Abstract: An internal combustion engine (100) includes a turbocharger (107) having a turbine (109) and a compressor (111). A charge-air cooler (121) is in fluid communication with an outlet (117) of the compressor (111) through a hot-air passage (123). An intake throttle (127) is in fluid communication with an outlet (125) of the charge-air cooler (121) through a cool-air passage (129). A junction (137) is located downstream of the intake throttle (127). An intake system (103) and an exhaust gas recirculation system (131, 133, 135) are in fluid communication with the junction (137). A bypass passage (139) containing an orifice (141) fluidly connects the hot-air passage (123) and the intake system (103).

Abstract: A fuel injection device (26) for an internal combustion engine (10) has a fuel inlet (40) and a fuel outlet (42). A plunger (58) is operable within a fuel pumping chamber (50) for forcing pressure-amplified fuel to open and pass through an outlet control valve (56) at the outlet. A (“fast-acting”) control valve (64) operates in timed relation to the engine cycle to allow control fluid from an oil rail (34) to force valve (56) closed when fuel is not to be injected and to disallow control fluid from forcing valve (56) closed when fuel is to be injected. A (“slow-acting”) control valve (72) is selectively operable in timed relation to the engine cycle to disallow control fluid from acting on plunger (58) when fuel is not to be injected, but allow control fluid to act on the plunger to force injection when control valve (72) is disallowing control fluid from forcing control valve (56) closed.

Abstract: A fuel injection device (26) for an internal combustion engine (10) has a fuel inlet (40) and a fuel outlet (42). A plunger (58) is operable within a fuel pumping chamber (50) for forcing pressure-amplified fuel to open and pass through an outlet control valve (56) at the outlet. A (“fast-acting”) control valve (64) operates in timed relation to the engine cycle to allow control fluid from an oil rail (34) to force valve (56) closed when fuel is not to be injected and to disallow control fluid from forcing valve (56) closed when fuel is to be injected. A (“slow-acting”) control valve (72) is selectively operable in timed relation to the engine cycle to disallow control fluid from acting on plunger (58) when fuel is not to be injected, but allow control fluid to act on the plunger to force injection when control valve (72) is disallowing control fluid from forcing control valve (56) closed.

Abstract: An electronic engine control for reducing, and ideally eliminating, accumulation of products of incomplete combustion that result from cold ambient conditions acting on the engine and that otherwise might ultimately affect engine operation before the useful life of an engine has elapsed. An idle speed control has a first source providing a signal corresponding to ambient air temperature, a second source providing a signal corresponding to engine coolant temperature, a third source providing a signal indicating that an engine is running substantially in an idle condition, and a processor that processes the signals from the first source, the second source, and the third source to develop an idle speed control signal for controlling engine idle speed by regulating the engine coolant temperature to a defined coolant temperature when the engine is running in an idle condition and the ambient air temperature does not concurrently exceed a defined air temperature.

Abstract: An electronic engine control for reducing, and ideally eliminating, accumulation of products of incomplete combustion that result from cold ambient conditions acting on the engine and that otherwise might ultimately affect engine operation before the useful life of an engine has elapsed. An idle speed control has a first source providing a signal corresponding to ambient air temperature, a second source providing a signal corresponding to engine coolant temperature, a third source providing a signal indicating that an engine is running substantially in an idle condition, and a processor that processes the signals from the first source, the second source, and the third source to develop an idle speed control signal for controlling engine idle speed by regulating the engine coolant temperature to a defined coolant temperature when the engine is running in an idle condition and the ambient air temperature does not concurrently exceed a defined air temperature.

Abstract: An electronic control (18) for a combustion engine that forms a portion of an automotive vehicle powertrain and has an output shaft for powering a drivetrain portion (14, 16, 17, 19) of the powertrain to propel the vehicle. The control has at least one ambient parameter variable input source representing a respective ambient parameter (EOT, BAP, AIT, and MAP) useful in deriving gross torque output of the combustion engine. The control also has at least one operating variable input source (EFC, ACD, DIT.sub.-- ADJ) representing a respective operating parameter useful in deriving a reduction in gross torque output of the combustion engine due to operation of the combustion engine, and a processor for processing a respective signal correlated to the at least one ambient parameter variable input source and for processing a respective signal correlated to the at least one operating parameter variable input source to derive torque at the output shaft of the engine for powering the drivetrain to propel the vehicle.

Abstract: An electric control for a fuel injector develops a commanded boost signal that is superimposed on a fuel injection pulse waveform. Variable operating parameters, such as engine speed, fuel injection quantity, engine coolant temperature, and engine air intake temperature are monitored and may diminish the duration of the commanded boost signal under certain conditions to avoid overheating electric circuit elements in the control through which electric power is delivered to the fuel injector.

Abstract: A diesel engine having a lubricating oil sump and a low pressure lubricating oil pump, is provided with a hydraulically-operated, electronically-controlled unit fuel injector operating system of the type having a unit fuel injector, a high pressure pump, a high pressure lubricating oil supply passage from said pump to said unit injector, a fuel supply to said unit injector, and an electronically controlled valve in said unit injector for controlling the application of the pressure of the lubricating oil to force said fuel to be expelled from said injector, wherein a priming reservoir is operatively connected to the low pressure lubricating oil pump and disposed upstream and above the high pressure supply pump and above the high pressure supply passage, preferably being disposed in the engine front cover and having a restricted return line to the oil sump for venting air from said reservoir, a siphon passage establishes fluid communication between said reservoir and said high pressure passage independently of

Abstract: An exhaust back pressure control system includes a valve in the exhaust outlet of a turbocharger of an internal combustion engine which is controlled by an engine control microcomputer. When the valve is moved toward a closed position, it restricts the exhaust flow, thereby increasing back pressure and friction within the engine by producing an artificial load thereon, and thus speeds up the warming process taking place within the engine upon starting thereof. The valve is moved by an actuating piston within a hydraulic cylinder using engine oil pressure controlled by an electrically operated valve receiving a pulse width modulated operating signal from the engine microcomputer, the operating signal being generated to provide a desired back pressure as a function of engine coolant temperature, engine speed, engine fuel comsumption, and actual back pressure. Operation of the system is enabled if the ambient air temperature is below 2.degree. C.