1. Field of the Invention
The present invention relates generally to systems and methods for controlling temperature and total hydrocarbon slip, and more particularly, to systems and methods for controlling temperature and total hydrocarbon slip of an exhaust system.
2. Technical Background
It is known to control the temperature within a particulate filter of a diesel engine exhaust system to regenerate the filter at a desired temperature. Known control systems for controlling the temperature may operate adequately under steady-state conditions. However, such systems may not provide acceptable control performance under various dynamic conditions, such as when engine speed and/or torque are dynamically changing.
The following presents a simplified summary of the invention in order to provide a basic understanding of some example aspects of the invention. This summary is not an extensive overview of the invention. Moreover, this summary is not intended to identify critical elements of the invention nor delineate the scope of the invention. The sole purpose of the summary is to present some concepts of the invention in simplified form as a prelude to the more detailed description that is presented later.
In one example aspect, a method is provided for controlling an exhaust stream temperature at a point along an exhaust system. The exhaust system includes an oxidation catalyst, a particulate filter including an outlet, and a fuel injector for injecting fuel into an exhaust stream at a location upstream from the outlet of the particulate filter. The method includes the steps of providing an oxidation catalyst model, monitoring a condition of an exhaust stream, and calculating a hydrocarbon fuel injection flow rate for the fuel injector based on the oxidation catalyst model. The method further includes the step of controlling an operation of the fuel injector based on the calculated hydrocarbon fuel injection flow rate, to control the exhaust stream temperature at the point along the exhaust system. The method still further includes the steps of determining an error in the oxidation catalyst model based on the monitored condition, and changing the oxidation catalyst model to reduce the error.
In another example aspect, a method is provided for controlling a total hydrocarbon slip exiting an exhaust system. The exhaust system includes an oxidation catalyst, a particulate filter including an outlet, and a fuel injector for injecting fuel into an exhaust stream at a location upstream from the outlet of the particulate filter. The method comprises the steps of providing an oxidation catalyst model, monitoring a condition of the exhaust stream, calculating a post fuel injection flow rate, and calculating a limiting total hydrocarbon slip flow rate based on the oxidation catalyst model. The method further includes the step of controlling an operation of the fuel injector at a hydrocarbon fuel injection flow rate based on a smaller one of the post fuel injection flow rate and the limiting total hydrocarbon slip flow rate, to control the total hydrocarbon slip exiting the exhaust system. The method further includes the steps of determining an error in the oxidation catalyst model based on the monitored condition, and changing the oxidation catalyst model to reduce the error.
In still another example aspect, a control system is provided for an exhaust system. The control system includes an oxidation catalyst, a particulate filter including an outlet, and a fuel injector for injecting fuel into an exhaust stream at a location upstream from the outlet of the particulate filter, wherein the exhaust stream flows through the particulate filter. The exhaust system further includes a processor for controlling an operation of the fuel injector based on an oxidation catalyst model. The processor is programmed to monitor a condition of the exhaust stream, control a hydrocarbon fuel injection flow rate based on the oxidation catalyst model to control a total hydrocarbon slip exiting the exhaust system, and control the operation of the fuel injector to control an exhaust stream temperature at a point along the exhaust system. The processor is further programmed to determine an error in the oxidation catalyst model based on the monitored condition of the exhaust system, and change the oxidation catalyst model to reduce the error.
In yet another example aspect, a virtual sensor for an exhaust system is provided. The virtual sensor comprises a controller having an input. The controller is configured to monitor a condition of the exhaust system through the input. The controller is also configured to model an oxidation catalyst of the exhaust system based on the monitored condition, and calculate a total hydrocarbon slip for the exhaust system based on a result of modeling the oxidation catalyst.
These and other features, aspects and advantages of the present invention are better understood when the following detailed description of the invention is read with reference to the accompanying drawings, in which:
In the following detailed description, for purposes of explanation and not limitation, example embodiments disclosing specific details are set forth to provide a thorough understanding of the present invention. However, it will be apparent to one having ordinary skill in the art, having had the benefit of the present disclosure, that the present invention may be practiced in other embodiments that depart from the specific details disclosed herein. Moreover, descriptions of well-known devices, methods, and materials may be omitted so as not to obscure the description of the present invention. Finally, wherever applicable, like reference numerals refer to like elements.
An example system for controlling temperature and total hydrocarbon (THC) slip of an exhaust system 10 is shown in
In example embodiments, the exhaust system 10 carries the exhaust stream 30 from an internal combustion engine (not shown), such as a diesel engine. It is to be appreciated that the engine does not need to be a diesel engine, and could be another type of internal combustion engine, such as a gasoline engine, for example. Nevertheless, the following description refers to a diesel system and controls for a diesel system for ease of explaining example embodiments, but it is understood that other (i.e., non-diesel) systems may be similarly controlled.
The exhaust system 10 includes the DOC 14, which can be included within a catalytic converter. The exhaust system 10 further includes the DPF 16 for filtering particulates from the exhaust stream 30 before the exhaust stream 30 is discharged through a tailpipe 32 into the atmosphere. Various types of DPF 16 can be used in accordance with the present invention. In one example, the DPF 16 can comprise porous ceramic honeycomb filters. It is useful to periodically clean out, i.e., “regenerate”, the DPF 16 by removing accumulated particles that have been filtered by the DPF 16. In a diesel after-treatment system, the DPF 16 can be regenerated by burning the accumulated particulates out of the DPF 16 by controlling the temperature of the exhaust stream 30. However, care should be taken so that the DPF 16 is not overheated to a point at which damage occurs. For example, too high of a regeneration temperature can cause cracks within the DPF 16 or reduce filtration efficiency and lifetime.
Example regeneration temperatures can be between 550° C. and 650° C., although temperatures below and above that range are also contemplated. Under normal operating conditions, the temperature of the exhaust stream 30 may not be hot enough to initiate and sustain a complete DPF 16 regeneration. Therefore, the exhaust system 10 can include the DOC 14 located near the DPF 16 to heat the exhaust stream 30. In
In certain applications, such as heavy or light duty diesel applications, supplemental fuel can be injected. For example, a fuel injector can be provided by way of an in-cylinder injection configured to be located upstream from the DOC 14. In another example, as shown schematically in
As shown in
A more detailed example of the system for controlling temperature and THC slip of the exhaust system 10 is shown in
The operation of the exhaust system 10 is nonlinear, and the PI controller 34 alone, without the DOC model 36, may be unable to adequately control the regeneration temperature of the DPF 16, due to the nonlinearity of the system. However, the GMC methodology places the DOC model 36 of a portion of the exhaust system 10 into the control structure. For example, the DOC model 36 could model the nonlinear behavior of the DOC 14. The DOC model 36 tends to cancel the nonlinearity existing in the exhaust system 10. The approximated linear system 42 can be seen in
Turning to
Referring to
The GMC controller 38 of the controller 12 determines the appropriate HC fuel injection flow rate 54 {dot over (m)}hc and, therefore, controls the temperature and THC slip of the exhaust system 10. The controller 12 is configured to model the DOC 14 based on the monitored conditions through one or more sensors 22, 24, 26, 28.
In one example embodiment, the fuel injector 20 is operated by an actual HC fuel injection flow rate 54 {dot over (m)}hc. In order to obtain the actual HC fuel injection flow rate 54 {dot over (m)}hc, a post fuel injection flow rate 56 {dot over (m)}pi is first determined based on the target temperature 40 Tout* for the DOC outlet 14b, the observed DOC outlet 14b temperature Tout, and DOC inlet 14a conditions (CO2, {dot over (m)}exh, and Tin). A first summer 44 receives the signals of Tout* and Tout, and determines a current control error Tout*−Tout. The current control error Tout*−Tout is an input to the PI controller 34. Based on the current control error Tout*−Tout between the target temperature 40 Tout* and the observed DOC outlet 14b temperature Tout, the PI controller 34 calculates the required time derivative of the control variable (i.e., dTout/dt) for the next control step to be performed by the DOC model 36. The PI controller 34 calculates dTout/dt and outputs dTout/dt to the DOC model 36. The DOC model 36 determines the appropriate post fuel injection flow rate 56 {dot over (m)}pi and outputs it to the comparator 50a of the THC slip controller 50. The DOC model 36 can also output a limiting THC slip Sliplim to the THC slip calculator 50b of the THC slip controller 50. The limiting THC slip Sliplim is applied to calculate the limiting THC slip flow rate 58 {dot over (m)}pi,lim by the THC slip calculator 50b. The limiting THC slip flow rate 58 {dot over (m)}pi,lim outputted by the THC slip calculator 50b is applied as an input to the comparator 50a. The actual HC fuel injection flow rate 54 {dot over (m)}hc is the output of the comparator 50a, and is the smaller one of the post injection flow rate {dot over (m)}pi and the limiting THC slip flow rate 58 {dot over (m)}pi,lim. A corresponding control signal of the HC fuel injection flow rate 54 {dot over (m)}hc is sent to the fuel injector 20 for controlling its operation.
In an example embodiment, the calculated post fuel injection flow rate 56 {dot over (m)}pi can be directly sent from the DOC model 36 to the fuel injector 20 without passing through the THC slip controller 50. In this case, the HC fuel injection flow rate 54 {dot over (m)}hc is the same as the post fuel injection flow rate 56 {dot over (m)}pi,, and the controller 12 only controls the temperature in the exhaust stream 30 and DPF 16 but does not control the THC slip exiting the exhaust system 10.
In another example embodiment, when the controller 12 controls both the temperature and the THC slip of the exhaust stream 30, a virtual sensor for the exhaust system 10 is provided, wherein the output of the virtual sensor is the THC slip calculated by the DOC model 36 and the THC slip controller 50. Referring to
Moreover, as shown in
In example embodiments, the controller 12 can further determine an error in the DOC model 36 based on the monitored condition of the exhaust system 10, and thus, change the DOC model 36 to reduce the error based on an open-loop adjustment parameter and a closed-loop adjustment parameter.
The open-loop adjustment parameter reflects the degradation of the DOC 14, and can be modeled by an expression:
where k is a reaction rate constant, t is time, and A and b are constants.
As shown in
Example methods for controlling temperature and THC slip in accordance with aspects of the present invention will now be described. In example embodiments, methods can comprise the steps of providing the DOC model 36.
The primary chemical reaction that occurs within the DOC 14 is:
HC+O2→CO2+H2O+ΔH
where HC represents the hydrocarbons introduced into the exhaust stream 30 via the fuel injector 20, and ΔH represents the heat released by the reaction. The heat released by the reaction ΔH raises the temperature of the exhaust stream 30 to regenerate the DPF 16. A continuous stirred tank reactor (CSTR) model can be used to capture the thermodynamics of the primary chemical reaction. The CSTR model can be generically expressed in the following format:
where Tout is the DOC outlet 14b temperature, Tout
It is to be appreciated that the PI controller 34 used in the GMC controller 38 has a different output than a PI controller found in conventional control systems. In a conventional control system, a PI controller would directly determine the manipulated variable, such as the HC fuel injection flow rate 54 {dot over (m)}hc. However, in the GMC controller 38, the PI controller 34 does not output the manipulated variable (the DOC model 36 outputs the manipulated variable). The PI controller 34 outputs the required time derivative of the control variable dTout/dt. The PI controller 34 specifies dTout/dt as follows:
where the term K1(Tout*−Tout) specifies that when the DOC outlet 14b temperature Tout deviates from the target temperature 40 Tout*, the fuel injector 20 should be controlled such that Tout* is approached as specified by dTout/dt=K1(Tout*−Tout). The term K2∫(Tout*−Tout)dt specifies that the change of dTout/dt should bring the DOC outlet 14b temperature Tout close to a zero offset. It is to be appreciated that values for K1 and K2 can be determined based on the desired operating performance of the PI controller 34. For example, values for K1 and K2 can be determined based on a desired shape (e.g., temperature overshoot amount) and speed of the exhaust system process response.
As stated above, the PI controller 34 calculates dTout/dt and outputs dTout/dt to the DOC model 36. The DOC model 36 models a portion of the exhaust system 10, such as the DOC 14, and controls the operation of the fuel injector 20 based on the dTout/dt signal received from the PI controller 34. Conventional methodologies for controlling the temperature and THC slip of the exhaust stream 30 generally involve open-loop control, which are either difficult for calibration or limited in accuracy. One control alternative can be the DOC model 36. The DOC model 36 considers both catalyst kinetics and mass transfer limitations, and takes account for the degradation of DOC 14 as well. The DOC model 36 can provide a conversion efficiency prediction on the full operation range and full lifetime of the DOC 14, and thus, improve the controller 12 performance. As compared to known conventional methods, the DOC model 36 and the THC slip controller 50 can provide an accurate THC slip prediction for the on-board diagnostics, which can be used for controlling THC slip during light-off and peak flow conditions. The THC slip control scheme can be useful for applications when there is no catalyst used downstream of DOC 14, thus all the THC slip emits from the tailpipe 32.
The DOC model 36 is provided based on the CSTR model and can further include a plurality of parameters, such as the THC conversion efficiency η, the mass transfer rate constant km, the kinetics rate constant kr, the THC slip Slip, and the limiting THC slip Sliplim.
With a CSTR model, the THC conversion efficiency η can be derived, in standard temperature and pressure format, in the following format:
where C1, C2, n, m, t and a are constants, T0 is a DOC 14 body temperature, Pg is an exhaust gas pressure, yO2 is a molar fraction, Ea is an activation energy, R is gas constant, and Ts is a solid temperature. The open-loop adjustment parameter determined in equation (1) may also be included in C2 calculation in equation (6).
The analytic solution of equations (4-6) provides a convenient way to calibrate the kinetics and mass transfer parameters. The THC conversion efficiency η derived from the equations is supplied as one of the plurality of parameters to the DOC model 36 for temperature control and THC slip control.
In example embodiments, methods further include a step of monitoring a plurality of conditions of the exhaust stream 30 in the DOC inlet 14a by one or more sensors 24, 26, 28 connected to the DOC model 36. The DOC inlet 14a conditions in the exhaust stream 30 include the oxygen concentration CO2, mass flow rate {dot over (m)}exh, and temperature Tin. The monitored conditions are sent to DOC model 36 and used for other steps.
In example embodiments, after monitoring the conditions, the controller 12 can utilize the DOC model 36 with the plurality of parameters and one or more DOC inlet 14a conditions to calculate the HC fuel injection flow rate 54 {dot over (m)}hc and control the operation of the fuel injector 20 and, therefore, the DOC outlet 14b temperature Tout.
In one example embodiment, the HC fuel injection flow rate 54 {dot over (m)}hc is the same as the post fuel injection flow rate 56 {dot over (m)}pi. In this example embodiment, the method is for controlling the temperature of the exhaust system 10 instead of controlling the THC slip exiting the exhaust system 10.
A closed-form solution for the DOC model 36 can be determined based on the CSTR model of the DOC 14, to calculate the HC fuel injection flow rate 54 {dot over (m)}hc as follows:
where Cp
In another example embodiment, the HC fuel injection flow rate 54 {dot over (m)}hc is controlled by the limiting THC Sliplim in order to control the THC slip exiting the exhaust system 10 as well. In this embodiment, the method includes the step of calculating the post fuel injection flow rate 56 {dot over (m)}pi using the same equation (7) above. The method further includes calculating the limiting THC slip flow rate 58 {dot over (m)}pi,lim by the DOC model 36 and THC slip calculator 50b. The limiting THC slip flow rate 58 {dot over (m)}pi,lim is calculated using the following formula:
where Sliplim is the limiting THC slip, {dot over (m)}pi,lim is the limiting THC slip flow rate 58, η is the THC conversion efficiency. The THC conversion efficiency η can be calculated by equations (4-6).
In this example embodiment, the method further includes a step of choosing the smaller value between the post fuel injection flow rate 56 {dot over (m)}pi and the limiting THC slip flow rate 58 {dot over (m)}pi,lim by the comparator 50a of the THC slip controller 50, and applying this value as the actual HC fuel injection flow rate 54 {dot over (m)}hc to control the operation of the fuel injector 20.
The method in the embodiment gives extremely accurate THC slip prediction for the full operation range of DOC 14. The THC slip can be predicted by the formula:
Slip={dot over (m)}hc(1−η) (9)
where Slip is the THC slip, {dot over (m)}hc is the actual HC fuel injection flow rate 54, η is the THC conversion efficiency.
This method with both kinetics and mass transfer calculations, works well both in mass-transfer-controlled regions (i.e. high flow condition) and kinetics-controlled regions (i.e. near lighted-off temperature). Thus, a protection strategy can be developed by calculating the limiting THC slip flow rate 58 {dot over (m)}pi,lim according to equation (8). The post fuel injection flow rate 56 {dot over (m)}pi is then limited by the limiting THC slip flow rate 58 {dot over (m)}pi,lim. This is useful to regulate the THC slip coming out of DOC 14, especially for temperature near light-off and high-flow conditions. This also becomes helpful when a bare DPF 16 is used in the exhaust system 10 and THC slip has to be controlled using DOC 14 only.
In example embodiments, in addition to controlling the temperature and THC slip based on the DOC model 36, methods can further comprise the steps of determining an error in the DOC model 36 based on the monitored conditions and changing the DOC model 36 based on the open-loop adjustment parameter and the closed-loop adjustment parameter to reduce the error.
As discussed above, equation (1) includes the open-loop adjustment parameter while equation (7) includes the closed-loop adjustment parameter Model_adj. Therefore, the controller 12 can determine errors in its own process model and compensate for such errors by dynamically adjusting the model. For instance, the DOC model 36 compensates for major system disturbances caused by changing exhaust system conditions, for example, changing conditions that occur at the DOC inlet 14a.
Model_adj is updated dynamically based on a monitored condition or conditions of the exhaust system 10. In an example, the controller 12 updates a value for Model_adj with each control step. During each control step, the controller 12 determines a model mismatch Tout−Tout
It is to be appreciated that the estimated DOC outlet 14b temperature Tout
where dTout/dt is the rate of change of the observed DOC outlet 14b temperature in one control interval, and Δt is a time differential.
Having determined Tout
where L is an arbitrary constant coefficient for determining the speed or magnitude for updating Model_adj. Increasing the value for L will increase the degree to which Model_adj is changed with each control step. However, too large a value for L can cause undesired oscillation errors for Tout−Tout
It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit and scope of the invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.
This application is a divisional of and claims the benefit of priority to U.S. patent application Ser. No. 12/786,758, filed on May 25, 2010, the content of which is relied upon and incorporated herein by reference in its entirety. U.S. patent application Ser. No. 12/786,758 claims the benefit of priority to U.S. provisional application No. 61/182,390, filed on May 29, 2009.
Number | Name | Date | Kind |
---|---|---|---|
5419122 | Tabe et al. | May 1995 | A |
5829248 | Clifton | Nov 1998 | A |
6202406 | Griffin et al. | Mar 2001 | B1 |
6968682 | Leuz et al. | Nov 2005 | B1 |
7062907 | Kitahara | Jun 2006 | B2 |
7111455 | Okugawa et al. | Sep 2006 | B2 |
7137248 | Schaller | Nov 2006 | B2 |
7293407 | Adler et al. | Nov 2007 | B2 |
7337607 | Hou et al. | Mar 2008 | B2 |
7367182 | Takahashi et al. | May 2008 | B2 |
20060213188 | Matsuno et al. | Sep 2006 | A1 |
20070130923 | Dye et al. | Jun 2007 | A1 |
20070199312 | Kapparos et al. | Aug 2007 | A1 |
20070220865 | Cunningham et al. | Sep 2007 | A1 |
20100050607 | He et al. | Mar 2010 | A1 |
Number | Date | Country | |
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20130192205 A1 | Aug 2013 | US |
Number | Date | Country | |
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61182390 | May 2009 | US |
Number | Date | Country | |
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Parent | 12786758 | May 2010 | US |
Child | 13796666 | US |