Calibratable fault reactions in heavy-duty diesel engines

A method to operate an internal combustion engine by derating the engine in response to sensed emissions levels as compared to engine speed and engine torque and logging a fault.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention is related to a method to operate an internal combustion engine having electronic control to detect emissions, compare the emissions to stored emissions at given engine speeds and torques, and derate the engine if the actual emissions are outside the range of calculated emissions for a given engine speed or torque.

The present invention further relates to a method to operate an electronic controlled internal combustion engine to detect failures or impending failures in an emission system and derate at least one of engine speed and engine torque by an amount sufficient to reduce emissions levels to calibrated emissions levels and render an indication to an operator of the failure or impending failure. Once the engine is serviced, the sensed failure repaired, or at the next ignition cycle, whichever is first, the engine can be re-calibrated or reset to operate without derate of at least one of engine speed and engine torque.

2. Description of the Related Art

Tani et al., U.S. Pat. No. 7,168,240 discloses a control apparatus for an internal combustion engine that can detect degradation of a three-way catalyst with high accuracy and without causing deterioration in an exhaust. A pair of first and second air fuel ratio detectors are disposed in an exhaust system at locations upstream and downstream of a three-way catalyst for detecting a first and second air fuel ratio of an exhaust gas. A target oxygen change amount calculator calculates a target oxygen change amount in a three-way catalyst, and an oxygen change amount calculator calculates an oxygen change mount of the three-way catalyst from an amount of exhaust gas passing through the three-way catalyst in the first air fuel ratio. An air fuel ratio operator inversely controls the air fuel ratio to a rich side and the lean side with a prescribed air fuel ratio width each time the oxygen change amount reaches a target oxygen change amount.

Edwards, II et al., U.S. Pat. No. 7,010,417 discloses a system for determining the maximum available engine output torque that includes an engine speed sensor and a control computer to produce a fueling command for fueling an internal combustion engine. The computer is configured to produce a maximum available engine output torque as a function of the engine speed signal and the fueling command. In another embodiment, the system includes a control computer configured to produce the maximum available engine output torque value as a function of engine speed, at least one engine intake parameter associating an intake manifold coupled to an engine and an exhaust parameter associated with the exhaust gas structure coupled to the engine. And on engine exhaust parameter associated with an exhaust gas structure coupled to the engine. In either case, the engine control strategy is responsive to the maximum available engine torque value to control an engine driven accessory. One of the engine parameters that are examined for determining maximum fueling and/or maximum torque is exhaust parameters such as contents of the exhaust gas.

Hershey, U.S. Pat. No. 6,473,677 discloses a system for determining a maintenance schedule for a jet engine using at least remotely gathered environmental data. The system includes a remote monitor having a sensor for collecting the remotely gathered environmental data. A data pathway is connected to a remote monitor and a processor is connected to the data pathway and processes the remotely gathered environmental data collected by the remote monitor. An environmental database is connected to the data pathway and compiles and stores remotely gathered environmental data. A flight database is connected to the data pathway and compiles and stores flight data for the jet engine. The flight data includes at least thermal cycle data and time on wing data. The processors adapt to generate the maintenance schedule for the jet engine based on the remotely gathered environmental data and flight data.

Blosser, U.S. Pat. No. 5,941,918 discloses a vehicle on board diagnostic system in which the system determines whether the vehicle is continuously in compliance with regulatory emissions standards by sensing only hydrocarbon and carbon monoxide emissions at a position downstream from the three-way catalytic converter. All emission data sensed is correlated to basic vehicle function such as speed and sorted into a number of histograms corresponding to vehicle operating conditions specified by emissions regulations. The histograms are sampled in a statistically validated manner to determine if the vehicle complies with emissions standards. If a failure has occurred, further histogram diagnostic routines are sequentially implement to determine which emission of the vehicle has failed. An indicator is activated to alert the vehicle operator that an emissions failure has occurred.

Betts, et al., U.S. Pat. No. 5,447,031 discloses a dynamic waste gate failure detection apparatus for determining waste gate failure levels for individual internal combustion engines. The apparatus measures and stores intake boost pressures at times when the engine is producing higher boost pressure levels. The apparatus calculates a boost pressure limit value as a function of the stored boost pressures. A waste gate failure is indicated and the engine output power is derated when a boost pressure value exceeds the sum of the boost pressure limit value and a predetermined pressure differential. The ECM derates the engine to 80% of its normal operating abilities in order to prevent pressure from exceeding a level at which engine damage may occur.

Hapka, et al., U.S. Pat. No. 5,070,832 discloses an engine protection system wherein engine performance is derated as a function of the severity of a fluid parameter fault. In one schedule, engine power torque as a function of engine speed is gradually reduced or derated as the fluid parameter moves further out of normal operating range. With this derate schedule the engine will still run and the driver can still operate the vehicle, albeit at lower power levels than a healthy engine. In a second schedule for a severe fault condition, the maximum allowable engine speed is gradually reduced over a certain time period to a certain percentage of the normal maximum engine rpm. Both schedules permit continued operation of the engine in a “limp home” mode for the less severe faults, and as required after a more severe fault, to bring the vehicle safely to a stop. The engine protection system also stores an array of fault information that can be later accessed to investigate engine fluid parameter faults.

BRIEF SUMMARY OF THE INVENTION

The present invention is a method to operate an internal combustion engine, and particularly a heavy duty diesel engine, having electronic control unit (ECU) having a Motor Control Module (MCM) and a Component Powertrain Controller (CPC), each with non-volatile memory and in electronic communication with each other, the engine is further equipped with an emissions system with sensors in electronic communication with the MCM to transmit data signals indicative of exhaust system emissions and failures or impending failures, the method being to force a maximum available engine torque and speed whenever an emission related fault is detected. The method comprises the steps of:

a) determining whether a detected error is an emission related fault;

b) determining actual engine speed and engine torque and emissions levels and comparing actual them with a calculated emission level stored in memory for said actual engine speed and engine torque;

c) de-rating at least said engine torque a predetermined amount as a fault reaction at actual engine speed sufficient to reduce actual emissions to calculated emissions; and

d) setting a fault in memory and said engine control unit.

A more detailed understanding of the invention will become apparent upon reading the specification as set forth below.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

FIG. 1illustrates a vehicle powertrain system10in accordance with one non-limiting aspect of the present invention. The system10may provide power for driving any number of vehicles, including on-highway trucks, construction equipment, marine vessels, stationary generators, automobiles, trucks, tractor-trailers, boats, recreational vehicle, light and heavy-duty work vehicles, and the like.

The system10may be referred to as an internal combustion driven system wherein fuels, such as gasoline and diesel fuels, are burned in a combustion process to provide power, such as with a spark or compression ignition engine14. The engine14may be a diesel engine that includes a number of cylinders18into which fuel and air are injected for ignition as one skilled in the art will appreciate. The engine14may be a multi-cylinder compression ignition internal combustion engine, such as a 4, 6, 8, 12, 16, or 24 cylinder diesel engines, for example. It should be noted, however, that the present invention is not limited to a particular type of engine or fuel.

Exhaust gases generated by the engine14during combustion may be emitted through an exhaust system20. The exhaust system20may include any number of features, including an exhaust manifold and passageways to deliver the emitted exhaust gases to a particulate filter assembly30, which in the case of diesel engines is commonly referred to as a diesel particulate filter. Optionally, the system20may include a turbocharger proximate the exhaust manifold for compressing fresh air delivery into the engine14. The turbocharger, for example, may include a turbine32and a compressor34, such as a variable geometry turbocharger (VGT) and/or a turbo compound power turbine. Of course, the present invention is not limited to exhaust systems having turbochargers or the like.

The particulate filter assembly30may be configured to capture particulates associated with the combustion process. In more detail, the particulate filter assembly30may include an oxidation catalyst (OC) canister36, which in includes an OC38, and a particulate filter canister42, which includes a particulate filter44. The canisters36,42may be separate components joined together with a clamp or other feature such that the canisters36,42may be separated for servicing and other operations. Of course, the present invention is not intended to be limited to this exemplary configuration for the particulate filter assembly30. Rather, the present invention contemplates the particulate filter assembly including more or less of these components and features. In particular, the present invention contemplates the particulate filter assembly30including only the particulate filter44and not necessarily the OC canister36or substrate38and that the particulate filter44may be located in other portions of the exhaust system20, such as upstream of the turbine32.

The OC38, which for diesel engines is commonly referred to as a diesel oxidation catalyst, may oxidize hydrocarbons and carbon monoxide included within the exhaust gases so as to increase temperatures at the particulate filter44. The particulate filter44may capture particulates included within the exhaust gases, such as carbon, oil particles, ash, and the like, and regenerate the captured particulates if temperatures associated therewith are sufficiently high. In accordance with one non-limiting aspect of the present invention, one object of the particulate filter assembly30is to capture harmful carbonaceous particles included in the exhaust gases and to store these contaminates until temperatures at the particulate filter44favor oxidation of the captured particulates into a gas that can be discharged to the atmosphere.

The OC and particulate filter canisters36,42may include inlets and outlets having defined cross-sectional areas with expansive portions there between to store the OC38and particulate filter44, respectively. However, the present invention contemplates that the canisters36,42and devices therein may include any number configurations and arrangements for oxidizing emissions and capturing particulates. As such, the present invention is not intended to be limited to any particular configuration for the particulate filter assembly30.

To facilitate oxidizing the capture particulates, a doser50may be included to introduce fuel to the exhaust gases such that the fuel reacts with the OC38and combusts to increase temperatures at the particulate filter44, such as to facilitate regeneration. For example, one non-limiting aspect of the present invention contemplates controlling the amount of fuel injected from the doser as a function of temperatures at the particulate filter44and other system parameters, such as air mass flow, ECR temperatures, and the like, so as to control regeneration. However, the present invention also contemplates that fuel may be included within the exhaust gases through other measures, such as by controlling the engine14to emit fuel with the exhaust gases.

An air intake system52may be included for delivering fresh air from a fresh air inlet54through an air passage to an intake manifold for introduction to the engine14. In addition, the system52may include an air cooler or charge air cooler56to cool the fresh air after it is compressed by the compressor34. Optionally, a throttle intake valve58may be provided to control the flow of fresh air to the engine14. Optionally, the throttle intake valve58may also be provided to control the flow of EGR gases to the engine14or control both fresh air and EGR gases64to the engine14. The throttle valve58may be a manually or electrically operated valve, such as one which is responsive to a pedal position of a throttle pedal operated by a driver of the vehicle. There are many variations possible for such an air intake system and the present invention is not intended to be limited to any particular arrangement. Rather, the present invention contemplates any number of features and devices for providing fresh air to the intake manifold and cylinders, including more or less of the foregoing features.

An exhaust gas recirculation (EGR) system64may be optionally provided to recycle exhaust gas to the engine14for mixture with the fresh air. The ECR system64may selectively introduce a metered portion of the exhaust gasses into the engine14. The EGR system64, for example, may dilute the incoming air charge and lower peak combustion temperatures to reduce the amount of oxides of nitrogen produced during combustion. The amount of exhaust gas to be recirculated may be controlled by controlling an EGR valve66and/or in combination with other features, such as the turbocharger. The EGR valve66may be a variable flow valve that is electronically controlled. There are many possible configurations for the controllable EGR valve66and embodiments of the present invention are not limited to any particular structure for the EGR valve66.

The EGR system64in one non-limiting aspect of the present invention may include an EGR cooler passage70, which includes an EGR cooler72, and an EGR cooler bypass74. The EGR valve66may be provided at the exhaust manifold to meter exhaust gas through one or both of the EGR cooler passage70and bypass74. Of course, the present invention contemplates that the EGR system64may include more or less of these features and other features for recycling exhaust gas. Accordingly, the present invention is not intended to be limited to any one EGR system and contemplates the use of other such systems, including more or less of these features, such as an EGR system having only one of the EGR cooler passage or bypass.

A cooling system80may be included for cycling the engine14by cycling coolant there through. The coolant may be sufficient for fluidly conducting away heat generated by the engine14, such as through a radiator. The radiator may include a number of fins through which the coolant flows to be cooled by air flow through an engine housing and/or generated by a radiator fan directed thereto as one skilled in the art will appreciated. It is contemplated, however, that the present invention may include more or less of these features in the cooling system80and the present invention is not intended to be limited to the exemplary cooling system described above.

The cooling system80may operate in conjunction with a heating system84. The heating system84may include a heating core, a heating fan, and a heater valve. The heating core may receive heated coolant fluid from the engine14through the heater valve so that the heating fan, which may be electrically controllable by occupants in a passenger area or cab of a vehicle, may blow air warmed by the heating core to the passengers. For example, the heating fan may be controllable at various speeds to control an amount of warmed air blown past the heating core whereby the warmed air may then be distributed through a venting system to the occupants. Optionally, sensors and switches86may be included in the passenger area to control the heating demands of the occupants. The switches and sensors may include dial or digital switches for requesting heating and sensors for determining whether the requested heating demand was met. The present invention contemplates that more or less of these features may be included in the heating system and is not intended to be limited to the exemplary heating system described above.

A controller92, such as an electronic control module or engine control module, may be included in the system10to control various operations of the engine14and other system or subsystems associated therewith, such as the sensors in the exhaust, EGR, and intake systems. Various sensors may be in electrical communication with the controller via input/output ports94. The controller92may include a microprocessor unit (MPU)98in communication with various computer readable storage media via a data and control bus100. The computer readable storage media may include any of a number of known devices which function as read only memory102, random access memory104, and non-volatile random access memory106. A data, diagnostics, and programming input and output device108may also be selectively connected to the controller via a plug to exchange various information there between. The device108may be used to change values within the computer readable storage media, such as configuration settings, calibration variables, instructions for EGR, intake, and exhaust systems control and others.

The system10may include an injection mechanism114for controlling fuel and/or air injection for the cylinders18. The injection mechanism114may be controlled by the controller92or other controller and comprise any number of features, including features for injecting fuel and/or air into a common-rail cylinder intake and a unit that injects fuel and/or air into each cylinder individually. For example, the injection mechanism114may separately and independently control the fuel and/or air injected into each cylinder such that each cylinder may be separately and independently controlled to receive varying amounts of fuel and/or air or no fuel and/or air at all. Of course, the present invention contemplates that the injection mechanism114may include more or less of these features and is not intended to be limited to the features described above.

The system10may include a valve mechanism116for controlling valve timing of the cylinders18, such as to control air flow into and exhaust flow out of the cylinders18. The valve mechanism116may be controlled by the controller92or other controller and comprise any number of features, including features for selectively and independently opening and closing cylinder intake and/or exhaust valves. For example, the valve mechanism116may independently control the exhaust valve timing of each cylinder such that the exhaust and/or intake valves may be independently opened and closed at controllable intervals, such as with a compression brake. Of course, the present invention contemplates that the valve mechanism may include more or less of these features and is not intended to be limited to the features described above.

In operation, the controller92receives signals from various engine/vehicle sensors and executes control logic embedded in hardware and/or software to control the system10. The computer readable storage media may, for example, include instructions stored thereon that are executable by the controller92to perform methods of controlling all features and sub-systems in the system10. The program instructions may be executed by the controller in the MPU98to control the various systems and subsystems of the engine and/or vehicle through the input/output ports94. In general, the dashed lines shown inFIG. 1illustrate the optional sensing and control communication between the controller and the various components in the powertrain system. Furthermore, it is appreciated that any number of sensors and features may be associated with each feature in the system for monitoring and controlling the operation thereof.

In one non-limiting aspect of the present invention, the controller92may be the DDEC controller available from Detroit Diesel Corporation, Detroit, Mich. Various other features of this controller are described in detail in a number of U.S. patents assigned to Detroit Diesel Corporation Further, the controller may include any of a number of programming and processing techniques or strategies to control any feature in the system10. Moreover, the present invention contemplates that the system may include more than one controller, such as separate controllers for controlling system or sub-systems, including an exhaust system controller to control exhaust gas temperatures, mass flow rates, and other features associated therewith. In addition, these controllers may include other controllers besides the DDEC controller described above.

FIG. 2. is a schematic representation of an electronic engine control as set forth in the present invention. Specifically, engine controller92has an MCM118that is calibratable to operate the engine MCM receives data signal inputs from various sensors and is able to receive data signals indicative of various engine operating parameters such as engine speed elapsed status of each are MU120ignition status122and engine torque124. The MCM stores engine configuration data126in ROM memory therein indicating the operational status of the engine. The engine configuration data is communicated a CPC2128and stored in volatile memory. The CPC2receives input from an ECAN over SAE J1587 or J1989 data link indicative of the actual engine speed, engine torque and operational status of systems that affect or may affect the exhaust emissions of the engine. The CPC2unit compares the engine data parameters and permissible emissions levels stored in memory with the actual engine operating parameters and actual exhaust emissions levels. When it is determined the actual exhaust emission levels are out of specification, the information is communicated to the MCM, which logs the fault and determines at least one of a derate factors for engine speed and a derate factor for engine torque that will reduce emission to levels consistent with the derated engine speed and engine torque. The derates are then effected and new engine configuration data are communicated to the CPC and the CPC receives data signals over the ECAN via a J1587 or J1939 data link and applies those inputs to the derated situation and the cycle reports itself. Preferably, the engine speed and torque are derated for an amount sufficient to bring engine operation in compliance with emissions, up to a 10% derate from maximum of engine speed and engine torque. An indicator signal may be included, such as a light on the instrument panel, to alert an operator that a fault has been indicated and the engine is operating in a derated state. A service tool may read the fault, the system failure is repaired or serviced and the CPC is recalibrated and the fault is deleted.

FIG. 3is a software flow chart indicating one method136of the present invention. Step138is determining whether a monitoring unit (MU) error is emissions related. If no, step140is continuing normal engine operation. If yes, step142is determining whether the error is indicative of a hardware failure or impending malfunction. If yes, step144is shut engine down to prevent further damage to the engine. If the determination in Step142is no, step146is determine whether the emission levels at actual engine speed and/or engine torque are outside a range of calculated emission levels at actual engine speed or engine torque. If the determination in step146is no, step148is continue normal engine operation. If the determination in step146is yes, step150is store fault in RAM as a fault copy. Step152is derate the engine speed and/or torque a sufficient amount to conform the engine operation to the calculated emissions. Generally, the derate is up to about a 10% decrease of the maximum torque/speed available. In addition, the derate occurs only in response to the fault copy and is achieved either by reducing the total torque curve available to the engine, or is reduced by a scalar value as a function of engine speed. Preferably, the MCM reports the derate torque available to the CPC through the fault react copy. Step154is activate a warning indicator to alert an operator that a fault has occurred. Step156is resetting faults after service or after the fault has been repaired or after each ignition cycle, whichever occurs first.