The present disclosure relates to exhaust gas recirculation systems for internal combustion engines.
Internal combustion engines may include exhaust gas recirculation systems that are configured to redirect exhaust gas into the air intake system of the engine to reduce emissions.
A vehicle includes an internal combustion, an air intake system, an exhaust system, and an exhaust gas recirculation system. The internal combustion engine has at least one cylinder. The air intake system is configured to deliver air to the at least one cylinder. The exhaust system has at least one conduit configured to direct exhaust gas away from the at least one cylinder. The exhaust gas recirculation system has a at least one tube, and a U-shaped exhaust gas mixer. The at least one tube is configured to direct the exhaust gas away from the at least one conduit. The U-shaped exhaust gas mixer is configured to direct the exhaust gas from the at least one tube, into the air intake system. The U-shaped exhaust gas mixer forms a pre-mixing cavity, the pre-mixing cavity configured to maintain an exhaust gas flow pressure during a dispersing and entraining of the exhaust gas with the intake air as the intake air flows through the U-shaped exhaust mixer prior to delivering the intake air and exhaust gas to the at least one cylinder.
An exhaust gas recirculation system for an engine includes a conduit, and a U-shaped exhaust gas mixer. The conduit is configured to direct exhaust gas away from an exhaust manifold. The U-shaped exhaust gas mixer is configured to direct exhaust gas from the conduit, into an engine air intake system. The U-shaped exhaust gas mixer is arranged with a pre-mixing cavity, the pre-mixing cavity is configured to disperse the exhaust gas and entraining the exhaust gas into an intake air flow prior to distribution into an intake manifold of an engine.
An exhaust gas recirculation mixer for an engine exhaust system includes a housing having an exhaust gas inlet an intake air inlet, and at least one pre-mixing conduit configured between the exhaust gas inlet and the intake air inlet. The pre-mixing conduit configured to distribute and disperse a volume of exhaust gas prior to entraining the exhaust gas in at least a portion of an intake air main flow and prior to distribution into the engine.
Embodiments of the present disclosure are described herein. It is to be understood, however, that the disclosed embodiments are merely examples and other embodiments may take various and alternative forms. The figures are not necessarily to scale; some features could be exaggerated or minimized to show details of specific components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the embodiments. As those of ordinary skill in the art will understand, various features illustrated and described with reference to any one of the figures may be combined with features illustrated in one or more other figures to produce embodiments that are not explicitly illustrated or described. The combinations of features illustrated provide representative embodiments for typical applications. Various combinations and modifications of the features consistent with the teachings of this disclosure, however, could be desired for specific applications or implementations.
Exhaust gas recirculation (EGR) is used on diesel and gas internal combustion engines and is an important method to reduce NOx emissions via peak combustion temperature reduction and on gas engines to reduce CO2 via reduced pump work and knock mitigation. EGR is taken off from the exhaust system and reintroduced into the intake system, where it needs to be mixed prior to entering the engine cylinders. The flow of EGR is typically unsteady due to the discrete number of engine cylinders and asymmetric takeoff location where one cylinder is contributing more exhaust flow to the EGR system than others.
With the more stringent emission criteria being established, especially with low NOx and CO2 emission requirements, there is a strong need to improve the engine exhaust gas recirculation distribution uniformity. However, due to the unsteady EGR flow current EGR systems require long mixing times, very elaborate EGR mixers and/or a revised EGR takeoff such as a dual bank EGR takeoff, which all add cost, consume package space and in the case of the EGR mixing length the elaborate EGR mixers increase pressure losses and reduce flow capabilities of the exhaust gas and an intake/charge air. Thus, to meet the low NOx and CO2 emission and avoid these system challenges with the elaborate EGR mixers, a low pressure drop EGR pre-mixer is needed to provide an initial cavity for the unsteady EGR gases to mix and diffuse into a volume before being entrained into the main flow for further micro mixing of the EGR with the intake or charge air. This EGR pre-mixer may largely reduce the issue of the EGR being entrained into the main flow of charge air as discrete slugs of EGR, which results in a lean or rich EGR zone in the main intake air flow that must diffuse over time. Thus, the innovative simple EGR pre-mixer, disclosed herein, provides a low-pressure loss mixer that eliminates the very long mixing lengths, the high-pressure losses and unevenly mixed EGR caused by the current elaborate EGR mixers.
In the current disclosure, a low-pressure loss pre-mixer, which introduces the EGR into a volume configured adjacent the main flow of intake air where diffusion of the EGR occurs. More specifically, once the volume of EGR is introduced it is then entrained into the main flow in steady fashion without significant pressure losses, which avoids expensive EGR system elements such as backpressure valves and EGR pumps that are typically required to flow the necessary EGR rates. The main goal is to enable improved exhaust gas mixing while minimizing the pressure losses in the system to promote EGR flow dispersion into a pre-mixing zone or chamber prior to entrainment into the main flow of intake air. The exhaust gas recirculation flow is introduced and dispersed into the premixing zone and then entrained into the main flow where further mixing occurs prior to distribution to the engine cylinders. This new pre-mixer allows for a shorter mixing length while providing a homogenous EGR distribution from cylinder-to-cylinder. Thus, the pre-mixer, as disclosed, enables better EGR mixing while allow for reduced EGR pressure losses, reduced EGR mixing lengths and includes lower cost asymmetric EGR takeoffs thereby eliminating the need for expensive EGR system components, such as, the elimination of EGR backpressure valves and EGR pumps used to maintain the required amount of EGR in the system.
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The engine 12 includes an air intake system 18. The air intake system 18 may include a set of pipes, tubes, or conduits 20 that are configured to deliver an air supply to each cylinder to provide the oxygen required for the combustion of fuel. The set of pipes, tubes, or conduits 20 may include one or more first intake pipes tubes or conduits 25 housing a throttle valve 28, one or more second air intake pipes tubes or conduits 26 directly connected to one or more air intake manifolds 22, the intake manifolds 22 directly deliver the intake air 64 into each cylinder. The first intake pipe, tube, or conduit 25 of the set of pipes, tubes, or conduits 20 may draw intake air 64 directly from an ambient environment or may receive air from a compressor 21 of a turbocharger 24 or supercharger. If a turbocharger 24 or supercharger is delivering the intake air 64 into the air intake system 18, the intake air 64 may first be sent to a charge air cooler 60. From the charge air cooler 60, the intake air 64 may then pass by the throttle valve 28, through the second air intake pipes tubes or conduits 26 and the air intake manifolds 22 and into the cylinders which may be in at least one of the first bank of cylinders 14 and of the second bank of cylinders 16. The throttle valve 28 is adjusted by an operator of the vehicle 10 by depressing an accelerator pedal (not shown) in conjunction with an adjustment to the amount of fuel being delivered into the cylinders based on a power or torque demand of the engine 12 or the wheels of the vehicle 10, which is interpreted by a controller (not shown) based on a position of the accelerator pedal.
The controller may be a powertrain control unit (PCU), may be part of a larger control system, and may be controlled by various other controllers throughout the vehicle 10, such as a vehicle system controller (VSC). It should therefore be understood that the controller and one or more other controllers can collectively be referred to as a “controller” that controls various actuators in response to signals from various sensors to control functions such as starting/stopping the engine 12, operating the engine 12 to provide wheel torque, select or schedule shifts of a transmission of the vehicle 10, etc.
The controller may include a microprocessor or central processing unit (CPU) in communication with various types of computer readable storage devices or media. Computer readable storage devices or media may include volatile and nonvolatile storage in read-only memory (ROM), random-access memory (RAM), and keep-alive memory (KAM), for example. KAM is a persistent or non-volatile memory that may be used to store various operating variables while the CPU is powered down. Computer-readable storage devices or media may be implemented using any of a number of known memory devices such as PROMs (programmable read-only memory), EPROMs (electrically PROM), EEPROMs (electrically erasable PROM), flash memory, or any other electric, magnetic, optical, or combination memory devices capable of storing data, some of which represent executable instructions, used by the controller in controlling the engine 12 or vehicle 10.
As illustrated, the engine 12 also includes an exhaust system 30. The exhaust system 30 is configured to direct exhaust gas 66 away from the cylinders of the engine 12. The exhaust system 30 may include a first set of exhaust gas pipes, tubes, or conduits 32 that are configured to direct exhaust gas 66 away from the first bank of cylinders 14. The first set of exhaust pipes, tubes, or conduits 32 may include a first exhaust manifold 34 that directly receives the exhaust gas 66 from the first bank of cylinders 14. The exhaust system 30 may include a second set of exhaust pipes, tubes, or conduits 36 that are configured to direct exhaust gas 66 away from the second bank of cylinders 16. The second set of exhaust pipes, tubes, or conduits 36 may include a second exhaust manifold 38 that directly receives the exhaust from the second bank of cylinders 16. The exhaust gas 66 may be channeled to one or more exhaust tail pipes (not shown), via the first set of exhaust pipes, tubes, or conduits 32 and the second set of exhaust pipes, tubes, or conduits 36, wherein the exhaust gas 66 is dumped into the ambient environment outside the vehicle 10. At least one intermediate component of the exhaust system 30 may be disposed between the exhaust manifolds 34, 38 and the one or more tailpipes (not shown). Such intermediate component may include one or more mufflers, one or more catalytic converters, and a turbine 40 if the vehicle 10 includes the turbocharger 24, etc.
The engine 12 also include an exhaust gas recirculation system 42. The exhaust gas recirculation system 42 may include a first exhaust gas recirculation pipe, tube, or conduit 44 that is configured to direct a first portion of the exhaust gas 66 away from the first set of exhaust pipes, tubes, or conduits 32 of the exhaust system 30. More specifically, the first exhaust gas recirculation pipe, tube, or conduit 44 may be configured to direct the first portion of the exhaust gas 66 away from the first exhaust manifold 34, thereby directing the first portion of exhaust gas 66 away from the first bank of cylinders 14. The first exhaust gas recirculation pipe, tube, or conduit 44 may be comprised of one or more pipes, tubes, or conduits. A first exhaust gas recirculation valve 46 may be disposed along the first exhaust gas recirculation pipe, tube, or conduit 44 to control the amount of exhaust flowing through the first exhaust gas recirculation pipe, tube, or conduit 44. The first exhaust gas recirculation pipe, tube, or conduit 44 directs the first portion of the exhaust gas 66 into an exhaust gas recirculation cooler 48. The first portion of the exhaust gas 66 is then directed toward a mixer 50 via a second pipe, tube, or conduit 45.
The exhaust gas recirculation system 42 may include a third exhaust gas recirculation pipe, tube, or conduit 52 that is configured to direct a second portion of the exhaust gas 66 away from the second set of pipes, tubes, or conduits 36 of the exhaust system 30. More specifically, the third exhaust gas recirculation pipe, tube, or conduit 52 may be configured to direct the second portion of the exhaust gas 66 away from the second exhaust manifold 38, thereby directing the second portion of exhaust gas away 66 from the second bank of cylinders 16. The third exhaust gas recirculation pipe, tube, or conduit 52 may be comprised of one or more pipes, tubes, or conduits. A second exhaust gas recirculation valve 53 may be disposed along the third exhaust gas recirculation pipe, tube, or conduit 52 to control the amount of exhaust gas 66 flowing through the third exhaust gas recirculation pipe, tube, or conduit 52. The third exhaust gas recirculation pipe, tube, or conduit 52 directs the second portion of the exhaust gas 66 into the exhaust gas recirculation cooler 48. The first and second portions of the exhaust gas 66 may be combined into a single flow path or fluid path in the exhaust gas recirculation cooler 48 or the first and second portions of exhaust gas may be segregated from each other when passing through the exhaust gas recirculation cooler 48. The second portion of the exhaust gas 66 is then directed toward the mixer 50 via a fourth pipe, tube, or conduit 54. The fourth pipe, tube, or conduit 54 may be comprised of one or more pipes, tubes, or conduits.
It should be understood that the second pipe, tube, or conduit 45 and the fourth pipe, tube, or conduit 54 may be directly connected to the mixer 50 or alternatively the second and fourth conduits may be connected to the mixer 50 through a Y-pipe, Y-tube or Y-conduit 58 as the mixer 50 may include a single inlet 62. Generally, the mixer 50 flows the intake air 64 past and entraining the exhaust gas 66, into the pipes, tubes, or conduits 26 of the air intake system 18 for introduction into the air intake manifold 22. This mixture of entraining the exhaust gas 66 with the intake air 64 results in a homogenous charge air 68 for use in at least one of the first bank of cylinders 14 and second bank of cylinders 16 within a tight device package footprint over a short distance without the use of a backpressure valve or an EGR pump.
As discussed previously and illustrated herein, at least in
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Additionally, it should be understood that the specific dimensions of the U-shaped housing 120 are configured to create a small envelope package for the mixer 100. The shape and transitioned surfaces of the pre-mixing cavity 136 and the mixing chamber 128 provide walls and surfaces, discussed above that may result in agitation and turbulent flow of the intake air 64 and the exhaust gas 66 to promote entraining the exhaust gas 66 within the intake air 64 to create the homogenous charge air 68 that flows out of the U-shaped housing 120 and into the intake manifold 22 to be burned during a combustion cycle of the engine 12 while reducing any EGR pressure loss and shortening the mixing distance from the exhaust gas 66 introduction into the U-shaped housing 120 to a homogenous charge air 68 without the use of a backpressure valve or an EGR pump as shown, at least, in
It should be understood that the designations of first, second, third, fourth, etc. for any component, state, or condition described herein may be rearranged in the claims so that they are in chronological order with respect to the claims. Additionally, the different embodiments disclosed herein may be implemented individually or in any combination, the specific arrangements are examples and do not limit any combination.
The words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the disclosure. As previously described, the features of various embodiments may be combined to form further embodiments that may not be explicitly described or illustrated. While various embodiments could have been described as providing advantages or being preferred over other embodiments or prior art implementations with respect to one or more desired characteristics, those of ordinary skill in the art recognize that one or more features or characteristics may be compromised to achieve desired overall system attributes, which depend on the specific application and implementation. As such, embodiments described as less desirable than other embodiments or prior art implementations with respect to one or more characteristics are not outside the scope of the disclosure and may be desirable for particular applications.