초록 ▼

The displacement of fluid translating devices are normally controlled by changing the angle of an eccentric or a cam plate to change the pumping stroke of the pistons within the device. In the subject arrangement, the displacement of the fluid translating device is controlled by controlling the flow

The displacement of fluid translating devices are normally controlled by changing the angle of an eccentric or a cam plate to change the pumping stroke of the pistons within the device. In the subject arrangement, the displacement of the fluid translating device is controlled by controlling the flow being delivered into or away from each of the associated pressure chambers defined therein by the respective ones of a plurality of pistons. By not permitting the flow from every piston to be directed into useful work, the volume of fluid being directed into or away from the fluid translating device can be altered. Likewise, the direction of fluid flow within the fluid translating device can be selectively changed thus permitting the subject fluid translating device to be capable of pumping or motoring in both directions of flow relative to the first and second inlet/outlet ports thereof.

대표청구항 ▼

The displacement of fluid translating devices are normally controlled by changing the angle of an eccentric or a cam plate to change the pumping stroke of the pistons within the device. In the subject arrangement, the displacement of the fluid translating device is controlled by controlling the flow

The displacement of fluid translating devices are normally controlled by changing the angle of an eccentric or a cam plate to change the pumping stroke of the pistons within the device. In the subject arrangement, the displacement of the fluid translating device is controlled by controlling the flow being delivered into or away from each of the associated pressure chambers defined therein by the respective ones of a plurality of pistons. By not permitting the flow from every piston to be directed into useful work, the volume of fluid being directed into or away from the fluid translating device can be altered. Likewise, the direction of fluid flow within the fluid translating device can be selectively changed thus permitting the subject fluid translating device to be capable of pumping or motoring in both directions of flow relative to the first and second inlet/outlet ports thereof. e the temperature of the exhaust gas oxygen sensor. 6. A method for controlling an internal combustion engine having a plurality of cylinders, at least some of which are selectively deactivated in a variable displacement operating mode, and at lease one exhaust gas oxygen sensor for providing an indication of oxygen content of an exhaust, the method comprising: monitoring temperature of the at least one exhaust gas oxygen sensor; and controlling activation of a heater associated with the at least one sensor and activation of at least one cylinder to achieve or maintain a minimum desired sensor operating temperature, wherein the step of controlling activation of at least one cylinder comprises activating a bank of deactivated cylinders to increase the temperature of the exhaust gas oxygen sensor, wherein the step of controlling comprises: activating the deactivated cylinders and controlling air/fuel ratio to the cylinders during activation to provide a lean air/fuel ratio; and controlling air/fuel ratio for a corresponding number of activated cylinders during activation of the deactivated cylinders to provide a rich air/fuel ratio. 7. The method of claim 6 further comprising retarding ignition timing for the deactivated cylinders during activation. 8. A method for controlling an internal combustion engine having a plurality of cylinders, at least some of which are selectively deactivated in a variable displacement operating mode, and at least one exhaust gas oxygen sensor for providing an indication of oxygen content of an exhaust, the method comprising: monitoring temperature of the at least one exhaust gas oxygen sensor; activating a heater associated with said at least one exhaust oxygen sensor, without activating at least one cylinder, if said heater can maintain said monitored temperature at a desired sensor operating temperature, and activating said heater and at least one cylinder if heater activation is insufficient to maintain said monitored temperature at said minimum desired sensor operating temperature. 9. A system for controlling an internal combustion engine having a plurality of cylinders, at least some of which are selectively deactivated in a variable displacement operating mode, the system comprising: first and second upstream emission control devices; first and second exhaust gas oxygen sensors having associated heaters and positioned upstream relative to the first and second upstream emission control devices, respectively; at least a third emission control device positioned downstream relative to at least one of the first and second upstream emission control devices; and an engine controller for monitoring temperature of at least one of the exhaust gas oxygen sensors and depending on said temperature monitoring, controlling at least one of (a) current supplied to said heater, without activation of at least one cylinder, to achieve or maintain a minimum desired sensor operating temperature, and (b) current supplied to said heater and activation of at least one cylinder to achieve or maintain a minimum desired sensor operating temperature. 10. The system of claim 9 wherein the controller modifies spark timing and air/fuel ratio during activation of at least one deactivated cylinder to retard spark timing from MBT timing and provide a lean air/fuel ratio relative to a stoichiometric ratio. 11. The system of claim 9 wherein the exhaust gas oxygen sensors comprise heated exhaust gas oxygen sensors with integrated heaters. 12. A system for controlling an internal combustion engine having a plurality of cylinders, at least some of which are selectively deactivated in a variable displacement operating mode, the system comprising: first and second upstream emission control devices; first and second exhaust gas oxygen sensors having associated heaters and positioned upstream relative to the first and second upstream emission control devices, respectively; at least a third emission con trol device positioned downstream relative to at least one of the first and second upstream emission control devices; and an engine controller for monitoring temperature of at least one of the exhaust gas oxygen sensors and selectively controlling current supplied to the associated heater and operation in the variable displacement operating mode to achieve or maintain a desired minimum sensor operating temperature, wherein the engine controller monitors temperature using a temperature model. 13. Apparatus for controlling a variable displacement internal combustion engine having a plurality of cylinders, at least some of which are selectively deactivated in a variable displacement operating mode, the apparatus comprising: at least one exhaust gas oxygen sensor for providing an indication of oxygen content of an exhaust, the at least one exhaust gas oxygen sensor having an associated heater selectively operable to achieve or maintain a minimum desired operating temperature; means for monitoring temperature of the at least one exhaust gas oxygen sensor; means for controlling activation of the at least one heater associated with the at least one exhaust gas oxygen sensor without changing the variable displacement operating mode, to achieve or maintain a minimum desired sensor operating temperature; and means for controlling activation of the at least one heater and the variable displacement operating mode to activate or deactivate at least one cylinder to achieve or maintain a minimum desired sensor operating temperature. 14. The apparatus method of claim 13 wherein the means for monitoring temperature comprises means for estimating the temperature. 15. The apparatus of claim 13 wherein the means for monitoring temperature comprises means for sensing the temperature. 16. The apparatus of claim 13 wherein the means for monitoring temperature comprises means for determining whether the sensor signal can be used for closed-loop air/fuel ratio control. 17. Apparatus for controlling a variable displacement internal combustion engine having a plurality of cylinders, at least some of which are selectively deactivated in a variable displacement operating mode, that apparatus comprising: at least one exhaust gas oxygen sensor for providing an indication of oxygen content of an exhaust, the at least one exhaust gas oxygen sensor having an associated heater selectively operable to achieve or maintain a minimum desired operating temperature; means for monitoring temperature of the at least one exhaust gas oxygen sensor; means for controlling activation of the at least one heater associated with the at least one exhaust gas oxygen sensor; means for controlling the variable displacement operating mode to activate or deactivate at least one cylinder to achieve or maintain a minimum desired sensor operating temperature; wherein the means for controlling the variable displacement operating mode comprises means for activating a bank of deactivated cylinders to increase the temperature of the exhaust gas oxygen sensor. 18. An apparatus for controlling a variable displacement internal combustion engine having a plurality of cylinders, at least some of which are selectively deactivated in a variable displacement operating mode, the apparatus comprising: at least one exhaust gas oxygen sensor for providing an indication of oxygen content of an exhaust, the at least one exhaust gas oxygen sensor having an associated heater selectively operable to achieve or maintain a minimum desired operating temperature; means for monitoring temperature of the at least one exhaust gas oxygen sensor; means for controlling activation of the at least one heater associated with the at least one exhaust gas oxygen sensor; and means for controlling the variable displacement operating mode to activate or deactivate at least one cylinder to achieve or maintain a minimum desired sensor operating temperature, wherein the means for controlling the variab