1. Field of the Invention
The invention relates to an internal combustion engine and a method of controlling the internal combustion engine.
2. Description of the Related Art
In an internal combustion engine having a secondary-air supply passage connected to an engine exhaust passage, and an air pump for supplying secondary air into the engine exhaust passage via the secondary-air supply passage, a pressure sensor for detecting an absolute pressure in the secondary-air supply passage is disposed in the secondary-air supply passage, and fault diagnosis of a secondary-air supply control device is performed based on an output value of the pressure sensor, as disclosed in, for example, Japanese Patent Application Publication No. 2003-83048 (JP-A-2003-83048).
In the internal combustion engine as described above, fault diagnosis is performed based on the magnitude of the pressure in the secondary-air supply passage relative to atmospheric pressure, and it is, therefore, necessary to detect in advance an output value of the pressure sensor representing atmospheric pressure. Also, since the fault diagnosis is carried out immediately after supply of secondary air is started after startup of the engine, the output value of the pressure sensor representing atmospheric pressure must be detected when or before the engine is started. Accordingly, a controller of the engine as described above stores an output value of the pressure sensor detected immediately before startup of the engine, as an output value representing atmospheric pressure.
In the meantime, a battery voltage is applied from a battery to the pressure sensor, and the output value of the pressure sensor decreases as the battery voltage decreases even if the sensor detects the same atmospheric pressure. On the other hand, immediately before startup of the engine, a starter motor or other accessories having a high electric load may be actuated or started. If the starter motor and/or other accessories of a high electric load is/are actuated while the battery is in deteriorated condition, the battery voltage may be reduced. Accordingly, if the output value of the pressure sensor obtained immediately before startup of the engine is simply stored as the output value representing atmospheric pressure while the battery voltage is reduced, as in the above-described engine, there arises a problem that the stored output value of the pressure sensor does not actually represent the atmospheric pressure.
The invention provides an internal combustion engine and its control method that can avoid erroneous detection of faults of a secondary-air supply control device even in the case where the battery is in deteriorated condition.
A first aspect of the invention relates to an internal combustion engine including a battery and a pressure sensor to which a battery voltage is applied from the battery and which produces an output responsive to a pressure, wherein an output value of the pressure sensor changes in accordance with a reduction in the battery voltage. In this engine, the output value of the pressure sensor is inhibited from being used as an output value representing the pressure, when the battery voltage is lower than a predetermined permissible voltage.
A second aspect of the invention relates a method of controlling an internal combustion engine including a battery and a pressure sensor to which a battery voltage is applied from the battery and which produces an output responsive to a pressure, wherein an output value of the pressure sensor changes in accordance with a reduction in the battery voltage. According to this method, the output value of the pressure sensor is inhibited from being used as an output value representing the pressure when the battery voltage is lower than a predetermined permissible voltage.
According to the first and second aspects of the invention, an erroneous output value of the pressure sensor is prevented from being used as an output value representing the pressure to be detected.
The foregoing and further features and advantages of the invention will become apparent from the following description of exemplary embodiments with reference to the accompanying drawings, wherein like numerals are used to represent like elements, and wherein:
The secondary-air supply control device 10 includes an air pump 11 adapted to be driven by an electric motor. An air inlet port of the air pump 11 is connected to a portion of the intake duct 4 upstream of the throttle valve 5 via a secondary-air inlet passage 12, and an air discharge port of the air pump 11 is connected to exhaust passages in the respective exhaust branch pipes 8 via a common secondary-air supply passage 13 and secondary-air supply branch passages 14 that branch off from the secondary-air supply passage 13. A switch valve 15 and a reed valve 16 are disposed in the secondary-air supply passage 13 in this order as viewed in the direction from the air pump 11 to the exhaust branch pipes 8. The reed valve 16 allows flow of air from the switch valve 15 into the exhaust branch pipes 8.
An electronic control unit 20 consists of a digital computer, and includes ROM (read-only memory) 22, RAM (random access memory) 23, CPU (microprocessor) 24, an input port 25 and an output port 26, which are connected to each other via a two-way bus 21. A load sensor 30 connected to an accelerator pedal 29 produces an output voltage proportional to the amount L of depression of the accelerator pedal 29, and the output voltage of the load sensor 30 is transmitted to the input port 25 via a corresponding A/D converter 27. To the input port 25 is also connected an engine speed sensor 31 that produces an output pulse each time the crankshaft rotates by, for example, 30°. The input port 25 also receives an ON/OFF signal from an ignition switch 32.
As shown in
An output voltage of the pressure sensor 36 is transmitted to the input port 25 via a corresponding A/D converter 27. A voltmeter 38, which is connected to the terminals 34 of the battery 33, serves to detect the battery voltage when the ignition switch 32 is turned on. The output signal of the voltmeter 38 is transmitted to the input port 25 via a corresponding A/D converter 27. On the other hand, the output port 26 is connected to the switch valve 15, relay 35, and other components via corresponding drive circuits 28.
In
When the engine is started, the secondary-air supply control device 10 operates to supply secondary air into exhaust gas so as to inhibit unburned HC from being discharged into the atmosphere and promote early warm-up of a catalyst. In this case, various problems may occur if the air pump 11 or the switch valve 15 is at fault, and therefore, it is determined from the output voltage of the pressure sensor 36 whether the air pump 11 and the switch valve 15 operate normally.
When the air pump 11 is stopped and the switch valve 15 is closed, the absolute pressure P in the secondary-air supply passage 13 is equal to the atmospheric pressure P0 as indicated by I in
When the air pump 11 is actuated and the switch valve 15 is closed, the absolute pressure P in the secondary-air supply passage 13 is held at a constant pressure level higher than the varying pressure II, as indicated by III in
If the air pump 11 is stopped when the secondary air is to be supplied, for example, the pressure as indicated by I or IV in
In order to make fault diagnosis based on the magnitude of the absolute pressure P as described above, it is required to accurately detect a reference pressure, namely, the output voltage of the pressure sensor 36 which represents atmospheric pressure. If the output voltage of the pressure sensor 36 detected when the battery voltage is temporarily reduced is determined as an output voltage representing atmospheric pressure, this output voltage representing atmospheric pressure deviates from a correct value when the nominal battery voltage is restored, and the fault diagnosis cannot be correctly performed.
In the present embodiment, therefore, when the battery voltage is lower than a predetermined permissible voltage, the output value of the pressure sensor 36 is inhibited from being used as an output value representing atmospheric pressure. In the following, this will be explained in greater detail referring to
In the present embodiment of the invention, a retrieving action for retrieving the output voltage of the pressure sensor 36 is started after a lapse of waiting time Δt1 from turn-on of the ignition switch 32 to a rise of the battery voltage E applied to the pressure sensor 36 and other components. This is a common feature in all of the cases illustrated in
On the other hand,
In this case, however, if the air pump 11 is actuated or started before the count value of the counter C3 reaches the specified value, an average value of the output voltages of the pressure sensor 36 retrieved until the air pump 11 is actuated is determined as the output voltage representing the atmospheric pressure.
If the nominal battery voltage E is restored, namely, if the battery voltage E is increased to be higher than the permissible voltage EX, as shown in
When the battery voltage E is lower than the permissible voltage EX after the lapse of the waiting time Δt1 as shown in
Namely, supply of secondary air is stopped when the battery voltage E is lower than the permissible voltage EX immediately after the ignition switch 32 is turned on, and supply of secondary air is started after the battery voltage E exceeds the permissible voltage Ex and the output value of the pressure sensor 36 representing the atmospheric pressure is determined.
In step 51, it is determined whether the waiting time Δt1 has elapsed since the ignition switch 32 is turned on. If the waiting time Δt1 has not elapsed, the current cycle of the routine is finished. If the waiting time Δt1 has elapsed, the control proceeds to step 52. In step 52, the count value of the counter C3 is incremented. In the following step 53, it is determined whether the battery voltage E is equal to or higher than the permissible voltage EX. If E≧EX, namely, if the battery voltage E is equal to or higher than the permissible voltage EX, the control proceeds to step 54 to clear or reset the counter C1, and then proceeds to step 55.
In step 55, it is determined whether an absolute value of a pressure difference (P1−P0) between the atmospheric pressure P1 detected by the pressure sensor 36 in the last cycle and the atmospheric pressure P0 detected by the pressure sensor 36 in the current cycle is lower than a predetermined permissible pressure difference ΔP. If |P1−P0|<ΔP, namely, if the amount of variation of the output voltage of the pressure sensor 36 is smaller than the permissible amount of variation, the control proceeds to step 56 to increment the count value of the counter C2. In the following step 57, it is determined whether the count value of the counter C2 has reached a specified value CX2, for example, whether a period of 200 msec. has elapsed. If C2≧CX2, the control proceeds to step 58 to determine the atmospheric pressure P0 from the output voltage of the pressure sensor 36. The control then proceeds to step 59 to set the retrieval completion flag. This case is illustrated in
Namely, in the case as shown in
As described above, the output value of the pressure sensor 36 may be retrieved during cranking immediately after the ignition switch 32 is turned on. In this case, noise is superimposed on the output voltage of the pressure sensor 36, and therefore, the output voltage of the pressure sensor 36 may vary or fluctuate. In this case, according to the present embodiment of the invention, when the output value of the pressure sensor 36 varies or fluctuates while the battery voltage E is higher than or equal to the permissible voltage EX, the output value of the pressure sensor 36 representing atmospheric pressure is determined depending upon the magnitude of variation of the output value.
Namely, in the case as shown in
Referring back to
After the sum ΣP0 is calculated in step 61, the control proceeds to step 62 to determine whether the count value of the counter C3 has reached a specified value CX3, or whether the air pump 11 is actuated or started. If the count value of the counter C3 reaches the specified value CX3, for example, 1000 msec. has elapsed after a lapse of the waiting time Δt1, or the air pump 11 is actuated, an average value of atmospheric pressure is calculated from the sum ΣP0 in step 63, and the thus obtained average value is determined as atmospheric pressure P0. This case is illustrated in
Namely, in the case as shown in
If it is determined in step 53 that the battery voltage E is lower than the permissible voltage EX, the control proceeds to step 64 to increment the count value of the counter C1. In the following step 65, it is determined whether the count value of the counter C1 has reached a specified value CX1, for example, whether 200 msec. has elapsed since it was determined that E<EX. If the count value of the counter C1 exceeds the specified value CX1, the control proceeds to step 66 to set the voltage reduction flag. In the following step 67, the counter C2, counter C3 and the sum ΣP0 are cleared. This case is illustrated in
If the voltage reduction flag is set, supply of secondary air is delayed as shown in
If the secondary-air supply condition is satisfied, on the other hand, the control proceeds to step 71 to determine whether the voltage reduction flag is set. If the voltage reduction flag is not set, namely, if the battery voltage E is not kept smaller than the permissible voltage EX for a specified period of time or longer, the control proceeds to step 73 to immediately start supply of secondary air. If the voltage reduction flag is set, on the other hand, the control proceeds to step 72 to determine whether the retrieval completion flag is set. If the retrieval completion flag is set, supply of secondary air is started. Namely, once the voltage reduction flag is set, supply of secondary air is started only after the output voltage of the pressure sensor 36 representing the atmospheric pressure is determined.
Needless to say, the present invention may find applications other than fault diagnosis of the secondary-air supply control device.
While the invention has been described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the described embodiments or constructions. To the contrary, the invention is intended to cover various modifications and equivalent arrangements. In addition, while the various elements of the exemplary embodiments are shown in various combinations and configurations, other combinations and configurations, including more, less or only a single element, are also within the spirit and scope of the invention.
Number | Date | Country | Kind |
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2006-335814 | Dec 2006 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2007/003689 | 11/30/2007 | WO | 00 | 3/30/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/072049 | 6/19/2008 | WO | A |
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Number | Date | Country | |
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20100028167 A1 | Feb 2010 | US |