Abstract: An engine assembly may include a first exhaust valve lift assembly, a first exhaust valve, and a first camshaft. The first exhaust valve lift assembly may be operable in first and second operating modes. The first exhaust valve may be engaged with the first exhaust valve lift assembly and may be in communication with an engine combustion chamber. The first camshaft may include a first exhaust lobe engaged with the first exhaust valve lift assembly and defining a profile including a first exhaust region and a first exhaust gas recirculation (EGR) region. The first exhaust valve may remain closed when the first EGR region engages the first exhaust valve lift assembly during the first operating mode and may be opened when the first EGR region engages the first exhaust valve lift assembly during the second operating mode to provide exhaust gas flow into the combustion chamber during an intake stroke.

Abstract: An engine system includes a diesel engine having an exhaust manifold connected to the diesel engine. An exhaust passage is connected to the exhaust manifold and a diesel particulate filter is disposed in the exhaust passage. An air intake passage is provided for supplying fresh air to the diesel engine. A bypass passage is connected between the air intake passage and the exhaust passage in a location downstream of the diesel particulate filter. The bypass passage includes a bypass control valve for opening and closing the bypass passage during a diesel particulate filter regeneration cycle when the vehicle is at low speed or idle.

Abstract: A control and method for an internal combustion engine that includes an exhaust gas recirculation system to predict an intake manifold critical temperature (dew point) at which condensation would occur upon entry into exhaust gas recirculation. The control calculates the intake manifold critical temperature (IMT_Critical) as a function of predetermined, sensed or assumed values by processing an equation whose variables are occupied by the values. The control commands adjustments of exhaust gas recirculation operation in response to the calculation, preferably after the actual intake manifold temperature exceeds the IMT_Critical for a predetermined time.

Abstract: A control for an internal combustion engine that includes an exhaust gas recirculation system predicts at least one of the intake manifold temperature in EGR mode or an intake manifold pressure in EGR mode, but preferably both, during Boost mode operation. The predictions are relied upon to calculate an intake manifold critical temperate in EGR, at which condensation would occur. The control then compares the predicted temperate value with the calculated intake manifold critical temperature, and if the predicted value exceeds the calculated temperature, the control commands re-entry into exhaust gas recirculation mode.

Abstract: A control for an internal combustion engine that includes an exhaust gas recirculation system predicts at least one of the intake manifold temperature in EGR mode or an intake manifold pressure in EGR mode, but preferably both, during Boost mode operation. The predictions are relied upon to calculate an intake manifold critical temperate in EGR, at which condensation would occur. The control then compares the predicted temperate value with the calculated intake manifold critical temperature, and if the predicted value exceeds the calculated temperature, the control commands re-entry into exhaust gas recirculation mode.

Abstract: A control and method for an internal combustion engine that includes an exhaust gas recirculation system to predict an intake manifold critical temperature (dew point) at which condensation would occur upon entry into exhaust gas recirculation. The control calculates the intake manifold critical temperature (IMT_Critical) as a function of predetermined, sensed or assumed values by processing an equation whose variables are occupied by the values. The control commands adjustments of exhaust gas recirculation operation in response to the calculation, preferably after the actual intake manifold temperature exceeds the IMT_Critical for a predetermined time.

Abstract: A system for supplying clean pressurized air to a diesel oxidation catalyst (DOC) includes a diesel engine, a turbocharger, and a DOC. The diesel engine having an outlet that presents an exhaust gas. The turbocharger receives at least a first portion of the exhaust gas and clean air, and presents uncooled pressurized clean air. The DOC receives a combination of the at least first portion of the exhaust gas and at least a second portion of the uncooled pressurized clean air.

Abstract: A system and method for controlling an internal combustion engine to reduce or eliminate formation of EGR condensate monitor current ambient and operating conditions to determine whether conditions are favorable for condensation of EGR gases, and control the engine accordingly to avoid condensation, preferably by increasing the intake manifold temperature. The intake manifold temperature may be increased by redirecting some or all of the EGR flow to avoid the EGR cooler. Alternatively, or in combination, some or all of the charge air may be redirected to bypass the charge air cooler and/or redirected from the outlet of the turbocharger compressor to the intake, effectively increasing the intake air temperature and resulting in a corresponding increase of the intake manifold temperature. Conditions favorable for condensation may be determined based on engine speed and load, ambient temperature, manifold pressure, scheduled or actual EGR flow rate and scheduled or actual air/fuel ratio.

Abstract: A system and method for controlling an internal combustion engine to reduce or eliminate formation of EGR condensate monitor current ambient and operating conditions to determine whether conditions are favorable for condensation of EGR gases, and control the engine accordingly to avoid condensation, preferably by increasing the intake manifold temperature. The intake manifold temperature may be increased by redirecting some or all of the EGR flow to avoid the EGR cooler. Alternatively, or in combination, some or all of the charge air may be redirected to bypass the charge air cooler and/or redirected from the outlet of the turbocharger compressor to the intake, effectively increasing the intake air temperature and resulting in a corresponding increase of the intake manifold temperature. Conditions favorable for condensation may be determined based on engine speed and load, ambient temperature, manifold pressure, scheduled or actual EGR flow rate and scheduled or actual air/fuel ratio.

Abstract: A system and method for controlling combustion engine compression braking having the variable timing of the dwell period of at least one exhaust valve by an electronic control module within each one of the engine cylinders during a braking event as well as the variable timing of the commencement or onset of the braking event. The system and method thus facilitate the proper performance of the braking event as a function of engine speed and prevents interference or physical impact with the cam driving elements used for achieving the normal or regular exhaust valve event.

Abstract: A method and an apparatus for controlling combustion engine compression braking has the variable timing of the opening of at least one exhaust valve by an electronic control module within each one of the engine cylinders and within a time range of 15°-150° before the top-dead-center position of each cylinder piston during each compression stroke such that variable compression braking power levels, and attendant noise levels, can be obtained as required or desired dependent upon various road, vehicle, and vehicle location parameters. The system and method facilitate a wide range of braking power levels or values, the braking power is smoothly modulated as a result of all of the designated exhaust valves of the cylinders being activated, and the braking power levels can also be generated as a function of engine speed.

Abstract: The present invention presents a system and method editing content elements within the context of the Web page that contains the content elements. Web pages are requested from a computer serving Web pages by a client using a Web browser, the content comprising the requested page or pages being stored and managed by a database or other data store. Embedded in the requested page is a dynamic database reader (DDR), which transmits a request to a Control Program (CP) running in the server. Upon this transmission the CP queries the database for page content and returns the content to the DDR. As the requested data is received, the DDR places editorial controls in the vicinity of one or more editable content elements and passes the resultant data off to the browser to be rendered and displayed to the user.

Abstract: A method of operating a diesel engine is disclosed. The method includes the step of sensing a temperature level associated with the engine. The method further includes the step of positioning the intake valve in the open position during an exhaust stroke of the engine if the temperature level is below a predetermined threshold value, whereby heated exhaust gases advance into the intake conduit during the exhaust stroke so as to heat intake air located in the intake conduit prior to the intake air advancing into the combustion chamber during a subsequent intake stroke. The method yet further includes the step of positioning the intake valve in the closed position during the exhaust stroke if the temperature level is above the predetermined threshold value, whereby heated exhaust gases are prevented from advancing into the intake conduit during the exhaust stroke. A diesel engine is also disclosed.