Abstract:
The method for regeneration of a diesel particulate filter of a vehicle equipped with a hybrid engine, wherein the temperature of the exhaust exiting the diesel engine is increased above a predetermined level by increasing load thereon, through optimization of interaction between the diesel particulate filter aftertreatment system and the hybrid engine control through messaging via a communication bus is disclosed. The load on the engine may be increased with or without the assistance of the electric motor/generator of the hybrid engine, and will not affect required acceleration/deceleration of the vehicle.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present disclosure relates to a method for diesel particulate filter regeneration. More specifically, the method relates to diesel particulate filter regeneration in a vehicle equipped with a hybrid power train. 
     2. Prior Art 
     There is no known prior art related to this method for diesel particulate filter regeneration in a vehicle equipped with a hybrid power train. 
     SUMMARY OF THE INVENTION 
     Provided is a method for regeneration of a diesel particulate filter of a vehicle equipped with a hybrid power train, wherein the temperature of the exhaust exiting a diesel engine is increased above a predetermined level by increasing load on the diesel engine when regeneration occurs. Interaction between the diesel particulate filter aftertreatment system and the hybrid power train is controlled through messaging via a communication bus. The load on the diesel engine may be increased with or without the assistance of the electric motor of the hybrid power train and will not affect accelerator/deceleration of the vehicle. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWING 
         FIG. 1  presents a logic flow diagram of the steps of the method of the present invention. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring now to  FIG. 1  in greater detail, a representative embodiment of the present method provides a solution for particulate filter regeneration in a vehicle provided with a hybrid power train and involves messaging over a communication bus to indicate that regeneration is required. Such messaging will ultimately increase or maintain the load on a diesel engine allowing for increase or maintenance of exhaust temperature as required for regeneration. 
     The diesel particulate filter (DPF) undergoes regeneration in response to filter flow being reduced due to soot build up within the DPF. During normal operating conditions, a hybrid power train, in which load is allocated between a diesel engine and an electric motor/generator, may not always produce exhaust temperatures hot enough to accomplish regeneration of the DPF. The present method will request that the electric motor/generator act as a generator to increase load to the diesel engine during regeneration in order to rapidly increase exhaust temperatures required for regeneration, if the battery pack of the vehicle is below maximum charge, which will result in a decrease in time required to regenerate the diesel particulate filter. If, on the other hand, the charge on the battery pack is at maximum, the logic will shut down the electric motor/generator until regeneration is no longer necessary, and the load will be completely transferred to the diesel engine, again decreasing the time taken to regenerate the DPF. The method optimizes interactions between the DPF aftertreatment system and the hybrid power train control (ECM). If the battery pack is at a maximum and the after treatment system is equipped with a resistive element the heating element can be activated thereby heating the feedstream gas to the after treatment inlet and providing a uniform load on the engine. The affect will be to maintain maximum battery charge and reduce the duration of the regeneration event and associated emissions. 
     It will be understood that the regeneration is accomplished by getting the exhaust temperature hot enough, long enough to burn off the soot that has accumulated in the filter. The higher the load on the diesel engine, the hotter the exhaust and the faster the filter is cleared. The addition of an optional heating element can promote this action during initial heating phase. 
     It will further be understood that when the vehicle is equipped with such hybrid power train, and the electric motor/generator is assisting the diesel engine in motor mode, load is taken away from the diesel engine because the electric motor/generator thereof is “sharing” the load with the diesel engine. 
     It will be further understood that the method sends and receives information or data via a communication bus. 
     An overview and explanation of what occurs are found in the flowchart of  FIG. 1  and as set forth below. 
     Step  1 . The logic of the method starts. 
     Step  2 . The logic first determines if the vehicle is equipped with a hybrid power train. If not, the logic moves on to Step  3 . If so, the logic moves on to Step  4 A. 
     Step  3 . The logic ends. It will be understood that each time the logic ends within this scheme, the hybrid power train reverts to its hybrid operation, with the electric motor sharing the load with the diesel engine, as necessary. 
     Step  4 A. The logic next checks to see if a regeneration of the Diesel Particulate Filter (DPF) is needed. The determination is based on sensing for a pressure drop across the DPF continually at Step  4 B. It will be understood that, as the filter accumulates soot, the passages there through become plugged, producing a pressure drop, due to a restriction in through flow. When the sensed pressure drop becomes greater than a threshold, a flag is set at Step  4 B indicating that regeneration of the DPF is required. If no flag is set, the logic moves on to Step  5 . If the flag is set, the logic moves on to Step  6 A.
 
Step  5 . The logic ends.
 
Step  6 A. Here the logic determines if the load factor on the diesel engine is below a critical threshold for DPF regeneration from a sensing of the instantaneous load factor at Step  6 B. If not, the logic proceeds to Step  7 . If so, it will be understood that the exhaust will not get hot enough to clean the DPF and the logic proceeds to Step  8 A.
 
Step  7 . The logic ends.
 
Step  8 A. Once it is determined that the load factor on the diesel engine is below the critical level, the logic determines the state of charge on the battery pack that is connected to the electric motor/generator of the hybrid power train from sensing the state of battery charge at Step  8 B. If the battery pack is at full charge, the electric motor/generator cannot be used as a generator because the battery pack will be damaged by overcharging thereof and the logic proceeds to Step  9 . If the charge on the battery pack is below full charge, the logic proceeds to Step  10 A.
 
Step  9 . The logic causes the electric motor/generator to be disabled and the additional load previously shared by the electric motor is returned to the diesel engine to produce a load factor over the critical threshold, the vehicle reverting to a “non-hybrid”, diesel engine configuration while the regeneration of the DPF is occurring to ensure the load factor stays above the critical threshold for such regeneration. If the electric motor/generator is disabled, the logic intermittently moves on to Step  14 .
 
Step  10 A. If the battery pack is not at maximum charge, the electric motor/generator is utilized as a generator to charge the battery pack at Step  10 C and to apply an additional load to the diesel engine by commanding the electric motor/generator on, which causes the electric motor/generator to absorb torque from the diesel engine, creating a “torque error” as sensed at Step  10 B, and the logic moves on to Step  11 A.
 
Step  11 A. At this step, the logic computes the torque output of the diesel engine from an input of the DDT at Step  11 B and an input of the torque absorbed by the electric motor/generator, acting as a generator, at Step  11 C, by subtracting the absorbed torque input (negative torque) from the DDT input, to obtain a higher value, which higher value of diesel engine torque must be decreased to maintain the DDT at the required level. The logic then moves on to Step  11 D.
 
Step  11 D. Here the “extra” torque required as calculated at Step  11 A, to maintain the Driver&#39;s Demand Torque (DDT) constant is output to the engine control module (ECM) The logic moves on to Step  12 .
 
Step  12 . The load on the diesel engine is increased by the amount the electric motor/generator is absorbing there from, as determined at Step  11 D, to maintain the Driver&#39;s Demand Torque (DDT) constant and the logic moves on to Step  13 .
 
Step  13 A. If Drive/Power Train Torque (DTT) equals Driver&#39;s Demand Torque (DDT) (DTT=DDT) as determined from a sensing of DDT at Step  13 B and DTT at Step  13 C, then nothing need change and the logic circles back to Point  2 . Alternatively, if DTT does not equal DDT, the logic circles back to Point  1 , as the method needs to be stepped through again to determine what has changed.
 
Step  14 . Here, as follows Step  9  described above, when the electric motor/generator has been disabled, the logic polls the PDF regeneration required input intermittently to see if regeneration is still required. If so, the logic returns to Point  1 . If not, the logic moves on to Step  15 . Step  15 . The logic commands the electric motor/generator to turn back on and the logic moves on to Step  16 .
 
Step  16 . The logic ends.
 
     As described above, the method of the present invention provides a number of advantages, some of which have been described above and others of which are inherent in the invention. Also, modifications may be proposed to the method without departing from the teachings herein. Accordingly, the scope of the invention is only to be limited as necessitated by the accompanying claims.