiometric A/F ratio, a significant amount of hydrogen (H2) and carbon monoxide (CO) may be formed. In many engine control strategies, this enhanced EGR is used to increase EGR tolerance by increasing burn rates, increasing the dilution limits of the mixture and reducing quench distances. In addition, the engine may perform better at knock limited conditions, such as improving low speed peak torque results, due to increased EGR tolerance and the knock resistance provided by hydrogen (H2) and carbon monoxide (CO).
An EGR control unit 150 has appropriate hardware (processing and memory devices) and programming for controlling the EGR system. It may be incorporated with a larger more comprehensive control unit. Regardless of division of tasks, it is assumed there is controlling to receive data from any sensors described herein, and perform various EGR control algorithms. Control signals are generated for the various valves and other actuators of the EGR system. Fuel delivery is controlled such that the dedicated EGR cylinder may operate at an equivalence ratio greater than that of the main cylinders.
D-EGR engine 200 does not have bypass valve 170 or bypass line 171, but is otherwise similar in structure and design to D-EGR engine 100.
Fuel Cam Lobe Modifications
In the example of
Another specific example is a piston type fuel pump. Fuel pump 30 could also be a diaphragm type pump having a filling stroke driven with a cam. A roller follower fuel pump is another example of a cam-driven fuel pump.
More specifically, fuel pump 30 is a mechanical fuel pump, driven by a camshaft 31 or other shaft driven by the crankshaft. As the camshaft 31 turns, a cam 32 actuates a plunger within fuel pump 30. The displacement of the plunger (or piston or other mechanical device) during the filling stroke determines the amount of fuel that is pumped.
In
Fuel is delivered to injectors 180 for injection into the cylinders. An advantage of the invention is that injectors 180 can be direct injectors, and supplied fuel in a range of 40 to 200 bar from high pressure fuel pump 30.
The cam 50 of
Depending on over-fueling requirements and desired flow rates, the fuel pump stroke for the D-EGR cylinder(s) can be increased by more than 100%. To maintain the same overall fuel flow rates, the strokes of the remaining cylinders (main cylinders) can be reduced accordingly to achieve the desired engine output. Otherwise the overall fuel mass flow would increase. The duration of the displacement phases remains constant.
The first four different D-Phi's are for an engine having a conventional fuel pump cam, such as shown in
For the stoichiometric operated engine (D-Phi=1), all cylinders have nearly the same injected fuel mass. This results in the least amount of cylinder-to-cylinder variations. However, once the D-EGR cylinder over-fueling rates increase, the fuel quantity discrepancy between the main cylinders also increases. Different fuel quantities lead to unequal torque production, increase combustion instabilities, emissions, NVH, and cause reduced fuel efficiency. The main cylinder that follows the D-EGR cylinder in the firing order (cylinder #2) received up to 10% less fuel than the main cylinders with firing orders before the D-EGR cylinder.
Using the proposed cam design (shown as D-Phi=1.67 modified lobe in
The results of the modified cam illustrated in
For a significantly increased fuel flow of the D-EGR cylinder 101d at maximum engine power, the fuel pump 30 will be oversized for the main cylinders 101. For any fuel system, the control system that is actuating the fuel pump 30 will have some degree of error with each pumping event. This is caused by errors in engine synchronization and variability in how the valve closes. Oversizing may result in some increase in error. The effective displacement of the fuel pump 30 is a function of the actual displacement, volumetric efficiency, and error in the control system.
One method to reduce error in the effective displacement is to provide an individual displacement for each cylinder 101. A reduction of the displacement by 30% would translate to a 30% reduction in effective displacement error for the main cylinders 101. This approach could allow for use of existing engine control units and fuel pump hardware while still resulting in more consistent fuel pressure control.
Number | Name | Date | Kind |
---|---|---|---|
3439655 | Pierre | Apr 1969 | A |
5261366 | Regueiro | Nov 1993 | A |
5313924 | Regueiro | May 1994 | A |
6230689 | Tengroth | May 2001 | B1 |
6405709 | Carroll, III | Jun 2002 | B1 |
7552720 | Borg | Jun 2009 | B2 |
20020096145 | Ricco | Jul 2002 | A1 |
20020117155 | Takeda | Aug 2002 | A1 |
20100083824 | Rastelli | Apr 2010 | A1 |
20140069082 | Alger, II | Mar 2014 | A1 |
20140261322 | Geckler | Sep 2014 | A1 |
20140331975 | Glugla | Nov 2014 | A1 |
20140360461 | Ulrey | Dec 2014 | A1 |
20150136051 | Kunz | May 2015 | A1 |
20150219028 | Gingrich | Aug 2015 | A1 |
20150226169 | Williams | Aug 2015 | A1 |
20150300285 | Macfarlane | Oct 2015 | A1 |
20160230712 | Akinyemi | Aug 2016 | A1 |
20160333830 | Henry | Nov 2016 | A1 |
20170276125 | Ishikura | Sep 2017 | A1 |
20170342969 | Mueller | Nov 2017 | A1 |
20180223777 | Gukelberger | Aug 2018 | A1 |
20190078522 | Tamaskar | Mar 2019 | A1 |
Number | Date | Country | |
---|---|---|---|
20190383242 A1 | Dec 2019 | US |