Exhaust gas recirculation apparatus and method
First Claim
1. An exhaust gas recirculation apparatus adapted for use on an internal combustion diesel engine, comprising:
- an engine operational model, with said engine operational model capable of outputting at least one engine operational characteristic;
a feedback controller portion, said feedback controller portion receiving an emissions level feedback and generating a feedback control signal based on a difference between a predetermined EGR level and said emissions level feedback;
a feedforward controller portion receiving a plurality of engine sensor inputs and using said plurality of engine sensor inputs in conjunction with said engine operational model to generate a feedforward control signal, said feedforward control signal capable of changing an EGR exhaust gas flow before said plurality of engine sensor inputs show a deviation from a predetermined emissions level; and
a controller receiving said feedback control signal, said feedforward control signal, and accessing said engine operational model, said controller regulating an EGR exhaust gas flow in response to said feedback control signal, said feedforward control signal, and said engine operational model.
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Abstract
An exhaust gas recirculation method and apparatus adapted for use on an internal combustion engine. The apparatus includes an engine operational model, with the engine operational model capable of outputting at least one engine operational characteristic, a feedback controller portion, the feedback controller portion receiving an emissions level feedback and generating a feedback control signal based on a difference between a predetermined EGR level and the emissions level feedback, a feedforward controller portion receiving a plurality of engine sensor inputs and using the plurality of engine sensor inputs in conjunction with the engine operational model to generate a feedforward control signal, the feedforward control signal capable of changing an EGR exhaust gas flow before the plurality of engine sensor inputs show a deviation from a predetermined emissions level, and a controller receiving the feedback control signal, the feedforward control signal, and accessing the engine operational model, the controller regulating an EGR exhaust gas flow in response to the feedback control signal, the feedforward control signal, and the engine operational model.
85 Citations
23 Claims
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1. An exhaust gas recirculation apparatus adapted for use on an internal combustion diesel engine, comprising:
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an engine operational model, with said engine operational model capable of outputting at least one engine operational characteristic;
a feedback controller portion, said feedback controller portion receiving an emissions level feedback and generating a feedback control signal based on a difference between a predetermined EGR level and said emissions level feedback;
a feedforward controller portion receiving a plurality of engine sensor inputs and using said plurality of engine sensor inputs in conjunction with said engine operational model to generate a feedforward control signal, said feedforward control signal capable of changing an EGR exhaust gas flow before said plurality of engine sensor inputs show a deviation from a predetermined emissions level; and
a controller receiving said feedback control signal, said feedforward control signal, and accessing said engine operational model, said controller regulating an EGR exhaust gas flow in response to said feedback control signal, said feedforward control signal, and said engine operational model. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23)
generating an EGR engine model factor from an engine model constructed of engine operational characteristics;
generating an EGR feedback factor from a plurality of engine sensor inputs;
generating an EGR feedforward factor from said plurality of engine sensor inputs and said engine model; and
controlling an EGR exhaust gas flow based on said EGR engine model factor, said EGR feedback factor, and said EGR feedforward factor.
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15. The method of claim 14, wherein said engine operational model is constructed of average engine operational characteristics.
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16. The method of claim 14, wherein said engine operational model is constructed of measured engine operational characteristics.
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17. The method of claim 14, wherein said engine operational model comprises a plurality of data tables, with a data table of said plurality of data tables outputting an engine operational characteristic in response to an input from at least one engine sensor.
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18. The method of claim 14, wherein said engine operational model comprises a plurality of data tables, with a data table of said plurality of data tables outputting at least one engine operational characteristic in response to an input from at least one engine sensor, with said outputted at least one engine operational characteristic being selected from the group consisting of an engine torque characteristic, an emissions level characteristic, a NOx emissions level characteristic, and combinations thereof.
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19. The method of claim 14, wherein said engine operational model comprises a plurality of data tables, with a data table of said plurality of data tables outputting an engine operational characteristic in response to an input from at least one engine sensor, with said at least one engine sensor being selected from the group consisting of a throttle position input, a throttle position change input, an RPM input, an RPM change input, an exhaust oxygen level input, a NOx level input, an emissions level input, an engine coolant temperature input, an ambient temperature input, a humidity input, an inlet manifold temperature input, an inlet manifold pressure input, a percent load input, an engine timing input, a percent EGR input, an air-to-fuel ratio input, an aftertreatment condition input, and combinations thereof.
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20. The method of claim 14, wherein said EGR feedback factor is formed from engine sensors selected from the group consisting of a NOx level input, a RPM input, a percent load input, a throttle position, and combinations thereof.
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21. The method of claim 14, wherein said EGR feedforward factor is formed from engine sensors selected from the group consisting of a throttle position input, a throttle position change input, an RPM input, an RPM change input, an exhaust oxygen level input, a NOx level input, an emissions level input, an engine coolant temperature input, an ambient temperature input, a humidity input, an inlet manifold temperature input, an inlet manifold pressure input, a percent load input, an engine timing input, a percent EGR input, an air-to-fuel ratio input, an aftertreatment condition input, and combinations thereof.
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22. The method of claim 14, wherein said feedforward controller portion incorporates adaptive learning.
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23. The method of claim 14, wherein said feedforward controller portion further includes the steps of:
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generating an error difference between a predetermined desired EGR valve position and an actual EGR valve position;
comparing said error difference to a predetermined tolerance threshold;
determining whether said actual EGR valve position is capable of being corrected;
generating a weighting factor comprised of a predetermined percentage of said error difference if said error difference is greater than said predetermined tolerance threshold and if said actual EGR valve position is capable of being corrected;
adding said weighting factor to said feedforward factor;
subtracting said weighting factor from said feedback factor; and
storing said weighting factor in said engine model.
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Specification