Abstract: A diesel oxidation catalyst (DOC) testing system includes a DOC that is located in an exhaust system of a vehicle. A control module verifies proper operation of the DOC during a post-fuel injection process in an engine of the vehicle. The control module computes a predicted temperature of exhaust gases at an output of the DOC that corresponds with proper operation of the DOC during the post-fuel injection process, determines an actual temperature of the exhaust gases during the post-fuel injection process, and activates an alarm indicator when a difference between the predicted temperature and the actual temperature is greater than a first predetermined value. A first temperature sensor is located downstream from the DOC in the exhaust system. The first temperature sensor communicates with the control module, generates the actual temperature, and transmits the actual temperature to the control module.

Abstract: A temperature sensor rationality control system for an exhaust treatment system having an oxidation catalyst includes an oxidation catalyst inlet temperature sensor that generates an inlet temperature signal and an oxidation catalyst outlet temperature sensor that generates an outlet temperature signal. A control module determines whether a difference based on the inlet temperature signal and the outlet temperature signal is below a difference threshold when an exhaust temperature is within a threshold range.

Abstract: A temperature sensor rationality control system for an exhaust treatment system having an oxidation catalyst includes an oxidation catalyst inlet temperature sensor that generates an inlet temperature signal and an oxidation catalyst outlet temperature sensor that generates an outlet temperature signal. A control module determines whether a difference based on the inlet temperature signal and the outlet temperature signal is below a difference threshold when an exhaust temperature is within a threshold range.

Abstract: A diesel oxidation catalyst (DOC) testing system includes a DOC that is located in an exhaust system of a vehicle. A control module verifies proper operation of the DOC during a post-fuel injection process in an engine of the vehicle. The control module computes a predicted temperature of exhaust gases at an output of the DOC that corresponds with proper operation of the DOC during the post-fuel injection process, determines an actual temperature of the exhaust gases during the post-fuel injection process, and activates an alarm indicator when a difference between the predicted temperature and the actual temperature is greater than a first predetermined value. A first temperature sensor is located downstream from the DOC in the exhaust system. The first temperature sensor communicates with the control module, generates the actual temperature, and transmits the actual temperature to the control module.

Abstract: A method for adjusting the timing of an internal combustion engine having a crankshaft and a camshaft to manage the thermal load on the engine. The method includes the step of altering the timing of the camshaft with respect to the timing of the crankshaft to reduce thermal load on the engine. Preferably, the step of altering the timing of the camshaft is accomplished with a variable camshaft phaser.

Abstract: A method and apparatus for controlling the amount of fuel used in combustion during open-loop run mode of a internal combustion engine. A lookup table calibrated to a fuel with a low driveability index is used to make a fueling decision for open-loop run mode. Then, at least one of the following indicators of fuel problems is monitored: the engine misfire detection system, the engine speed and the manifold absolute pressure. If any of these indicators detect a problem with the amount of fuel the engine is receiving, a fuel increase is calculated and implemented in one or more steps. A problem is indicated if an engine misfire is detected, the engine speed drops below a predetermined threshold value, or the manifold absolute pressure rises above a predetermined threshold value. The fuel increase is limited by a calculation based upon a fuel with a high driveability index.

Abstract: A method for adjusting the timing of an internal combustion engine having a crankshaft and a camshaft to manage the thermal load on the engine. The method includes the step of altering the timing of the camshaft with respect to the timing of the crankshaft to reduce thermal load on the engine. Preferably, the step of altering the timing of the camshaft is accomplished with a variable camshaft phaser.

Abstract: A method and apparatus for controlling the amount of fuel used in combustion during open-loop run mode of a internal combustion engine. A lookup table calibrated to a fuel with a low driveability index is used to make a fueling decision for open-loop run mode. Then, at least one of the following indicators of fuel problems is monitored: the engine misfire detection system, the engine speed and the manifold absolute pressure. If any of these indicators detect a problem with the amount of fuel the engine is receiving, a fuel increase is calculated and implemented in one or more steps. A problem is indicated if an engine misfire is detected, the engine speed drops below a predetermined threshold value, or the manifold absolute pressure rises above a predetermined threshold value. The fuel increase is limited by a calculation based upon a fuel with a high driveability index.

Abstract: An improved fuel compensation method for a variable cam phase engine which predicts the phase of the cam at the midpoint of valve overlap and uses the predicted cam phase to compensate a base fuel pulse for the corresponding amount of diluent. If the cam phase is in transition to a desired value, the cam phase for purposes of compensation may be predicted based on the desired cam phase, current cam phase and its rate of change; otherwise, the cam phase is predicted based on the current cam phase. In a first interval of cam phase transition characterized by nonlinear change in cam phase, the cam phase is predicted by applying a nonlinear offset to the measured cam phase. In a second interval of cam phase transition characterized by substantially linear variation of cam phase, the cam phase is predicted by linear extrapolation of the measured cam phase, and limited to range bounded by the measured cam phase and the desired cam phase.

Abstract: A reed valve for a passage defined by an inner surface in an engine comprises a cage mounted across the passage. The cage has a cage port, an upstream side and a downstream side. The read valve includes a flexible petal having a fixed portion connected to the cage enabling the petal to flex away from the cage in a cantilevered manner. The petal overlies the cage port to allow fluid flow therethrough from the upstream side to the downstream side by flexing away from the cage, and to obstruct fluid back-flow in the reverse direction by seating against the cage. The read valve further comprises an inflatable member adjoining a portion of the petal which flexes away from the cage. The petal is sandwiched between the inflatable member and cage so that inflation of the inflatable member obstructs the flexing of the petal away from the cage to reduce the effective length of the petal.