JP4110603B2 - Failure determination device for heater control system used in gas concentration sensor - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a failure determination device for a heater control system used in a gas concentration sensor.
[0002]
[Prior art]
In a gas concentration detection device including an application to an automobile, the same detection device using a gas concentration sensor has been proposed, and an air-fuel ratio detection device using an air-fuel ratio sensor is known as an example.
[0003]
That is, in recent vehicle-mounted engines, linear air-fuel ratio sensors that detect the air-fuel ratio (oxygen concentration in exhaust gas) of the air-fuel mixture sucked into the engine in a wide area and linearly are applied. For example, in the limit current type air-fuel ratio sensor, it is necessary to maintain the temperature of the sensor element at a predetermined activation temperature in order to accurately detect the air-fuel ratio (oxygen concentration). For this reason, a heater is usually attached to the sensor, and energization of the heater is controlled by a predetermined duty ratio signal.
[0004]
Recently, it has been legally prescribed to monitor the function of the heater control system for this type of sensor related to automobile exhaust gas, and this regulation tends to be further strengthened in the future. Under such circumstances, a technique such as “Method and apparatus for monitoring the functional capability of a heater of an oxygen measurement sensor” in Japanese Patent Laid-Open No. 5-195443 has been proposed. The apparatus disclosed in the publication is configured to measure the voltage applied to the heater of the oxygen measurement sensor when the heater is energized and when the heater is energized and to output a failure signal when the measured voltage difference is outside a predetermined range. It was.
[0005]
[Problems to be solved by the invention]
However, in the above-described conventional apparatus, it is mainly configured to determine the presence or absence of a failure based on the voltage value (power supply voltage) applied to the heater. Regarding the identification of the failure location and failure mode of the heater control system Was still inadequate. Therefore, automobiles brought into repair shops after the occurrence of a failure, such as inspection of control circuits and harness inspection (including inspection of conductors and connectors), etc. to investigate what is the cause of the failure and where it should be repaired Will be forced to investigate. For this reason, there is a problem that maintenance and inspection require complicated work and a lot of time, and the maintainability is poor.
[0006]
The present invention has been made paying attention to the above-mentioned problem, and the object of the present invention is to accurately determine that when a failure occurs in the heater control system and to identify the failure location. It is providing the failure determination apparatus of the heater control system used for a density sensor.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 has the following characteristics: Applied to a heater control system provided with a heater attached to a gas concentration sensor and energized by power supply from a power source, and heater control means for on / off controlling energization of the heater at a predetermined control duty ratio As a failure determination device, Connected in parallel to the heater, the voltage across the heater Accompanying on / off control with a predetermined control duty ratio Voltage detection means that detects when the heater is energized and de-energized, and the current flowing through the heater connected in series to the heater Similarly with on / off control with a predetermined control duty ratio Current detection means for detecting when the heater is energized and not energized, and the detected voltage and current when the heater is energized And hi The four values consisting of the voltage and current at the time of non-energization are compared with each other at a predetermined threshold value. Small Is the deviation different from the normal value? , A combination of these four values And determine whether there is a failure according to In the circuit constituting the heater control system Failure determination means for specifying a failure location.
[0008]
According to the above configuration, by detecting four values consisting of the voltage and current when the heater is energized and the voltage and current when the heater is not energized, and comparing each with a predetermined threshold value, This makes it possible to identify the failure point of the heater control system, which was insufficient. That is, when a failure occurs in the heater control system, this is accurately determined, and the failure location can be specified in detail. In such a case, when it is determined that a failure has occurred, for example, a failure warning light (MIL: Malfunction indicator light) is turned on, and the vehicle in which the failure has occurred is brought to a repair shop or the like in accordance with this warning. Then, by using the above-described failure location identification result, the failure location identification work required until actual repair can be greatly simplified. As a result, the effect of improving maintainability and workability can be obtained.
[0009]
Incidentally, the failure information specified as described above is stored in a backup memory or the like that retains the data even after the power is turned off, and is read out by a diagnostic checker at any time in a repair shop or the like.
[0010]
The invention of claim 1 is embodied as the following claims 2 to 5. That is,
In the invention described in claim 2, the failure determination means specifies a failure that opens an electrical path connecting the power source side, ground side electrical path of the heater and the heater.
-In invention of Claim 3, the said failure determination means specifies the failure that the electrical path which connects the said heater and the said voltage detection means is open | released.
In the invention according to claim 4, the failure determination means is configured such that the heater is energized regardless of a failure (GND short) in which an electrical path on the ground side of the heater is short-circuited, that is, whether the semiconductor switching element is on or off. Identify faults that will be left alone.
In the invention according to claim 5, the failure determination means is a failure that makes it impossible to switch on / off the semiconductor switching element for intermittently connecting an electric path connecting the power source, the heater, and the ground, that is, a normally-on failure or Identify faults that are always off. According to the structure of Claims 2-5, it becomes possible to specify the failure location about the failure with a comparatively high occurrence frequency, or a failure with a comparatively high priority.
[0011]
If the example of the failure form is briefly explained using the circuit diagram of FIG.
In claim 2, the failure such as disconnection of each part of A, C, D, F, and G in FIG. 4 can be detected.
In the third aspect of the present invention, it is possible to detect a failure such as disconnection of each part B and E in FIG.
In claim 4, a failure such as a short circuit in each part of D, E, and F in FIG. 4 can be detected.
In the fifth aspect of the invention, an on failure or an off failure of the transistor 26 can be detected.
[0012]
According to the sixth aspect of the present invention, at the beginning of energization of the heater at the start of the engine, all energization means for setting the control duty ratio of the heater to 100% and before the start of heater energization by the all energization means, An initial value detecting means for detecting a voltage and a current value and, after the detection, starting energization of the heater to detect both-end voltage and current value; and the failure determining means is detected by the initial value detecting means Failure determination is performed according to each value of the measured voltage and current.
[0013]
That is, when the engine is started at a low temperature, the control duty ratio of the heater is set to 100% so that a gas concentration sensor (for example, an air-fuel ratio sensor) is activated quickly, and the heater is continuously energized (100% energized). ). In this case, if 100% energization is performed, the voltage and current when the heater is not energized cannot be detected even if a failure occurs, and accurate failure determination becomes impossible. On the other hand, in the above configuration, by detecting the voltage and current when the heater is not energized before starting energization, the four values consisting of the voltage and current when the heater is energized and the voltage and current when the heater is not energized are detected. Can be detected, and the desired failure determination as described above can be performed.
[0014]
In the seventh aspect of the invention, when it is determined that a failure has occurred according to the detected values of the voltage and current by the initial value detecting means, the voltage across the heater and the current value can be detected only for the minimum time. The means for setting the control duty ratio to cut off the heater energization, and the heater energization is controlled with the set control duty ratio, and in this state, it is determined continuously that a failure has occurred in the heater control system for a predetermined time or more. A means for finally determining that a failure has occurred. In this case, a more accurate failure determination can be made as compared with the invention of claim 6. In other words, when it is determined that a failure has occurred for the first time, the determination result is used as a temporary determination result, and then the heater energization is cut off for a minimum time during which the both-end voltage and current value of the heater can be detected. It is possible to avoid erroneous determination of failure even at the time of temporary failure determination at the beginning of engine startup.
[0015]
In the invention according to claim 8, the control duty ratio by the heater control means is limited by a predetermined lower guard value or upper guard value. In this case, since the heater energization state or non-energization state is not continued, it is possible to always detect four values consisting of the voltage and current when the heater is energized and the voltage and current when the heater is de-energized. Thus, the desired failure determination as described above can be performed.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment in which the present invention is embodied in an air-fuel ratio detection apparatus will be described with reference to the drawings. The air-fuel ratio detection apparatus in the present embodiment is applied to an electronically controlled gasoline injection engine mounted on an automobile. In the air-fuel ratio control system of the engine, the air-fuel ratio detection system is based on the detection result by the air-fuel ratio detection apparatus. Then, the fuel injection amount to the engine is controlled to a desired air-fuel ratio. In the following description, with regard to the limit current type air-fuel ratio sensor as a gas concentration sensor, the heater energization control procedure attached to the sensor and the failure determination procedure of the heater control system will be described in detail and the processing will be realized. A specific configuration for doing this will be described.
[0017]
FIG. 1 is a configuration diagram showing an outline of an air-fuel ratio detection apparatus according to the present embodiment. In FIG. 1, the air-fuel ratio detection device includes a limiting current air-fuel ratio sensor (hereinafter referred to as an A / F sensor) 30. The A / F sensor 30 is attached to an exhaust pipe 12 extending from the engine body 11 of the engine 10, and the oxygen concentration in the exhaust gas is adjusted with the application of a voltage commanded from a microcomputer (hereinafter referred to as a microcomputer) 20. A proportional linear air-fuel ratio detection signal (sensor current signal) is output. The microcomputer 20 includes a well-known CPU 20a, ROM 20b, RAM 20c, backup RAM 20d, and the like for executing various arithmetic processes, and controls the heater control circuit 25 and the bias control circuit 40 according to a predetermined control program. The backup RAM 20d is configured as a memory capable of holding stored information even after the power supply to the microcomputer 20 is cut off.
[0018]
Here, the bias command signal Vr output from the microcomputer 20 is input to the bias control circuit 40 via the D / A converter 21. The output of the A / F sensor 30 corresponding to the air / fuel ratio (oxygen concentration) at that time is detected as a sensor current by the current detection circuit 50 in the bias control circuit 40, and the detected value is sent to the A / D converter 23. Via the microcomputer 20. The microcomputer 20 performs ON / OFF control of the heater 33 of the A / F sensor 30 by a predetermined control duty ratio signal. A heater voltage and a heater current associated with ON / OFF of the heater 33 are detected by a heater control circuit 25 described later, and the detected values are input to the microcomputer 20 via the A / D converter 24. Further, the microcomputer 20 is connected with a failure warning light 42 for notifying the passenger of the vehicle that a failure has occurred. The warning light 42 is turned on or off according to a determination result of a failure determination process described later. Turns off.
[0019]
FIG. 2 is a cross-sectional view showing an outline of the A / F sensor 30. In FIG. 2, the A / F sensor 30 protrudes toward the inside of the exhaust pipe 12, and the sensor 30 is roughly divided into a cover 31, a sensor body 32, and a heater 33. The cover 31 has a U-shaped cross section, and a plurality of small holes 31a communicating with the inside and outside of the cover are formed on the peripheral wall. The sensor main body 32 as the sensor element unit generates a limit current corresponding to the oxygen concentration in the air-fuel ratio lean region or the unburned gas (CO, HC, H2 etc.) concentration in the air-fuel ratio rich region.
[0020]
The configuration of the sensor body 32 will be described in detail. In the sensor body 32, an exhaust gas side electrode layer 36 is fixed to the outer surface of the solid electrolyte layer 34 formed in a cup shape in cross section, and an atmosphere side electrode layer 37 is fixed to the inner surface. A diffusion resistance layer 35 is formed outside the exhaust gas side electrode layer 36 by plasma spraying or the like. The solid electrolyte layer 34 is made of an oxygen ion conductive oxide sintered body in which CaO, MgO, Y2 O3, Yb2 O3 or the like is dissolved as a stabilizer in ZrO2, HfO2, ThO2, Bi2 O3 or the like as a stabilizer. Consists of heat-resistant inorganic materials such as alumina, magnesia, siliceous, spinel, mullite. Both the exhaust gas side electrode layer 36 and the atmosphere side electrode layer 37 are made of a noble metal with high catalytic activity such as platinum, and the surface thereof is subjected to porous chemical plating or the like. The area and thickness of the exhaust gas side electrode layer 36 are about 10 to 100 mm 2 (square millimeter) and about 0.5 to 2.0 μm, while the area and thickness of the atmosphere side electrode layer 37 are. Is 10 mm ^ 2 (square millimeter) or more and about 0.5 to 2.0 μm.
[0021]
The heater 33 is accommodated in the atmosphere-side electrode layer 37 and heats the sensor body 32 (the atmosphere-side electrode layer 37, the solid electrode layer 34, the exhaust gas-side electrode layer 36, and the diffusion resistance layer 35) by the heat generation energy. . The heater 33 has a heat generation capacity sufficient to activate the sensor body 32.
[0022]
In the A / F sensor 30 configured as described above, the sensor main body 32 generates a limit current corresponding to the oxygen concentration in the lean region from the theoretical air-fuel ratio point. In this case, the limit current corresponding to the oxygen concentration is determined by the area of the exhaust gas side electrode layer 36, the thickness of the diffusion resistance layer 35, the porosity, and the average pore diameter. The sensor main body 32 can detect the oxygen concentration with a linear characteristic, and a high temperature of about 600 ° C. or higher is required to activate the sensor main body 32. Since the active temperature range is narrow, the element temperature cannot be controlled in the active region by heating only with the exhaust gas of the engine 10. For this reason, in the present embodiment, the sensor main body 32 is heated to the active temperature range by duty-controlling the power supplied to the heater 33. Note that in the region on the richer side than the stoichiometric air-fuel ratio, the concentration of unburned gas such as carbon monoxide (CO) changes almost linearly with respect to the air-fuel ratio, and the sensor body 32 corresponds to the concentration of CO or the like. Generate limit current.
[0023]
The voltage-current characteristic (VI characteristic) of the sensor body 32 will be described with reference to FIG. According to FIG. 3, the inflow current to the solid electrolyte layer 34 of the sensor main body 32 proportional to the detection A / F of the A / F sensor 30 and the applied voltage to the solid electrolyte layer 34 have linear characteristics. I understand. In such a case, the straight line portion parallel to the voltage axis V is a limit current detection area for specifying the limit current of the sensor body 32, and the increase / decrease of the limit current (sensor current) is the increase / decrease of A / F (that is, lean / rich). ). That is, the limit current increases as A / F becomes leaner, and the limit current decreases as A / F becomes richer.
[0024]
In this V-I characteristic, a voltage region smaller than a straight line portion (limit current detection region) parallel to the voltage axis V is a resistance dominant region, and the slope of the primary linear portion in the resistance dominant region is It is specified by the internal resistance of the solid electrolyte layer 34 (hereinafter referred to as element impedance Zdc). This element impedance Zdc changes with changes in temperature, and when the temperature of the sensor body 32 decreases, the inclination decreases due to an increase in Zdc.
[0025]
FIG. 4 is a circuit diagram showing a configuration of the heater control circuit 25. In the figure, one end of the heater 33 is connected to a battery power supply + B having a rated voltage of 12 volts, and the other end is connected to the drain of an n-channel MOS transistor (hereinafter referred to as MOS 26) constituting a semiconductor switching element. The gate of the MOS 26 is connected to the microcomputer 20 via a driver 27, and the source is grounded via a heater current detection resistor 41. In short, the MOS 26 is turned ON / OFF by the control duty ratio signal of the microcomputer 20, and the energization operation of the heater 33 is controlled by the ON / OFF operation of the MOS 26.
[0026]
The heater voltage detection circuit 28 as voltage detection means is constituted by a differential amplifier circuit composed of an operational amplifier 28a and resistors 28b to 28e, measures the voltage Vh across the heater 33, and outputs the measurement result to an A / D converter. 24 to the microcomputer 20. The heater end-to-end voltage Vh corresponds to the difference between the battery-side voltage Vpos of the heater 33 and the GND-side voltage Vneg (Vh = Vpos−Vneg). Here, the resistance values of the resistors 28b and 28e are equal (this resistance value is R1), and the resistance values of the resistors 28c and 28d are equal (this resistance value is R2).
[0027]
The heater current detection circuit 29 as current detection means is constituted by a differential amplifier circuit composed of an operational amplifier 29a and resistors 29b to 29e, and converts the heater current Ih detected by the heater current detection resistor 41 into a voltage signal. The result is output to the microcomputer 20 via the A / D converter 24. Incidentally, the resistance value of the heater current detection resistor 41 is set to a very small value so as not to affect the heater current Ih, so that the temperature rise performance of the heater 33 is not impaired.
[0028]
If no failure has occurred in the heater control system when the heater is energized (when the MOS 26 is turned on) and when the heater is not energized (when the MOS 26 is turned off), the heater control circuit 25 is configured as follows. Detect voltage and heater current. That is, when the heater is energized, the voltage applied to both ends of the heater (hereinafter referred to as the heater-on voltage Von) becomes a value substantially equal to the power supply voltage VB of the heater 33 (a value lower by the voltage drop of the resistance component such as the harness). At this time, the current flowing through the heater 33 (hereinafter referred to as heater-on current Ion) is a value obtained by dividing the power supply voltage VB by the heater resistance value Rh. Specifically, if VB = 12 volts, the heater on voltage Von is
Von = (R1 / R2) · Vh
From the above formula, it becomes “about 11 volts”. If Rh = 2 ohms, the heater-on current Ion is
Ion = VB / Rh
It becomes "about 5 amps" from the mathematical formula. That is, the output of the heater voltage detection circuit 28 (output voltage of the operational amplifier 28a) becomes “about 11 volts” and the current conversion value of the output of the heater current detection circuit 29 (output voltage of the operational amplifier 29a) becomes “about 5 amperes”. It becomes.
[0029]
In addition, when the heater is not energized, the potential difference between both ends of the heater disappears, so that the voltage applied to both ends of the heater (hereinafter referred to as heater off voltage Voff) becomes “almost 0 volts”. At this time, since there is no potential difference between both ends of the heater current detection resistor 41, the current flowing through the heater 33 (hereinafter referred to as heater off current Ioff) becomes “0 ampere”. That is, the output of the heater voltage detection circuit 28 (output voltage of the operational amplifier 28a) becomes “almost 0 volt” and the current conversion value of the output of the heater current detection circuit 29 (output voltage of the operational amplifier 29a) becomes “almost 0 amperes”. It becomes.
[0030]
On the other hand, in the heater control system, when any failure occurs, such as a harness failure (conductor disconnection or connector contact failure), Von, Ion, Voff, Ioff described above becomes a value different from the normal value. Is different depending on what kind of failure has occurred at which location due to the configuration of the heater control system. Therefore, in the present embodiment, the failure occurrence location and the content (hereinafter referred to as failure mode) are analyzed by dividing into the following (1) to (10), and the analysis results are individually shown with reference to FIG. Explained. FIG. 15 shows values of Von, Ion, Voff, and Ioff corresponding to each failure location and failure mode.
[0031]
(1) Opening of part A in Fig. 4
When the heater is energized (when the MOS 26 is turned on) at the time of failure of “A part open” due to disconnection or the like, the potentials at both ends of the heater 33 are both at the GND level, and no potential difference between the both ends of the heater occurs. Accordingly, the heater-on voltage Von is “0 volts”. At this time, since the electric path connecting the battery power source + B, the heater 33 and GND is cut off, no current flows through the heater 33 and the heater on-current Ion becomes “0 ampere”. In this case, Von and Ion are greatly different from those when the heater control system is normal.
[0032]
Incidentally, the non-inverting input terminal of the operational amplifier 28a is connected to the GND through the resistor 28e, and the operational amplifier 28a applies negative feedback by the resistor 28b. Therefore, when the heater is not energized (when the MOS 26 is turned off), the inverting input terminal of the operational amplifier 28a is at the GND level, and the output voltage of the operational amplifier 28a is "0 volts", which is the GND level. That is, the heater off voltage Voff becomes “0 volt” as in the normal state. Further, the heater-off current Ioff is “0 amperes” as in the normal state.
[0033]
(2) In the case of B part opening of FIG.
At the time of failure of “B part open” due to disconnection or the like, when the heater is energized (when the MOS 26 is turned on), the non-inverting input terminal of the operational amplifier 28a becomes the GND level, and the heater on voltage Von becomes “0 volt”. At this time, as apparent from the circuit diagram of FIG. 4, the heater current normally flows even when the portion B is opened, so the heater on-current Ion has the same value as in the normal state. Note that the heater off voltage Voff and the heater off current Ioff when the heater is not energized (when the MOS 26 is turned off) both have the same values as when normal. In other words, only Von is greatly different from the normal value. This makes it possible to determine a failure and to determine that the above-mentioned failure of the A section is open.
[0034]
(3) In the case of part C opening in FIG.
At the time of failure of “C section open” due to disconnection or the like, when the heater is energized (when the MOS 26 is ON), the non-inverting input terminal of the operational amplifier 28a becomes the potential of the heater power supply voltage VB and the inverting input terminal is 0. It becomes a bolt. In detail,
Von = (R1 / R2) · VB
The Von value is obtained from the mathematical expression. At this time, the heater-on voltage Von is a voltage value corresponding to the potential of the power supply voltage VB, that is, “12 volts”. Here, when the part C is opened, the electric path connecting the battery power source + B, the heater 33 and GND is cut off, and no heater current flows even if the MOS 26 is turned on. For this reason, there is no voltage drop in the harness or the like, and the heater-on voltage Von is higher than normal. Further, the heater-on current Ion becomes “0 ampere” due to the interruption of the electric path.
[0035]
On the other hand, when the heater is not energized (when the MOS 26 is turned off), the heater off voltage Voff is obtained from the product of the power supply voltage VB and the resistance divided value (R1 / (R1 + R2)). That means
Voff = {R1 / (R1 + R2)} · VB
The heater-off voltage Voff is obtained from the above formula, specifically, a value of about “9 volts”. The heater off current Ioff is “0 amperes”. In the case of such a failure of the C section opening, Ion and Voff are greatly different from the normal values, thereby making it possible to determine the failure.
[0036]
(4) In the case of D part opening of FIG.
At the time of failure of “D part open” due to disconnection or the like, Von = 12 volts, Ion = 0 ampere, Voff = 9 volts, Ioff = 0 ampere as in the case of the failure of the C part open. Incidentally, the same detection result can be obtained when a failure such as the heater 33 itself being damaged occurs.
[0037]
(5) In the case of E part opening of FIG.
At the time of failure of “E part open” due to disconnection etc., when the heater is energized (when MOS 26 is on),
Von = {R1 / (R1 + R2)} · VB
The heater-on voltage Von is obtained from the above formula. Specifically, Von has a value of about “9 volts”. Here, since the heater 33 can be energized when the E portion is opened, the heater-on current Ion is detected as normal (Ion = 5 amperes).
[0038]
On the other hand, when the heater is not energized (when the MOS 26 is turned off), the heater off voltage Voff is similar to the heater on voltage Von.
Voff = {R1 / (R1 + R2)} · VB
Specifically, it is a value of about “9 volts”. The heater off current Ioff is “0 amperes”. In the case of such an E portion opening, Voff is greatly different from the normal value, and thus it is possible to determine a failure.
[0039]
(6) In the case of F part opening of FIG.
At the time of failure of “F section open” due to disconnection or the like, the electric paths such as the battery power source + B, the heater 33, the MOS 26, and the GND are cut off. Therefore, regardless of whether the heater 33 is energized or not (MOS 26 is turned on / off), the heater voltage and current value are equal to the values when the MOS 26 is turned off. That is, Von = 0 volt, Ion = 0 ampere, Voff = 0 volt, and Ioff = 0 ampere. In this case, Von and Ion are greatly different from the normal value, thereby making it possible to determine whether a failure has occurred.
[0040]
(7) In case of G part opening in FIG.
Even in the case of failure of “G part open” due to disconnection or the like, the electric path such as the battery power source + B, the heater 33, the MOS 26, and GND is cut off as in the case of the F part open in (6) above. Therefore, regardless of whether the heater 33 is energized or not (MOS 26 is turned on / off), the heater voltage and current value are the same as when the MOS 26 is turned off. That is, Von = 0 volt, Ion = 0 ampere, Voff = 0 volt, and Ioff = 0 ampere. In this case, Von and Ion are greatly different from the normal value, thereby making it possible to determine whether a failure has occurred.
[0041]
(8) In case of D, E, F-GND short circuit in Fig. 4
At the time of this “D, E, F-GND short circuit” failure, the heater voltage is almost equal to the value when the MOS 26 is ON, regardless of whether the heater 33 is energized or not (MOS 26 is ON / OFF). However, in such a case, there is no voltage drop due to resistance due to the harness or the like, and the same voltage as the power supply voltage VB is applied to both ends of the heater. That is, Von = 12 volts and Voff = 12 volts. Further, since there is no potential difference between both ends of the heater current detection resistor 41, Ion = 0 ampere and Ioff = 0 ampere. In this case, Ion and Voff are greatly different from the normal values, thereby making it possible to determine a failure.
[0042]
Incidentally, the fact that Ion and Voff differ greatly from the normal value is the same as the above-described failure of C part or D part open, but if each Voff is compared, these C part or D part open And D, E, F-GND short circuit faults. This will be described below. When the C part or D part is opened, the Voff value is obtained by the product of the power supply voltage VB and the resistance voltage dividing value (R1 / (R1 + R2)). On the other hand, when D, E, F-GND are short-circuited, the inverting input terminal of the operational amplifier 28a becomes the GND level, and the output of the operational amplifier 28a, that is, the Voff value is obtained as “R1 / R2 × VB”. Therefore, Voff at the time of short circuit between D, E, F and GND is higher than Voff at the time of opening C part and D part, and if a threshold voltage for determining the Voff value of both is set, It becomes possible to distinguish between the C part or D part open and the D, E, F-GND short circuit.
[0043]
(9) When MOS26 is always ON
When the “MOS 26 is always ON” failure, the heater voltage and current value are equal to the values when the heater is energized, regardless of whether the heater 33 is energized or not. That is, Von = 11 volts, Ion = 5 amps, Voff = 11 volts, Ioff = 5 amps. In this case, Voff and Ioff are greatly different from the normal values, thereby making it possible to determine the occurrence of a failure.
[0044]
(10) When MOS26 is always OFF
When the “MOS 26 is always OFF” failure, the heater voltage and current value are equal to the values when the heater 33 is not energized, regardless of whether the heater 33 is energized or de-energized. That is, Von = 0 volt, Ion = 0 ampere, Voff = 0 volt, and Ioff = 0 ampere. In this case, Von and Ion are greatly different from the normal value, thereby making it possible to determine whether a failure has occurred.
[0045]
Next, the operation of the apparatus of the present embodiment configured as described above will be described.
FIG. 5 is a flowchart showing a heater control routine, FIG. 6 is an initial processing routine which is a subroutine of FIG. 5, and FIGS. 7 to 9 are flowcharts showing failure determination routines of the heater control system. Each of these routines is started by a timer interrupt at a predetermined interval (for example, 128 msec cycle) by the CPU 20a in the microcomputer 20. However, the routines of FIGS. 7 to 9 are executed immediately after the routine of FIG.
[0046]
In the heater control routine of FIG. 5, the CPU 20a first determines in step 101 whether or not the initial flag XINT is “0”. This initial flag XINT indicates whether or not the initial processing required when the IG key is turned on has been performed. XINT = 0 indicates that the initial processing has not been performed, and XINT = 1 indicates that the initial processing has been performed. It represents that it is finished. If XINT = 0, the CPU 20a proceeds to step 120, performs the initial processing shown in FIG. 6, and then ends this routine once.
[0047]
Here, the initial processing routine of FIG. 6 will be described. In this initial process, before the energization control of the heater 33 is started, the heater off voltage Voff and the heater off current Ioff are first detected, and then the heater 33 is energized (ON) to determine the voltage value when the heater is on. The current value is detected. Specifically, the CPU 20 a first detects the heater off voltage Voff and the heater off current Ioff based on the output values of the heater voltage detection circuit 28 and the heater current detection circuit 29 in step 121. Further, the CPU 20a energizes the heater 33 and waits for a predetermined time in that state (steps 122 and 123). This standby time is the time required for the voltage and current value to converge after the heater is energized, and specifically, it may be about 200 μsec.
[0048]
After waiting for a predetermined time, the CPU 20a detects the heater-on voltage Von and the heater-on current Ion in step 124, and in step 125, sets the initial flag XINT to “1”. Thereafter, the CPU 20a sets “1” to the all energization flag XZN in step 126 and returns to the routine of FIG. Here, the all energization flag XZN indicates whether or not all energization control, which will be described later, is performed. XZN = 1 indicates that all energization control is performed, and XZN = 0 indicates that all energization control is performed. Represents not being implemented.
[0049]
On the other hand, when the initial flag XINT is set in the initial process routine, step 101 in FIG. 5 is positively determined every time thereafter. In step 102, the CPU 20a determines whether the failure occurrence flag XFAIL is “0”. This failure occurrence flag XFAIL indicates a determination result of the presence or absence of a failure in the heater control system, where XFAIL = 0 indicates that there is a failure in the heater control system, and XFAIL = 1 indicates that there is no failure in the heater control system. . The flag XFAIL is operated in a failure determination routine shown in FIGS. If the failure occurrence flag XFAIL is “1”, the CPU 20a makes a negative determination in step 102 and ends the present routine as it is. That is, the energization control of the heater 33 is not performed.
[0050]
If the failure occurrence flag XFAIL is “0”, the CPU 20a proceeds to step 103, where the element impedance Zdc is a predetermined determination value for determining the semi-active state of the sensor main body 32 (in this embodiment, 200 ohms). It is determined whether or not the degree is less than or equal to. Here, the element impedance Zdc is detected as follows. That is, when detecting the element impedance Zdc, as shown in FIG. 10, the applied voltage of the A / F sensor 30 is temporarily changed in the positive direction and the negative direction. Then, the element impedance Zdc is calculated from either the positive or negative voltage change amount ΔV and the current change amount ΔI during the voltage change (Zdc = ΔV / ΔI). However, this calculation method is an example, and the sensor when the element impedance Zdc is detected based on the amount of change in voltage and current on both sides of the positive and negative, or when the negative applied voltage Vneg (voltage that does not fall within the limit current detection range) is applied. The element impedance Zdc may be detected from the current Ineg (Zdc = Vneg / Ineg).
[0051]
For example, when the element temperature is low, such as when the engine 10 is cold started, Zdc> 200 ohms, and the CPU 20a proceeds to step 104 to determine whether or not the failure temporary flag XTEM is “1”. Here, the temporary failure flag XTEM is operated to “1” when the occurrence of a failure in the heater control system is temporarily determined at the time of engine start, and this operation is performed by a failure determination routine described later. To be implemented.
[0052]
If XTEM = 0, that is, if it is not temporarily determined that a failure has occurred when the engine is started, the CPU 20a proceeds to step 105 and performs “all energization control” of the heater 33. In this full energization control, the control duty ratio signal to the heater 33 is maintained at 100%, and sensor activation is preferentially implemented.
[0053]
On the other hand, if XTEM = 1, that is, if it is temporarily determined that a failure has occurred when the engine is started, the CPU 20a proceeds to step 106 and performs “98% duty control” of the heater 33. In the 98% duty control, the heater OFF time of about Duty = 2% is set so that the heater off voltage Voff and the heater off current Ioff can be continuously detected at the time of provisional determination of failure occurrence. By detecting Voff and Ioff in this manner, failure determination by a failure determination routine described later can be performed. Thereafter, the CPU 20a sets “1” to the all energization flag XZN in step 107 and once ends this routine.
[0054]
After the heater energization is started, the element temperature rises due to the heating action of the heater 33 (or the element temperature is high from the beginning), and when the step 103 is positively determined, the CPU 20a proceeds to step 108, and the all energization flag is Clear XZN to “0”. In step 109, the CPU 20a determines whether or not the element impedance Zdc is equal to or less than a predetermined determination value (in the present embodiment, about 40 ohms) for starting feedback (F / B) control. Here, the determination value of step 109 is used to determine the active state of the sensor body 32, and is set as a value of about “+10 ohms” with respect to the target impedance (in this embodiment, 30 ohms). Yes.
[0055]
When the activation of the A / F sensor 30 is not completed and the determination at Step 109 is negative, the CPU 20a proceeds to Step 110 and controls the energization of the heater 33 by “power control”. At this time, as shown in the map of FIG. 11, a power command value is determined according to the element impedance Zdc, and a control duty ratio for energizing the heater is calculated according to the power command value.
[0056]
On the other hand, when the activation of the A / F sensor 30 is completed and the determination at Step 109 is affirmative, the CPU 20 a performs “element impedance F / B control” at Step 111. In this element impedance F / B control, the duty ratio Duty for heater energization is calculated in the following procedure. In the present embodiment, a PID control procedure is used as an example.
[0057]
That is, first, the proportional term GP, the integral term GI, and the differential term GD are calculated by the following equations (1) to (3).
GP = KP · (Zdc−ZdcTG) (1)
GI = GIi-1 + KI. (Zdc-ZdcTG) (2)
GD = KD. (Zdc-Zdci-1) (3)
In the above equation, “KP” is a proportional constant, “KI” is an integral constant, and “KD” is Fine The subscript “i−1” represents a value at the time of the previous process.
[0058]
Then, the duty ratio Duty for energizing the heater is calculated by adding the proportional term GP, the integral term GI, and the differential term GD (Duty = GP + GI + GD). However, such a heater control procedure is not limited to the PID control described above, and PI control or P control may be performed.
[0059]
Thereafter, in step 112, the CPU 20a determines whether or not the duty ratio Duty set by the element impedance F / B control is larger than a predetermined lower limit guard value. The lower limit guard of the duty ratio Duty limits the duty not to be “0%” even when the exhaust gas temperature is high and heater energization is unnecessary, such as during high load operation. It may be set to about “1%”. Thus, even when the heater energization is unnecessary, the heater energization is performed with a small duty so that the heater on voltage Von and the heater on current Ion can be detected under any operating condition, and the failure determination by the failure determination routine described later is performed. It becomes possible.
[0060]
If the duty ratio Duty is less than the lower limit guard value, the CPU 20a limits the duty ratio Duty with the lower limit guard value (1%) in Step 113, and then ends this routine. On the other hand, if the duty ratio Duty is equal to or greater than the lower limit guard, the CPU 20a ends this routine as it is.
[0061]
Next, the failure determination process of the heater control system will be described. In the failure determination process of the present embodiment, various failures in the heater control system shown in FIG. 15 are determined based on the heater on voltage Von, the heater on current Ion, the heater off voltage Voff, and the heater off current Ioff. Von, Ion, Voff, and Ioff are basically detected in synchronization with the rise of “OFF → ON” of the energization control signal of the heater 33. However, only when the IG key is turned ON, Von, Ion, Voff, and Ioff are detected according to the above-described initial processing.
[0062]
FIG. 12 is a time chart for explaining detection timings of Von, Ion, Voff, and Ioff corresponding to the energization control signal of the heater 33. The time-up counter in the figure is counted up at a cycle of 4 msec, and the count value changes within the range of “0” to “32”. At this time, the timing at which the time-up counter is cleared to “0” and the rising timing of the energization control signal of the heater 33 are synchronized. The heater off voltage Voff and the heater off current Ioff are detected immediately before the count value of the time-up counter is cleared to “0”, that is, the count value = 31 (the timing of ▼ in the figure), and the count value is set to “0”. The heater on voltage Von and the heater on current Ion are detected immediately after being cleared, that is, at a count value = 1 (timing of ▽ in the figure). The detected values of Von, Ion, Voff, and Ioff are stored and held in the RAM 20c in the microcomputer 20 as needed.
[0063]
Further, “Vth” in the figure is a threshold voltage for determining the suitability of the on-voltage and off-voltage Von, Voff of the heater 33, and “Ith” is the on-current and off-current Ion, This is a threshold current for determining the suitability of Ioff. These threshold values Vth and Ith are set in advance. Specifically, Vth = 5 volts and Ith = 1.5 amperes.
[0064]
Hereinafter, failure determination processing corresponding to Von, Ion, Voff, and Ioff detected as described above will be described with reference to the flowcharts of FIGS. When the failure determination routine of the heater control system starts, the CPU 20a first determines whether or not the initial flag XINT is “1” in step 201 of FIG. Then, on the condition that XINT = 1, the CPU 20a reads the latest values of Von, Ion, Voff, and Ioff in the RAM 20c in step 202.
[0065]
Thereafter, the CPU 20a determines whether or not the heater control system is normal from the values of Von, Ion, Voff, and Ioff read in step 203 and predetermined threshold values Vth and Ith. Here, in this step, it is determined whether or not all of the following four conditions are satisfied. That is,
・ Von> Vth,
・ Ion> Ith,
・ Voff <Vth,
・ Ioff <Ith,
It is determined whether or not all are satisfied. In this case, if the heater control system is normal, all the above four conditions are satisfied (see FIG. 15), and the CPU 20a clears the temporary failure flag XTEM to “0” in step 203a, and then ends this routine.
[0066]
On the other hand, if the condition of step 203 is not satisfied, the processing after step 204 is executed assuming that there is a high possibility that some failure has occurred in the heater control system. In the following, description will be given in order. In step 204, the CPU 20a determines whether or not all of the following four conditions are satisfied. That is,
・ Von <Vth,
・ Ion <Ith,
・ Voff <Vth,
・ Ioff <Ith,
It is determined whether or not all are satisfied. In this case, if a failure such as the A part, the F part or the G part in FIG. That is, as shown in FIG. 15, when a failure occurs such as A part, F part or G part open, or MOS 26 is always OFF, Voff and Ioff values are normal values, whereas Von and Ion values are normal values. It is smaller than the normal value and falls below the threshold values Vth and Ith (Von = 0 volts, Ion = 0 amperes). If the determination in step 204 is affirmative, the CPU 20a stores in step 205 the failure location and failure mode (failure information indicating that the A portion, F portion or G portion is open, or the MOS 26 is normally OFF) in the backup RAM 20d.
[0067]
If the condition of step 204 is not satisfied, the CPU 20a proceeds to step 206 and determines whether or not all of the following four conditions are satisfied. That is,
・ Von <Vth,
・ Ion> Ith,
・ Voff <Vth,
・ Ioff <Ith,
It is determined whether or not all are satisfied. In this case, if a failure such as part B opening in FIG. 4 has occurred, an affirmative determination is made in step 206. That is, as shown in FIG. 15, when a failure occurs such as part B opening, the values of Ion, Voff, and Ioff are normal values, whereas only the value of Von is smaller than the normal value, and the threshold value Vth is set. (Von = 0 volts). If the determination in step 206 is affirmative, the CPU 20a causes the backup RAM 20d to store the failure location and mode (failure information for opening part B) at that time in step 207.
[0068]
On the other hand, if the condition in step 206 is not satisfied, the CPU 20a proceeds to step 208 in FIG. 8, and determines whether or not all the following four conditions are satisfied. That is, Von> Vth,
・ Ion <Ith,
・ Voff> Vth,
・ Ioff <Ith,
It is determined whether or not all are satisfied. In this case, if a failure such as the opening of the part C or D in FIG. 4 or a short circuit between D, E, F and GND has occurred, an affirmative determination is made in step 208. That is, as shown in FIG. 15, when a failure occurs such as C part or D part open or D, E, F-GND short circuit, Von and Ioff values are normal values (however, Von is 12 volts, which is a substantially normal value), the value of Ion is smaller than the normal value and falls below the threshold value Ith (Ion = 0 amperes). Further, the value of Voff is larger than the normal value and exceeds the threshold value Vth (Voff = 9 volts or 12 volts).
[0069]
Further, when the determination in step 208 is affirmative, in step 209, the CPU 20a distinguishes whether the failure at that time is due to opening of the C part or D part or due to a short circuit between D, E, and F-GND. Specifically, when a failure such as C part or D part open or D, E, F-GND short-circuit occurs, the value of Voff exceeds the threshold value Vth (= 5 volts) in any case. Thus, the value of Voff when the C part or the D part is open is lower than the value of Voff when D, E, F-GND is short-circuited. The Voff in the former case is about 9 volts, and the Voff in the latter case is about 12 volts. Therefore, a second threshold voltage Vth2 is set between these two values (Vth2 = 10.5 volts or so), and the threshold voltage Vth2 is compared with Voff.
[0070]
That is, the CPU 20a determines whether or not Voff <Vth2 is established in step 209. If Voff <Vth2, the CPU 20a proceeds to step 210, assumes that a failure has occurred due to the opening of the C or D portion, and stores failure information to that effect in the backup RM 20d. If Voff ≧ Vth2, the CPU 20a proceeds to step 211, regards that a failure has occurred due to a short circuit between D, E, and F-GND, and stores failure information to that effect in the backup RAM 20d.
[0071]
On the other hand, if the condition of step 208 is not satisfied, the CPU 20a proceeds to step 212 and determines whether or not all of the following four conditions are satisfied. That is,
・ Von> Vth,
・ Ion> Ith,
・ Voff> Vth,
・ Ioff <Ith,
It is determined whether or not all are satisfied. In this case, if a failure such as the opening of the E portion in FIG. 4 has occurred, an affirmative determination is made in step 212. That is, as shown in FIG. 15, Von, Ion, and Ioff values are normal values when a failure such as an E portion opening occurs (however, Von is 9 volts, which is a substantially normal value). Only the value of is larger than the normal value and exceeds the threshold value Vth (Voff = 9 volts). If the determination in step 212 is affirmative, in step 213, the CPU 20a stores the failure location and mode (failure information for opening the E section) at that time in the backup RAM 20d.
[0072]
If the condition of step 212 is not satisfied, the CPU 20a proceeds to step 214 and determines whether or not all of the following four conditions are satisfied. That is,
・ Von> Vth,
・ Ion> Ith,
・ Voff> Vth,
・ Ioff> Ith,
It is determined whether or not all are satisfied. In this case, if there is a failure such as the MOS 26 of FIG. That is, as shown in FIG. 15, when a failure occurs such that the MOS 26 is always ON, the values of Von and Ion are normal values, whereas the values of Voff and Ioff are larger than the normal values and the threshold values Vth, It will exceed Ith (Voff = 11 volts, Ioff = 5 amps). If the determination in step 214 is affirmative, the CPU 20a stores the failure location and mode (failure information in which the MOS 26 is always ON) in the backup RAM 20d in step 215. If the condition in step 214 is not satisfied, the CPU 20a ends the routine as it is.
[0073]
After it is determined that a failure has occurred according to the series of failure determinations (after the processing of steps 205, 207, 210, 211, 213, and 215), the CPU 20a performs the processing of steps 216 to 221 in FIG. Specifically, the CPU 20a determines whether or not the all energization flag XZN is “1” in step 216, that is, whether or not the all energization control (or 98% duty control) of the heater 33 is currently being performed. Determine. If XZN = 0 and the power control or element impedance F / B control of the heater 33 is being performed, the CPU 20a makes a negative determination in step 216 and immediately proceeds to step 220. The CPU 20a sets “1” to the failure occurrence flag XFAIL at step 220 and turns on the failure warning lamp 42 at the subsequent step 221, and then ends this routine. When the failure warning lamp 42 is turned on, a vehicle passenger is warned that a failure has occurred.
[0074]
On the other hand, if XZN = 1 and full energization control (or 98% duty control) of the heater 33 is being performed, the CPU 20a makes an affirmative determination in step 216 and proceeds to step 217 to set “1” in the temporary failure flag XTEM. Set to "". Thereafter, the CPU 20a increments the counter CZN by “1” in Step 218, and determines whether or not the counter CZN is equal to or greater than a predetermined determination value KC in subsequent Step 219. This determination value KC is a time required to determine the occurrence of a failure, and is a count value corresponding to about “3 seconds” in the present embodiment.
[0075]
When CZN <KC, the CPU 20a ends this routine as it is. If CZN ≧ KC, the CPU 20a proceeds to step 220. The CPU 20a sets “1” to the failure occurrence flag XFAIL at step 220 and turns on the failure warning lamp 42 at the subsequent step 221, and then ends this routine.
[0076]
Incidentally, in the failure determination routines of FIGS. 7 to 9 described above, if the failure of the heater 33 is not determined at the beginning of energization and all the energization control is performed, it is impossible to detect Voff and Ioff. Become. Therefore, in such a case, the process for determining the failure is temporarily suspended until the all-energization control is terminated and the power control or the element impedance F / B control is started. If Voff and Ioff can be detected, the failure determination can be performed).
[0077]
In the present embodiment, the heater control routine of FIG. 5 corresponds to the heater control means described in the claims, and the failure determination routines of FIGS. 7 to 9 correspond to the failure determination means. Further, the process of step 105 in FIG. 5 corresponds to all energization means, and the process of step 120 and FIG. 6 in FIG. 5 corresponds to initial value detection means.
[0078]
13 and 14 are time charts showing the heater energization control operation at the time of starting the engine 10 at a low temperature, the transition of the heater current, and the state of operation of various flags. FIG. 13 shows any failure in the heater control system. FIG. 14 shows a case where a failure has occurred.
[0079]
In FIG. 13, at time t1, the microcomputer 20 is powered on, and initial processing is performed during the period of time t1 to t2 (see the flow in FIG. 6). In this case, after the heater off voltage Voff and the heater off current Ioff are detected, the heater on voltage Von and the heater on current Ion are detected. And failure determination is implemented using each value of this first Voff, Ioff, Von, and Ion (refer the flow of the said FIGS. 7-9). At the beginning of energization of the heater, the heater current is relatively large because the heater resistance is small, but the heater current converges to a normal value (5 amperes) with warming up.
[0080]
At time t2, “1” is set to the initial flag XINT, and “1” is set to the all energization flag XZN. Thereafter, in the period of time t2 to t4, all energization control of the heater 33 is performed. That is, the control duty ratio Duty of heater energization is maintained at 100%. The time required for the full energization control varies depending on the degree of the cold state of the A / F sensor 30, but is about 7 seconds at the longest. At time t4, the all energization flag XZN is cleared to “0”, and thereafter, the power control and element impedance F / B control of the heater 33 are performed (see the flow of FIG. 5).
[0081]
In FIG. 13, when it is temporarily determined that a failure has occurred based on Von, Ion, Voff, and Ioff detected in the initial process, “1” is set in the failure temporary flag XTEM at time t2, as indicated by a broken line in the figure. ”Is set, and“ 98% Duty control ”is performed with 2% of the duty ratio Duty as the OFF time (step 106 in FIG. 5). In such a case, if the determination of the occurrence of the failure is temporary, the failure temporary flag XTEM is reset to “0” at time t3 in FIG. 7 (step 203a in FIG. 7), and the heater energization is completely changed from the 98% duty control. Switch to energization control (step 105 in FIG. 5).
[0082]
On the other hand, in FIG. 14, any of the various failures shown in FIG. 15 has occurred since the beginning of energization. In this case, failure determination is performed using each value of Von, Ion, Voff, and Ioff detected by the initial process at times t11 to t12, and a provisional determination is made that a failure has occurred. At time t12, the failure temporary flag XTEM and the like are set, and the counter CZN starts counting up (steps 217 and 218 in FIG. 9).
[0083]
After the time t12, if the failure occurrence is not resolved during the execution of the 98% duty control, the failure occurrence flag XFAIL is set to “1” at the time t13 when the value of the counter CZN reaches the predetermined determination value KC (FIG. 9 step 220). At this time, failure information such as failure location and failure mode is stored in the backup RAM 20d, and the failure warning lamp 42 is turned on. Then, energization of the heater after that is stopped.
[0084]
As described above, 98% duty control is performed during the period in which all energization control is originally performed, and the heater non-energization operation is forcibly performed. Therefore, each value of Voff and Ioff is detected at the time of temporary determination of the occurrence of a failure. It becomes possible. Therefore, the failure of the heater control system can be accurately grasped, and there is no inconvenience such as excessive temperature rise of the sensor.
[0085]
When the failure warning lamp 42 is turned on as described above, the vehicle in which the failure has occurred is brought into a repair shop or the like according to this warning. If the failure information stored in the backup RAM 20d is read by a diagnostic checker or the like, the trouble location can be easily identified without requiring complicated work, and repair work corresponding to the trouble at that time is performed. .
[0086]
According to the embodiment described in detail above, the following effects can be obtained.
(A) In the present embodiment, four values consisting of a voltage and currents Von and Ion when the heater is energized and a voltage and currents Voff and Ioff when the heater is not energized are set to predetermined threshold values Vth and Ith, respectively. Then, the presence / absence of a failure is determined according to which of the compared four values is different from the normal value, and the failure location is specified. According to the above configuration, it is possible to identify a failure point of the heater control system, which is insufficient with the existing apparatus. That is, when a failure occurs in the heater control system, this is accurately determined, and the failure location can be specified in detail. In such a case, the use of the above-described failure location identification result makes it possible to greatly simplify the failure location identification work required until actual repair. As a result, the effect of improving maintainability and workability can be obtained.
[0087]
(B) In the present embodiment, the failure determination corresponding to the actual machine can be realized by specifying various failures as shown in FIG. 15 for each occurrence location or for each mode.
[0088]
(C) At the beginning of energization of the heater 33 accompanying the engine start, the heater off voltage Voff and the heater off current Ioff are detected before the start of all energization control. The voltage Von and the heater on-current Ion are detected (the initial process in FIG. 6). Then, failure determination is performed according to the detected values of Voff, Ioff, Von, and Ion. In this case, if full energization control of the heater 33 is performed (Duty = 100%), even if a failure occurs, Voff and Ioff cannot be detected and an accurate failure determination becomes impossible. By detecting Voff and Ioff before the start of energization, it becomes possible to detect four values consisting of Von, Ion, Voff, and Ioff. As a result, the desired failure determination as described above can be performed.
[0089]
(D) When it is determined that a failure has occurred at the beginning of heater energization, “98% duty control” is performed to cut off the heater energization for the minimum time that Voff and Ioff can be detected (see FIG. Step 106 in FIG. 5) If it is determined that the failure of the heater control system has continued for a predetermined time or longer in this state, it is finally determined that the failure has occurred (Step 216 in FIG. 9). ~ 221). In this case, erroneous determination of a failure can be avoided even at the time of a temporary failure determination at the start of the engine, and a more accurate failure determination becomes possible.
[0090]
(E) Further, in the present embodiment, the control duty ratio Duty is limited to a predetermined lower limit guard value (1%) (steps 112 and 113 in FIG. 5). In this case, the heater on voltage Von and the heater on current Ion can be reliably detected even when the exhaust gas temperature is high and heater energization is not necessary (when Duty = 0%), for example, when the engine 10 is in a high load operation. it can. Therefore, it becomes possible to always detect the four values consisting of Von, Ion, Voff, and Ioff, and to perform the desired failure determination as described above.
[0091]
(F) Moreover, if the failure of the heater control system can be accurately grasped as described above, a normal active state of the A / F sensor 30 can be maintained. As a result, highly accurate air-fuel ratio F / B control can be performed, emissions can be reduced, and legal regulations relating to exhaust gas regulations can be appropriately handled.
[0092]
The embodiment of the present invention can be realized in the following form in addition to the above.
In the above embodiment, in the heater control system failure determination routine (FIGS. 7 to 9),
・ Von> Vth,
・ Ion <Ith,
・ Voff> Vth,
・ Ioff <Ith,
When the failure that satisfies the above four conditions is satisfied (when step 208 of FIG. 8 is YES), the value of Voff is compared with the second threshold voltage Vth2, and the failure due to the opening of the C part or the D part, Although the failure due to the short circuit between D, E, and F-GND has been determined (steps 209 to 211 in FIG. 8), this configuration may be changed. For example, if the process of step 209 is omitted and step 208 is affirmed, it is concluded that a failure has occurred due to "C or D part open or D, E, F-GND short circuit". Also good.
[0093]
Further, the number or mode of failure determination may be reduced as compared with the above-described embodiment (see FIG. 15), and the calculation load by the CPU 20a may be reduced. Specifically, in consideration of the occurrence frequency and priority order of failures, all or a part of failures such as E portion opening, F portion opening, G portion opening and MOS 26 always ON and always OFF in FIG. It may be excluded from the target. In short, failures such as A portion opening, B portion opening, C portion opening, D portion opening and D, E, F-GND short circuit in FIG. In this case, a failure with a high occurrence frequency or a failure with a high priority can be appropriately determined. However, when it is analyzed that most of the causes of the failure are due to the inability to turn on / off the semiconductor switching element, it is also possible to limit the failure determination target to the ON / OFF failure of the switching element.
[0094]
In the above-described embodiment, full energization control of the heater 33 is performed at the beginning of the engine 10 at a low temperature. That is, the heater 33 is heated by 100% energization. By changing this configuration, the control duty ratio of the heater 33 may be limited by an upper limit guard value of, for example, “98%”. In this case, unlike the heater control routine of FIG. 5 described above, it is not necessary to distinguish between “full energization control” and “98% energization control” before the sensor activation. According to such a configuration, the upper limit and the lower limit of the control duty ratio are limited within the range of “1% to 98%”, and each value of Von, Ion, Voff, and Ioff can always be detected. However, the limitation of the duty ratio by the upper limit and the lower limit guard is not an essential requirement in the present invention, and can be embodied by being omitted as appropriate.
[0095]
In the above embodiment, the occurrence of failure is provisionally determined at the beginning of heater energization, and the occurrence of failure is confirmed when the state has exceeded a predetermined time (steps 216 to 221 in FIG. 9). ), Such provisional determination processing may be applied to other than the beginning of heater energization. In this case, an erroneous determination that a failure has occurred can be prevented. Conversely, in order to simplify the arithmetic processing, the provisional determination processing may be deleted and embodied.
[0096]
The configuration of the heater control circuit 25 may be changed as follows.
A heater control circuit 25 shown in FIG. 16 is obtained by changing a part of FIG. 4. Specifically, the configuration of the heater current detection circuit is changed. The heater current detection circuit 45 of FIG. 16 includes an operational amplifier 45a, resistors 45b and 45c connected to the non-inverting input terminal of the operational amplifier 45a, a constant voltage power supply Vcc (5 volts), and a resistor 45d connected to the inverting input terminal. , 45e, a differential amplifier circuit. The detection circuit 45 converts the heater current Ih detected by the heater current detection resistor 41 into a voltage signal and outputs the result to the microcomputer 20 via the A / D converter 24. Unlike the configuration shown in FIG. 4, this configuration has an output characteristic that the output of the operational amplifier 45a decreases as the heater current Ih increases.
[0097]
In the heater control circuit of FIG. 17, the voltage detection means and the current detection means are configured by the A / D converter 24 and the microcomputer 20. In this configuration, the battery side potential of the heater 33 is input to “CH1” of the A / D converter 24 via the resistors 46a and 46b, and the GND side potential of the heater 33 is A / D converted via the resistors 46c and 46d. Is input to “CH 2” of the device 24. Further, the heater-side potential of the heater current detection resistor 41 is input to “CH 3” of the A / D converter 24. Then, the microcomputer 20 detects both-end voltages (Von, Voff) and heater currents (Ion, Ioff) of the heater 33 based on signals taken into CH1, CH2, and CH3 of the A / D converter 24.
[0098]
As another form, it is possible to configure the heater control circuit by combining FIGS. 4, 16, and 17, or to apply the heater current low-side detection configuration or the heater current high-side detection configuration. is there. These circuit configurations are selectively used as appropriate according to the design concept of each engine.
[0099]
A threshold for comparing and determining the detected values (Von, Ion) of the voltage and current when the heater is energized and a threshold for comparing and determining the detected values (Voff, Ioff) of the voltage and current when the heater is not energized The value may be provided separately. That is, in the configuration of the present embodiment, when the heater control system is normal, Von = 11 volts, Ion = 5 amperes, Voff = 0 volts, Ioff = 0 amperes or a value in the vicinity thereof. So, for example,
・ The threshold voltage (Vthon) when the heater is energized is about 9 volts.
・ The threshold current (Ithon) when the heater is energized is set to about “4 amps”.
・ When the heater is not energized, the threshold voltage (Vthoff) is set to about "2 volts"
-The threshold current (Ithoff) when the heater is not energized is set to about "1 ampere".
Set each. And
・ Von> Vthon,
・ Ion> Ithon,
・ Voff <Vthoff,
・ Ioff <Ithoff,
Only when these four conditions are satisfied, it is determined that the heater control system is normal. Otherwise, the four detection values (Von, Ion, Voff, Ioff) are set to the four threshold values. On the other hand, the failure location and mode of the heater control system are specified with reference to FIG. 15 according to the magnitude relationship. According to such a configuration, it becomes possible to perform failure determination more accurately.
[0100]
In the above embodiment, the present invention is embodied in a cup-type A / F sensor, but may be embodied in a laminated A / F sensor.
In the above-described embodiment, the present invention is embodied in the limiting current type air-fuel ratio sensor (A / F sensor). However, the present invention can be embodied in other gas concentration sensors. For example, the present invention may be embodied by an O2 sensor that outputs a voltage signal (electromotive force) that differs depending on whether the air-fuel ratio is rich or lean with respect to the stoichiometric air-fuel ratio (stoichiometric). In short, the present invention can be applied to any gas concentration sensor that needs to be heated by a heater for activation, such as a sensor for detecting the gas concentration of NOx, HC, CO, or the like.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing an outline of an air-fuel ratio detection apparatus in an embodiment of the invention.
FIG. 2 is a cross-sectional view showing a detailed configuration of an A / F sensor.
FIG. 3 is a VI characteristic diagram for explaining output characteristics of an A / F sensor.
FIG. 4 is a circuit diagram showing a configuration of a heater control circuit.
FIG. 5 is a flowchart showing a heater control routine.
FIG. 6 is a flowchart showing an initial processing routine.
FIG. 7 is a flowchart showing a failure determination routine of the heater control system.
FIG. 8 is a flowchart showing a failure determination routine of the heater control system, following FIG. 7;
FIG. 9 is a flowchart showing a failure determination routine of the heater control system, following FIGS. 7 and 8;
FIG. 10 is a waveform diagram for explaining an example of a detection method of element impedance.
FIG. 11 is a map for obtaining a power command value corresponding to the element impedance during power control.
FIG. 12 is a time chart for explaining heater end-to-end voltage and heater current corresponding to a heater energization control signal, and detection timing of each value.
FIG. 13 is a time chart for explaining a control operation at the time of engine start.
FIG. 14 is a time chart for explaining a control operation at the time of engine start.
FIGS. 15A and 15B are diagrams for explaining various failure modes and heater voltage and heater current values when normal and when a failure occurs; FIGS.
FIG. 16 is a circuit diagram showing a configuration of a heater control circuit in another embodiment.
FIG. 17 is a circuit diagram showing a configuration of a heater control circuit in another embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Engine, 12 ... Exhaust pipe, 20 ... Microcomputer (microcomputer), 20a ... Heater control means, failure determination means, all energization means, CPU which comprises initial value detection means, 20d ... Backup RAM, 24 ... A / D Converter, 26 ... MOS (n-channel MOS transistor) as semiconductor switching element, 28 ... Heater voltage detection circuit constituting voltage detection means, 29 ... Heater current detection circuit constituting current detection means, 30 ... Gas concentration sensor A / F sensor (limit current type air-fuel ratio sensor), 33... Heater, 41... Heater current detection resistor constituting current detection means, 42.

Claims (8)

A heater attached to the gas concentration sensor and energized by power supply from a power source;
Applied to a heater control system comprising heater control means for on / off control of energization of the heater at a predetermined control duty ratio;
Voltage detection means connected in parallel to the heater and detecting the voltage at both ends of the heater at the time of heater energization and non-energization accompanying on / off control by the predetermined control duty ratio ;
Current detection means connected in series to the heater and detecting the current flowing through the heater when the heater is energized and de-energized with the on / off control according to the predetermined control duty ratio ;
The then compares with the detected heater current when the voltage and current and Heater-energized when the voltage and current and four values each in a predetermined threshold value consisting of four that the comparison value sac lichen Or a failure determination means for determining whether or not there is a failure according to a combination of these four values, and for identifying a failure location in a circuit constituting the heater control system. A failure determination device for a heater control system used for a gas concentration sensor. 2. The heater control used in the gas concentration sensor according to claim 1, wherein the failure determination unit is configured to identify a failure in which an electrical path connecting the power source side, ground side electrical path of the heater and the heater is opened. System failure determination device. 2. The failure determination device for a heater control system used for a gas concentration sensor according to claim 1, wherein the failure determination unit identifies a failure that opens an electrical path connecting the heater and the voltage detection unit. A semiconductor switching element for interrupting an electrical path between the heater and the ground side is provided by a duty signal of the heater control means,
The failure determination device for a heater control system used for a gas concentration sensor according to claim 1, wherein the failure determination means specifies a failure in which an electrical path on the ground side of the heater is short-circuited. In accordance with a duty signal of the heater control means, a semiconductor switching element is provided for intermittently connecting an electric path connecting the power source, the heater and the ground,
2. The failure determination device for a heater control system used for a gas concentration sensor according to claim 1, wherein the failure determination unit specifies a failure that makes it impossible to switch on and off the semiconductor switching element. The gas concentration sensor is disposed in an engine exhaust pipe, and is applied to a gas concentration detection system that detects a gas concentration from a measurement result of the gas concentration sensor,
All energization means for setting the control duty ratio of the heater to 100% at the beginning of energization of the heater as the engine starts;
Before starting the heater energization by all the energization means, the both end voltage and current value of the heater are detected, and after the detection, the heater energization is started to detect the both end voltage and current value. Prepared,
The heater control system used in the gas concentration sensor according to any one of claims 1 to 5, wherein the failure determination unit performs failure determination according to each value of voltage and current detected by the initial value detection unit. Failure determination device. The failure determination device for a heater control system according to claim 6,
When it is determined that a failure has occurred according to each detected value of voltage and current by the initial value detecting means, the control duty ratio is set so that the heater energization is cut off for a minimum time that the voltage and current value of the heater can be detected. A means of setting
Means for controlling the heater energization with the set control duty ratio, and finally determining that a failure has occurred if it is determined in that state that a failure has occurred in the heater control system for a predetermined time or longer. A failure determination device for a heater control system used in a gas concentration sensor. The failure determination device for a heater control system used in a gas concentration sensor according to any one of claims 1 to 7, wherein a control duty ratio by the heater control means is limited by a predetermined lower limit guard value or upper limit guard value. .

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