JP5047196B2 - Gas sensor control device and gas sensor control method - Google Patents

Description

  The present invention relates to a sensor control apparatus and a sensor control method for controlling a gas sensor having at least one cell including a solid electrolyte body and a pair of electrodes provided on the solid electrolyte body.

2. Description of the Related Art As a gas sensor that improves fuel consumption and combustion control of an internal combustion engine such as an automobile, an oxygen sensor and an air-fuel ratio sensor that detect an oxygen concentration in exhaust gas are known. Further, with the tightening of exhaust gas regulations for automobiles, it is required to reduce the amount of nitrogen oxide (NO _x ) in the exhaust gas, and a NO _x sensor capable of directly measuring the NO _x concentration has been developed.
These gas sensors have a gas sensor element having one or a plurality of cells formed by forming a pair of electrodes on the surface of an oxygen ion conductive solid electrolyte such as zirconia, and are specified based on the output from the gas sensor element. The gas concentration is detected.
In addition, these gas sensors have a built-in heater for activating the solid electrolyte.

As these gas sensors, two cells (an oxygen concentration detection cell and an oxygen pump cell) are arranged so as to sandwich the measurement chamber, and the gas to be measured is introduced into the measurement chamber via a diffusion resistor, and oxygen contained in the gas to be measured. A full-range air-fuel ratio sensor (hereinafter also referred to as UEGO sensor) is known. Furthermore, in addition to two cells (oxygen concentration detection cell and oxygen pump cell), a NO _x gas sensor having a total of three cells in which a cell for detecting the NO _x gas concentration is arranged is also known.

A sensor driving circuit is connected to such a gas sensor, and the cell is energized through the sensor driving circuit, and the specific gas concentration in the gas to be measured is measured based on the output of the cell, including the sensor driving circuit. It is called a gas sensor control device. In addition, the energized state of the cell includes a protective energized state for protecting the gas sensor, a pre-activated energized state in which a minute current is energized to the inactive gas sensor, and a gas concentration measurement energized state for detecting a specific gas. There are states.
Among these, the energizing state for protection electrically cuts off the conduction between the cell and the sensor drive circuit, prevents current from flowing through the gas sensor, and protects the gas sensor. The pre-activation energization state is a mode for preparing a gas concentration measurement by accumulating a reference concentration oxygen in a reference oxygen chamber of an oxygen concentration detection cell, for example, by energizing a minute current.

By the way, abnormalities such as a short circuit or disconnection with the battery or the ground may occur in the wiring of the sensor driving circuit or the gas sensor. In spite of the occurrence of the wiring abnormality, if the gas concentration measurement energization state for measuring the gas concentration continues, an excessive current may flow through the gas sensor and the gas sensor may be damaged.
For this reason, when a wiring abnormality is detected, the technology for diagnosing the content of the abnormality and the location where the abnormality has occurred is established by electrically disconnecting the connection between the sensor drive circuit side and the gas sensor and setting the current state for protection. It has been developed (see Patent Document 1). Thereby, abnormal current does not continue to flow through the gas sensor, and the gas sensor is prevented from being damaged.

Also, if a command to switch from another energized state to an energized state for gas concentration measurement is output to the sensor drive circuit without recognizing the wiring abnormality, an excessive current may flow to the gas sensor and the gas sensor may be damaged. is there.
For this reason, a technology has been developed that detects an abnormality without damaging the gas sensor by allowing switching to the gas concentration measurement energization state only when the immediately preceding state is the pre-activation energization state. (See Patent Document 2). As a result, even if a wiring abnormality has occurred, the wiring abnormality can be detected because the applied voltage of the gas sensor deviates from the normal range in the pre-activation energization state in which a minute current is supplied to the gas sensor.

Japanese Patent No. 3833687 JP 2008-70194 A

By the way, in the case of the conventional gas sensor control device, even if a wiring abnormality is detected, the heater is controlled in the same manner as when the heater is normal. Therefore, the wiring sensor is detected and the operation of the gas sensor is stopped (engine switch off operation). Later, when the gas sensor was restarted (hot restart), there was a possibility that the temperature of the gas sensor was raised too much and a malfunction occurred.
On the other hand, if the wiring is normal, it may be erroneously detected as abnormal, or the wiring abnormality may be resolved immediately.If the wiring abnormality is detected and heating of the heater is turned off immediately, the wiring abnormality is resolved. Even if the gas sensor is to be restored (operated) normally, it takes time to operate because the gas sensor is too cold.
That is, according to the present invention, if a wiring abnormality is temporarily detected but the abnormality is not fixed, the gas sensor can be quickly returned to normal when the abnormality is resolved, and the gas sensor is An object of the present invention is to provide a gas sensor control device and a gas sensor control method capable of preventing the gas sensor from being damaged due to energization when the wiring is abnormal.

In order to solve the above problems, a gas sensor control device of the present invention includes a gas sensor having at least one cell including a solid electrolyte body and a pair of electrodes provided on the solid electrolyte body, and a heater for heating the solid electrolyte body. A sensor drive circuit connected to the gas sensor and energizing the cell to drive the gas sensor, a heater control circuit for controlling the heater, and a wiring abnormality detection for detecting a wiring abnormality of the sensor drive circuit or the gas sensor And when the wiring abnormality detecting means detects the wiring abnormality, the heater control circuit is driven to drive the heater at an intermediate voltage that is lower than the maximum voltage of the heater and equal to or higher than a voltage capable of maintaining the activation temperature of the cell. If the occurrence of the wiring abnormality exceeds a predetermined frequency, the abnormality is confirmed and the sensor drive circuit is driven. And and a control means for the gas sensor in a non-energized.
With such a configuration, if an abnormality is temporarily detected, but the abnormality cannot be confirmed, the heater is appropriately heated with an intermediate voltage. Can return to operation. Therefore, even if the wiring abnormality is solved and the gas sensor is to be operated normally, it is possible to prevent the gas sensor from being too cold and taking a long time to start.
On the other hand, since the gas sensor is de-energized after the abnormality is confirmed, the gas sensor is prevented from being damaged due to energization when the wiring is abnormal. In addition, if the heater is appropriately heated at an intermediate voltage even after the abnormality is confirmed, the gas sensor is prevented from being heated too much, and the gas sensor continues to be heated appropriately. Therefore, the gas sensor is poisoned by carbon in the measurement gas. Can be prevented.

After the abnormality is determined, the control means may further drive the heater control circuit to deenergize the heater.
With such a configuration, since the heater is de-energized after the abnormality is confirmed, the heater is continued to be heated even after the abnormality is confirmed, thereby preventing the gas sensor from being excessively heated.

In the gas sensor control device of the present invention, information indicating that the abnormality has been determined by the control means is stored, and storage means for storing the information even after the gas sensor control device is stopped, and the control means determines the abnormality. In this case, the information processing apparatus may further include notification means for determining presence / absence of notification based on the information held in the storage means.
With such a configuration, it is possible to notify the operator (automobile driver or the like) that the gas sensor is abnormal in accordance with the abnormality confirmation information, and to prompt a response. Normally, when the gas sensor control device is temporarily stopped and then restarted, the abnormality is serious when the abnormality has been repeatedly confirmed despite the fact that the abnormality previously confirmed may be resolved. This is because there are many cases.

  The gas sensor control method of the present invention includes a gas sensor having at least one cell including a solid electrolyte body and a pair of electrodes provided on the solid electrolyte body, a heater for heating the solid electrolyte body, and the gas sensor. A control method of a gas sensor control device comprising a sensor drive circuit for energizing the cell to drive the gas sensor, the wiring abnormality detection process for detecting a wiring abnormality of the sensor drive circuit or the gas sensor, and the wiring When an abnormality is detected, a heater energization control process in which the heater is energized with an intermediate voltage that is less than the maximum voltage of the heater and that can maintain the activation temperature of the cell, and the occurrence of the wiring abnormality exceeds a predetermined frequency. If the gas sensor is not energized, the abnormality is confirmed and the sensor driving circuit is driven to deenergize the gas sensor. Having, and

In the gas sensor de-energization process, the heater may be de-energized after the abnormality is determined.

In the gas sensor control method of the present invention, when information indicating that the abnormality has been determined is stored and the information is retained even after the gas sensor control device is stopped, and the abnormality is determined in the gas sensor de-energization process Furthermore, you may have further the alerting | reporting process which determines the presence or absence of alerting | reporting based on the said information.

  According to the present invention, when a wiring abnormality is temporarily detected but the abnormality is not fixed, the gas sensor can be quickly returned to normal when the abnormality is resolved, and after the abnormality is confirmed, the gas sensor is turned off. It is possible to prevent the gas sensor from being damaged due to energization when the wiring is abnormal by de-energizing.

It is a schematic block diagram of an internal combustion engine control system provided with an electronic control unit. It is a circuit diagram which shows schematic structure of an electronic control unit. It is explanatory drawing showing the state of each switch with respect to each energized state (operation mode). It is a figure which shows the flowchart of a heater energization control process (an abnormality determination process is included).

Hereinafter, embodiments of the present invention will be described.
FIG. 1 is a schematic diagram showing a configuration of a gas sensor control device 1 (internal combustion engine control system) according to an embodiment of the present invention, including an electronic control unit (ECU) 5. The gas sensor control device 1 executes various control processes for controlling the operating state of the internal combustion engine (engine), and detects the concentration of a specific gas (oxygen or the like) contained in the gas to be measured (exhaust gas). Is running.
The gas sensor control device 1 includes an electronic control unit 5 and a gas sensor 8, and the gas sensor 8 is attached to an exhaust pipe of an engine. The electronic control unit 5 includes a sensor control circuit 2 that controls the gas sensor 8 (sensor element 10), an engine control device 9 (hereinafter also referred to as “engine CPU” 9), and a heater control circuit 60 that controls the heater 43. The control circuit 2 includes a sensor drive circuit 52. The engine control device 9 is connected to the heater control circuit 60 and controls the heater control circuit 60 so that the temperature of the sensor element 10 becomes an operating temperature (hereinafter also referred to as an activation temperature, for example, 550 to 900 ° C.). The engine control device 9 is connected to the sensor control circuit 2 via the transmission cable 71 and controls the sensor control circuit 2.

  The gas sensor 8 includes a sensor element 10 that detects an oxygen concentration in a gas to be measured (exhaust gas) over a wide area, and a heater 43 that keeps the sensor element 10 at an operating temperature, and operates as a so-called full-range air-fuel ratio sensor. . The sensor element 10 includes an oxygen pump cell 14, a porous diffusion layer 18, an oxygen concentration detection cell 24, and a reinforcing plate 30. The detailed configuration of the gas sensor 8 will be described later.

The sensor control circuit 2 includes a sensor drive circuit 52 and the like that are electrically connected to the gas sensor 8. The sensor drive circuit 52 energizes the gas sensor 8 (the oxygen pump cell 14 and the oxygen concentration detection cell 24) to perform drive control thereof, and detects an output (gas detection signal) and an element resistance value signal of the oxygen pump cell 14. The sensor control circuit 2 outputs the detected gas detection signal and element resistance value signal to the engine control device 9.
The sensor control circuit 2 can be realized as an ASIC (Application Specific Integrated Circuit), for example. The gas detection signal changes according to the oxygen concentration in the gas to be measured, and is used for measuring the oxygen concentration. On the other hand, the element resistance value signal indicates the electric resistance value of the gas sensor 8 and changes according to the temperature of the gas sensor 8. However, the detection of the element resistance value signal and the calculation of the temperature of the gas sensor 8 should be performed using a known method. Therefore, details are omitted.

  The sensor control circuit 2 (sensor drive circuit 52) includes a Vs + terminal, a COM terminal, and an Ip + terminal. These terminals are the first connection terminal 15, the second connection terminal 17, and the third connection terminal of the electronic control unit 5, respectively. 19 are electrically connected to each other. A second detection electrode 28 of the sensor element 10 to be described later is electrically connected to the Vs + terminal of the sensor control circuit 2 through the first connection terminal 15 and the wiring 61. Further, the first detection electrode 22 and the second pump electrode 16 of the sensor element 10 are electrically connected to the COM terminal of the sensor control circuit 2 through the second connection terminal 17 and the wiring 62. Similarly, the first pump electrode 12 of the sensor element 10 is electrically connected to the Ip + terminal of the sensor control circuit 2 via the third connection terminal 19 and the wiring 63. In this way, the sensor drive circuit 52 is electrically connected to the gas sensor 8 to detect a gas detection signal or an element resistance value signal.

  The control unit 55 can be configured by a logic circuit that executes various control processes in the sensor control circuit 2.

The heater control circuit 60 includes a transistor Tr, the collector of the transistor Tr is connected to one end of the heater 43, the emitter is grounded via a resistor Rh, and the base is connected to the engine control device 9. For this reason, while the engine control device 9 outputs a voltage level signal (heater ON signal (corresponding to a command)) for turning on the transistor Tr to the base of the transistor Tr, a voltage is supplied from the battery VB and the heater 43 is supplied. Current flows through the heating resistor 72 and the heater 43 generates heat. On the other hand, when the engine control device 9 stops outputting the heater on signal, the transistor Tr is turned off, no current flows through the heating resistor 72, and heating of the heater 43 is stopped.
In this embodiment, when the heater 43 is applied at the maximum effective voltage (= the power supply voltage of the battery VB, 12 V in the present embodiment), the energization rate (duty) is 100%, and a voltage equal to or lower than the maximum effective voltage is applied. The applied voltage to the heater 43 is controlled by changing the energization rate at that time between 0% and less than 100%. This control is performed when the engine control device 9 outputs the heater-on signal determined by the energization rate to the heater control circuit 60, and the heater control circuit 60 turns on / off according to the heater-on signal. That is, in the present embodiment, the energization to the heater 43 is PWM controlled.
However, the energization control to the heater 43 may be performed by a constant voltage source instead of the PWM control.

The engine control device 9 includes a CPU as a central processing unit, storage units (RAM and ROM) for storing data, programs, and the like, and an input port and an output port for inputting and outputting signals between external devices, It can comprise with a microcomputer provided with. In the engine control device 9, the CPU executes various arithmetic processes based on a program stored in the storage unit, and controls the execution of instructions such as arithmetic and data transfer. Further, the engine control device 9 reflects the signal input to the input port in the contents of the input port register, and outputs the content stored in the output port register as a signal to the output port.
Of the storage unit of the engine control device 9, an EEPROM (writeable / erasable non-volatile memory) 9m stores abnormality determination information to be described later, and this information is held in the EEPROM 9m even after the gas sensor control device 1 is stopped. Is done.
The EEPROM 9m corresponds to “storage means” in the claims.

  Then, the engine control device 9 determines the energization state (energization direction, integrated current value, etc.) of the Ip current flowing in the oxygen pump cell 14 to be described later based on the gas detection signal Vip output from the sensor control circuit 2, and Ip The oxygen concentration is calculated based on the current application state. The engine control device 9 controls the operating state of the internal combustion engine by executing engine combustion control using the oxygen concentration obtained by the calculation.

Further, the engine control device 9 outputs a command (hereinafter referred to as “switching command” as appropriate) to switch the energization state to be described later to the sensor control circuit 2 to drive the sensor control circuit 2, and responds to wiring abnormality. A heater energization control process for driving the heater control circuit 60 by outputting an energization command for the heater 43 to the heater control circuit 60 and a non-energization process for the gas sensor 8 which is one of the switching commands are also executed.
The engine control device 9 corresponds to “control means” and “and notification means” in the claims.

Next, the configuration of the gas sensor 8 will be described.
The oxygen pump cell 14 includes an oxygen ion conductive solid electrolyte body 13 formed in a plate shape with partially stabilized zirconia (ZrO ₂ ), a first pump electrode 12 mainly formed of platinum on each of the front and back surfaces, Two pump electrodes 16 are provided. The first pump electrode 12 is electrically connected to the third connection terminal 19 of the electronic control unit 5 through the wiring 63, and the second pump electrode 16 is connected to the second pump of the electronic control unit 5 through the wiring 62. It is electrically connected to the connection terminal 17. The first pump electrode 12 is covered with a porous protective layer 29 and is protected from poisonous substances by the porous protective layer 29.
The oxygen concentration detection cell 24 includes an oxygen ion conductive solid electrolyte body 23 formed in a plate shape by partially stabilized zirconia (ZrO ₂ ), and a first detection electrode 22 mainly formed of platinum on the front and back surfaces thereof. The second detection electrode 28 is provided. The first detection electrode 22 is electrically connected to the second connection terminal 17 of the electronic control unit 5 via the wiring 62 and is also electrically connected to the second pump electrode 16. The second detection electrode 28 is electrically connected to the first connection terminal 15 of the electronic control unit 5 via the wiring 61.

Between the oxygen pump cell 14 and the oxygen concentration detection cell 24, an insulating layer (not shown) mainly composed of an insulating material (such as alumina) is interposed between the cells 14 and 24, A porous diffusion layer 18 is provided in a part of the insulating layer. The porous diffusion layer 18 is formed in a porous shape mainly composed of an insulating material (such as alumina) in order to control the diffusion of the gas to be measured introduced into the sensor element 10. Instead of the porous diffusion layer 18, a small hole may be provided as a diffusion-controlling portion on the side wall of the insulating layer.
A hollow measurement chamber 20 surrounded by the porous diffusion layer 18 and the insulating layer (not shown) is formed between the oxygen pump cell 14 and the oxygen concentration detection cell 24. The measurement chamber 20 is communicated with the measurement gas atmosphere via the porous diffusion layer 18 (specifically, the porous portion). Further, the second pump electrode 16 is exposed on the upper surface of the measurement chamber 20, and the first detection electrode 22 is exposed on the lower surface of the measurement chamber 20.

In addition, a reinforcing plate 30 is laminated on the surface opposite to the surface facing the measurement chamber 20 in the oxygen concentration detection cell 24 to improve the overall strength of the sensor element 10. The reinforcing plate 30 is substantially the same size as the solid electrolyte bodies 13 and 23, and is formed in a plate shape with a material mainly made of ceramic.
The second detection electrode 28 is sandwiched between the reinforcing plate 30 and the oxygen ion conductive solid electrolyte body 23 and is cut off from the outside, and a reference oxygen chamber 26 as a sealed space around the second detection electrode 28. Is formed. Accordingly, a small constant current Icp is applied in the direction from the second detection electrode 28 to the first detection electrode 22, and oxygen is pumped from the measurement chamber 20 to the second detection electrode 28 side, thereby causing the reference oxygen chamber 26 to enter. A substantially constant concentration of oxygen is accumulated. In this way, the oxygen in the reference oxygen chamber 26 becomes the reference oxygen concentration when detecting the oxygen concentration.

  On the other hand, a flat heater 43 is disposed so as to face the oxygen pump cell 14 of the sensor element 10. The heater 43 is formed of a material mainly composed of alumina, and has a heater wiring 72 formed of a material mainly composed of platinum therein. The heater 43 is controlled so that the temperature of the sensor element 10 becomes an activation temperature (830 ° C. in this embodiment) by electric power supplied from a heater control circuit 60 described later. Further, both ends of the heater wiring 72 are electrically connected to the heater control circuit 60. The sensor element 10 (the oxygen pump cell 14 and the oxygen concentration detection cell 24) is activated by the heating by the heater 43, and gas detection (oxygen detection) becomes possible.

Next, the operation of the gas sensor 8 (sensor element 10) will be described.
First, the gas to be measured (exhaust gas) diffuses into the measurement chamber 20 through the porous diffusion layer 18. At this time, in a state where the air-fuel mixture supplied to the engine (that is, the gas to be measured in the measurement chamber 20) is maintained at the stoichiometric air-fuel ratio, the measurement chamber 20 and the reference oxygen chamber 26 serving as a reference for the oxygen concentration Due to the difference in oxygen concentration, an electromotive force of 450 [mV] is generated in the oxygen concentration detection cell 24 (a potential difference of 450 [mV] is generated between the first detection electrode 22 and the second detection electrode 28).
By the way, according to the change of the air-fuel ratio of the air-fuel mixture supplied to the engine, the oxygen concentration contained in the exhaust gas changes, and the oxygen concentration in the measurement gas contained in the measurement chamber 20 also changes. Therefore, in the internal combustion engine control system 1 of the present embodiment, the sensor control circuit 2 causes the oxygen pump cell 14 to maintain the potential difference between the first detection electrode 22 and the second detection electrode 28 at 450 [mV]. The flowing Ip current is controlled. That is, oxygen pumping is performed by the oxygen pump cell 14 by controlling the Ip current so that the atmosphere in the measurement chamber 20 is in the same state as the stoichiometric air-fuel ratio.

  The oxygen pump cell 14 pumps out oxygen from the measurement chamber 20 or supplies it to the measurement chamber 20 depending on the direction of current flowing between the pair of electrodes (the first pump electrode 12 and the second pump electrode 16). The pumping of oxygen can be switched. The oxygen pump cell 14 is configured to be capable of adjusting the oxygen pumping amount in accordance with the magnitude of the Ip current passed between the pair of electrodes. For this reason, the oxygen concentration in the gas to be measured can be calculated based on the energization state (energization direction, current integrated value, etc.) of the Ip current.

  Next, the configuration and operation of the electronic control unit 5 will be described with reference to FIG. FIG. 2 is a circuit diagram showing a schematic configuration of the electronic control unit 5. As described above, the electronic control unit 5 includes the sensor control circuit 2, the heater control circuit 60, and the engine control device 9.

  The sensor control circuit 2 includes a sensor drive circuit 52, a terminal voltage output circuit 54, a control unit 55, a differential amplifier circuit 57, and an abnormality detection circuit 58.

The sensor drive circuit 52 includes an operational amplifier 32 for flowing an Ip current for driving the oxygen pump cell 14, a PID control circuit 56 for improving the control characteristic of the Ip current, and the periphery of the second detection electrode 28 (reference oxygen chamber 26). A constant current source 46 for supplying a constant current Icp to the oxygen concentration detection cell 24 so as to keep the oxygen concentration constant, and a constant voltage source 48 for supplying a control target voltage for the Ip current are provided.
The sensor drive circuit 52 is connected to the sensor element 10 (Vs + terminal, COM terminal, Ip + terminal) and terminals for externally determining elements that determine the characteristics of the PID control circuit 56 (P1 terminal, P2 terminal, Pout). Terminal) and switches SW1 to SW5 for changing the energization state (operation mode) of the sensor drive circuit 52 in accordance with the energization state switching command output from the engine control device 9. The operation mode of the sensor drive circuit 52 represents the energization state to the sensor element 10.

Further, the sensor driving circuit 52 includes a Vcent point connected to the COM terminal 17, and an output terminal (described later) of the PID control circuit 56, an inverting input terminal of the operational amplifier 32, and an output terminal of the operational amplifier 34 are connected to the Vcent point. Yes. The output terminal of the operational amplifier 34 is connected to the Vcent point via the switch SW1. Further, the inverting input terminal of the operational amplifier 34 is connected to the output terminal, and the reference voltage 3.6 V is applied to the non-inverting input terminal of the operational amplifier 34. That is, the operational amplifier 34 is a circuit that applies a reference voltage of 3.6 V to the Vcent point and supplies an abnormality diagnosis current for performing an abnormality diagnosis of the sensor element 10.
The second pump electrode 16 is connected to the Vcent point via the wiring 62, the second connection terminal 17, and the resistance element R1.

The voltage dividing circuit 65 and the output terminal of the operational amplifier 32 are connected to the Ip + terminal. The voltage dividing circuit 65 includes two resistance elements R7 and R8 that divide the constant power supply voltage, and the connection point of the resistance elements R7 and R8 is connected to the Ip + terminal via the switch SW4. The output terminal of the operational amplifier 32 is connected to the Ip + terminal via the switch SW3. One end of the resistance element R8 is grounded.
A PID control circuit 56 is connected to the inverting input terminal of the operational amplifier 32 via the Vcent point and the resistance element R2, and a reference voltage of 3.6 V is applied to the non-inverting input terminal of the operational amplifier 32. That is, the operational amplifier 32 constitutes a part of a negative feedback circuit that controls a current flowing to the sensor element 10 (specifically, the oxygen concentration detection cell 24).

The PID control circuit 56 performs a PID operation on a deviation amount ΔVs between the control target voltage 450 mV of the oxygen concentration detection cell 24 and the output voltage Vs of the oxygen concentration detection cell 24 to improve the control characteristics of the negative feedback control described above. It has a function. The PID control circuit 56 includes operational amplifiers 36 and 40, resistors R3 to R5, and capacitors C1 to C3.
The input terminal of the PID control circuit 56 (the inverting input terminal of the operational amplifier 40) is connected to the output terminal of the operational amplifier 42, and the non-inverting input terminal of the operational amplifier 42 is connected to the Vs + terminal. That is, the output voltage Vs of the oxygen concentration detection cell 24 is input to the PID control circuit 56 via the operational amplifier 42. Note that the inverting input terminal of the operational amplifier 42 is connected to the output terminal.
A constant current source 46 is connected to the Vs + terminal via the switch SW5. The constant current source 46 is a constant current Icp (for example, 17 μA) that is passed through the oxygen concentration detection cell 24 in order to keep the oxygen concentration around the second detection electrode 28 (reference oxygen chamber 26) of the oxygen concentration detection cell 24 constant. ).

The output terminal of the operational amplifier 38 is connected to the inverting input terminal of the operational amplifier 40 through a resistance element. A constant voltage source 48 is connected to the non-inverting input terminal of the operational amplifier 38, and the inverting input terminal of the operational amplifier 38 is connected to the output terminal. That is, the output of the constant voltage source 48 is input to the inverting input terminal of the operational amplifier 40 via the operational amplifier 38, and 450 mV, which is a control target for controlling the Ip current, is supplied to the PID control circuit 56 via the operational amplifier 40. Is done.
The output terminal of the operational amplifier 40 is connected to the P1 terminal, and the non-inverting input terminal of the operational amplifier 40 is connected to the Vcent point. Further, a resistance element is interposed between the output terminal and the inverting input terminal of the operational amplifier 40. The P1 terminal is connected in parallel to the resistor R5 side of the first series circuit of the resistor R5, the capacitor C3, and the capacitor C2, and the R4 side of the second series circuit of the resistors R4 and R3. The connection point between the capacitor C3 and the capacitor C2 of the first series circuit is connected to the P2 terminal. Similarly, the connection point between the resistors R4 and R3 of the second series circuit is also connected to the P2 terminal. Further, the capacitor C2 and the resistor R3 are connected to the capacitor C1, and the capacitor C1 is connected to the Pout terminal.

The P2 terminal is connected to the inverting input terminal of the operational amplifier 36, and the output terminal of the PID control circuit 56 (the output terminal of the operational amplifier 36) is connected to the Pout terminal via the switch SW2. On the other hand, a reference voltage of 3.6 V is applied to the non-inverting input terminal of the operational amplifier 36.
The Pout terminal is connected to the Vcent point via the resistance element R2, and the output terminal (capacitor C1) of the PID control circuit 56 is connected to the COM terminal via the resistance element R2 and the resistance element R1.
Resistors R3 to R5 and capacitors C1 to C3 are provided to determine the control characteristics of the PID control circuit 56 attached to the P1 terminal and the P2 terminal.
Further, an oscillation preventing circuit 59 composed of a series circuit of a resistor R6 and a capacitor C4 is inserted between the Vs + terminal and the Ip + terminal in order to prevent oscillation of the sensor drive circuit 52.

Next, other circuits 54, 57, and 58 included in the sensor control circuit 2 will be described.
The terminal voltage output circuit 54 outputs the terminal voltages of the Vs + terminal, the COM terminal, and the Ip + terminal to the engine control device 9 via the control unit 55. Although connection lines are omitted in the figure, the input terminals of the terminal voltage output circuit 54 are connected to the Vs + terminal, the COM terminal, and the Ip + terminal, respectively.
The differential amplifier circuit 57 outputs the voltage across the resistor element R2 (specifically, the voltage across the Vcent point and the Pout point) to the input port of the engine control device 9 as a gas detection signal. This voltage is obtained by converting the Ip current flowing through the oxygen pump cell 14 by the resistance element R2. Note that the gas detection signal may be output to the input port of the engine control device 9 via the transmission cable 71.

Next, the abnormality detection circuit 58 includes window comparators 58a, 58b and 58c and an OR circuit 58d, and the output terminals of the comparators 58a, 58b and 58c are connected in parallel to the input terminal of the OR circuit 58d. Although the connection lines are omitted in the figure, the input terminals of the comparators are connected to the Vs + terminal, the COM terminal, and the Ip + terminal, respectively.
Each of the window comparators 58a, 58b, and 58c outputs a low level signal when each terminal voltage of the Vs + terminal, the COM terminal, and the Ip + terminal is within a predetermined voltage range, and each terminal voltage is out of the predetermined voltage range. Is configured to output a high level signal.

The terminal voltage of the Vs + terminal is normally maintained at 4.05 V, which is a value obtained by adding the output voltage Vs (450 mV) of the oxygen concentration detection cell 24 to the reference voltage 3.6 V of the COM terminal. However, when the wiring 61 or the like (also referred to as a Vs + line) connected to the Vs + terminal is short-circuited to the power supply potential or the ground potential for some reason, the terminal voltage of the Vs + terminal becomes the power supply potential or the ground potential. Then, an excessive abnormal current flows through the sensor element 10 and the sensor element 10 may be damaged. Therefore, the window comparator 58a is configured to compare the terminal voltage of the Vs + terminal with a preset threshold value and output a high level signal when the terminal voltage of the Vs + terminal exceeds the threshold value.
Specifically, the upper limit of the threshold value of the window comparator 58a is set to 9V or a predetermined voltage value obtained by subtracting a predetermined value (for example, 1.5V) from the power supply voltage in consideration of the fluctuation of the power supply voltage of the sensor element control circuit 50. In addition to setting, the lower limit of the threshold is set to 1 V taking ground floating into 0 V of the ground level. When the terminal voltage at the Vs + terminal rises above the upper limit value of 9V or a predetermined voltage value, or when the terminal voltage at the Vs + terminal falls below the lower limit value of 1V, the window comparator 58a It is configured to output a signal.

  The terminal voltage of the COM terminal is normally controlled by the operational amplifier 32 so that the reference voltage is 3.6V. However, when the wiring 62 or the like (also referred to as a COM line) connected to the COM terminal is short-circuited to the power supply voltage or the ground level for some reason, the terminal voltage of the COM terminal becomes the power supply potential or the ground potential, like the Vs + terminal. Therefore, the window comparator 58b is configured to compare the terminal voltage of the COM terminal with a preset threshold value and output a high level signal when the terminal voltage of the COM terminal exceeds the threshold value. Specifically, similarly to the window comparator 58a, the upper limit of the threshold of the window comparator 58b is set to 9V or a predetermined voltage value, and the lower limit of the threshold is set to 1V. When the terminal voltage of the COM terminal rises above the upper limit value of 9V, or when the potential of the COM terminal falls below the lower limit value of 1V, the window comparator 58b outputs a high level signal. It is configured.

  Also in the Ip + terminal, when the wiring 63 or the like (also referred to as an Ip + line) connected to the Ip + terminal is short-circuited to the power supply voltage or the ground level for some reason, the terminal voltage of the Ip + terminal becomes the power supply potential or the ground potential. Therefore, the window comparator 58c is configured to compare the terminal voltage of the Ip + terminal with a preset threshold value and output a high level signal when the terminal voltage of the Ip + terminal exceeds the threshold value. Specifically, in the window comparator 58c to which the terminal voltage of the Ip + terminal is input, the upper limit of the threshold is set to 9V or a predetermined voltage value so as to sandwich the reference voltage 3.6V, similarly to the window comparator 58b. The lower limit of the threshold is set to 1V. When the terminal voltage at the Ip + terminal rises above the upper limit value of 9V or a predetermined voltage value, or when the terminal voltage at the Ip + terminal falls below the lower limit value of 1V, the window comparator 58c It is configured to output a signal.

The OR circuit 58d calculates a logical sum of signals from the window comparators 58a, 58b, and 58c, and sets an abnormality detection flag DIAG when a high level signal is input from any of the window comparators 58a, 58b, and 58c. DIAG = 1 and output to the engine control device 9 and the control unit 55. When the terminal voltages of the Vs + terminal, the COM terminal, and the Ip + terminal are within a predetermined voltage range, the abnormality detection circuit 58 sets the abnormality detection flag DIAG to DIAG = 0 and outputs it to the engine control device 9 and the control unit 55. To do. As described above, the abnormality detection circuit 58 has a short circuit abnormality in any of the Vs + line, the COM line, and the Ip + line, and the terminal voltage of the Vs + terminal, the COM terminal, and the Ip + terminal exceeds the predetermined threshold value described above. When the voltage value is reached (in other words, when an abnormality occurs in the sensor element 10), the abnormality detection flag DIAG has a function of setting DIAG = 1.
The abnormality detection circuit 58 corresponds to “wiring abnormality detection means” in the claims.

The sensor drive circuit 52 configured as described above switches ON / OFF of each of the switches SW1 to SW5 in response to a command from the engine control device 9, and changes the energized state (operation mode) of the sensor drive circuit 52 itself to measure the gas concentration. Current energization state (hereinafter referred to as “A mode” as appropriate), sensor protection energization state (hereinafter referred to as “P mode” as appropriate), and pre-activation energization state (hereinafter referred to as “NA mode” as appropriate). Each energized state will be described later.
The engine control device 9 outputs a command for switching the energization state of the sensor drive circuit 52 (specifically, a control signal for performing ON / OFF control of the switches SW1 to SW5) from the output port, and the transmission cable 71 Command to the sensor control circuit 2 (the control unit 55). Then, the control unit 55 switches (sets) the energization state of the sensor drive circuit 52.

Further, the gas detection signal indicating the voltage across the resistance element R <b> 2 is directly input to the input port of the engine control device 9 via the differential amplifier circuit 57. Further, the abnormality detection flag DIAG from the abnormality detection circuit 58 is directly input to the input port of the engine control device 9 and is also input to the control unit 55. On the other hand, an output signal from the terminal voltage output circuit 54 is input to the control unit 55 and input to the input port of the engine control device 9 via the transmission cable 71. An element resistance value signal indicating the electrical resistance value and temperature of the sensor element 10 is also input to the control unit 55 and input to the input port of the engine control device 9 via the transmission cable 71.
As described above, the engine control device 9 can control the energization state of the sensor drive circuit 52, and can determine whether the sensor element 10 is abnormal based on the input signals from the abnormality detection circuit 58 and the terminal voltage output circuit 54. Can be detected. Specifically, the engine control device 9 identifies which terminal among the predetermined identification conditions the state of each input terminal voltage applies to, and the terminal where the abnormality has occurred and its abnormality content (power supply Short circuit (VB short circuit), ground short circuit (ground short circuit, etc.) can be detected.

  Next, referring to FIG. 3, the energization state (operation mode) of the sensor drive circuit 52 when the switches SW1 to SW5 are switched ON / OFF will be described.

Here, the energization state for sensor protection is a state in which the electrical connection between the sensor element 10 and the sensor drive circuit 52 is cut off to protect the gas sensor 8 from current flow.
Further, in the energized state for gas concentration measurement, the value and direction of the current flowing through the oxygen pump cell 14 are controlled so that the voltage between both electrodes of the oxygen concentration detection cell 24 becomes a desired value so that the gas concentration can be measured. It is a state to make.
The pre-activation energization state is a state in which a minute current is applied to both electrodes of at least one of the oxygen concentration detection cell 24 and the oxygen pump cell 14 so that an overvoltage is not applied to the gas sensor 8 (the two cells 14, 24). It is. As a more specific pre-activation energized state, in the case of a gas sensor having a configuration in which the electrode 28 on the side not facing the measurement chamber is closed to the outside of the pair of electrodes provided in the oxygen concentration detection cell 24, In order to use 28 as an internal oxygen reference source, an energized state in which a minute current is supplied to the oxygen concentration detection cell 24 can be exemplified.

  First, in the gas concentration measurement energization state, the switches SW2, SW3, and SW5 of the sensor drive circuit 52 are turned on, and the switches SW1 and SW4 are turned off. The gas concentration measurement energization state is an operation mode in which a relatively large current can be supplied to the gas sensor 8 (specifically, the oxygen pump cell 14) for oxygen pumping or the like. At this time, the maximum current value that can be supplied to the oxygen pump cell 14 is determined by the current drive capability of the outputs of the operational amplifier 32 and the PID control circuit 56, and is set to about 20 [mA] in this embodiment.

For example, when the gas to be measured becomes excessively rich (rich) in the fuel supply, the oxygen concentration in the measurement chamber 20 is deficient than the theoretical air-fuel ratio, and the output voltage Vs of the oxygen concentration detection cell 24 is the control target voltage. It becomes higher than 450 mV. Therefore, a deviation amount ΔVs between the control target voltage and the output voltage Vs is generated, and the deviation amount ΔVs is PID-calculated by the PID control circuit 56 and fed back by the operational amplifier 32. For this reason, an Ip current for pumping the insufficient oxygen into the measurement chamber 20 by the oxygen pump cell 14 flows into the oxygen pump cell 14.
On the other hand, when the gas to be measured becomes insufficient in fuel supply (lean), the oxygen concentration in the measurement chamber 20 becomes excessive than the theoretical air-fuel ratio, and the output voltage Vs of the oxygen concentration detection cell 24 is lower than the control target voltage 450 mV. Therefore, the deviation amount ΔVs is fed back by the operational amplifier 32 in the same manner as described above, and an Ip current for pumping excess oxygen from the measurement chamber 20 by the oxygen pump cell 14 flows to the oxygen pump cell 14.
In this way, the oxygen concentration in the gas to be measured can be calculated based on the energization state (energization direction, current integrated value, etc.) of the Ip current.

Next, in the sensor protection energization state, all the switches SW1 to SW5 of the sensor drive circuit 52 are turned off. For this reason, the signals input to the sensor element 10 from the operational amplifiers 32, 34, and 36 and the constant current source 46 are turned OFF, and the energization from the sensor drive circuit 52 to the sensor element 10 is interrupted.
Accordingly, when a wiring abnormality occurs and the abnormality detection flag DIAG (= 1) is output from the OR circuit 58d, the engine control device 9 outputs a switching command to the control unit 55, and based on this command, the control unit 55 However, by setting the sensor drive circuit 52 to the energized state for sensor protection, it is possible to prevent the abnormal current from continuously flowing through the sensor element 10 and to protect the sensor element 10.

In the energization state before activation, the switches SW1, SW4, and SW5 of the sensor drive circuit 52 are turned on, and the switches SW2 and SW3 are turned off. At this time, since the switch SW3 is OFF, no current is supplied from the operational amplifier 32 driving the oxygen pump cell 14, and since the switch SW2 is OFF, current is also supplied from the output of the PID control circuit 56. Therefore, the current control for the oxygen pump cell 14 is stopped. Therefore, the negative feedback control of the oxygen pump cell 14 is not performed in the pre-activation energized state.
Further, since the switches SW1, SW4, and SW5 are ON, the oxygen pump cell 14 and the oxygen concentration detection cell 24 are supplied with a small constant current Icp from the operational amplifier 34, the constant current source 46, and the voltage dividing circuit 65. Become. Thus, oxygen is pumped from the first detection electrode 22 to the second detection electrode 28 side, and oxygen having a substantially constant concentration is accumulated in the reference oxygen chamber 26 formed around the second detection electrode 28.

In this way, in the energized state before activation, only a very small current is supplied to the sensor element 10, and therefore an excessive current is not supplied even when a wiring abnormality occurs. Damage (blackening, etc.) is less likely to occur.
Further, as described above, the engine control device 9 detects the wiring abnormality based on the state of each input terminal voltage. However, since each terminal voltage is low in the pre-activation energization mode, the sensor element 10 is damaged. Therefore, it is possible to detect a wiring abnormality.

  For example, when the gas concentration measurement energization state is set in a wiring abnormality state in which the wiring 62 is shorted to ground (ground short), an energization path from the operational amplifier 32 to the ground line via the oxygen pump cell 14 and the wiring 62 is formed. At the same time, the maximum current driving capability of the operational amplifier 32 is supplied from the operational amplifier 32 to the oxygen pump cell 14. In this case, an excessive current is supplied to the oxygen pump cell 14, and the sensor element 10 is damaged (blackening or the like) in an instant. On the other hand, if the wiring 62 is short-circuited to the ground and is in an energized state before activation, an energization path from the voltage dividing circuit 65 to the ground line via the oxygen pump cell 14 and the wiring 62 is formed. The current supplied from the pressure circuit 65 to the oxygen pump cell 14 is very small. For this reason, an excessive current is not supplied to the oxygen pump cell 14, and the sensor element 10 can be prevented from being damaged (blackening or the like).

Next, the contents of the heater energization control process executed by the engine control device 9 and the gas sensor de-energization process, which are the features of the present invention, will be described.
In the present invention, when a wiring abnormality is detected (hereinafter referred to as “provisional abnormality”), the heater 43 is energized with a voltage lower than the maximum voltage. As a result, when the gas sensor 1 is stopped (engine switch off operation) due to a wiring abnormality and then the gas sensor 1 is restarted (hot restart), the heater 43 is heated at the maximum voltage as in the conventional case. Continuously, the gas sensor 1 is prevented from being heated too much. On the other hand, even if the wiring is normal, it may be erroneously detected as abnormal, or the wiring abnormality may be resolved immediately.If the heater voltage is turned off immediately due to a temporary abnormality, the wiring abnormality is resolved and the gas sensor is turned off. Even if it is attempted to return (activate) normally, it takes time until the gas sensor 1 is activated because it is too cold.
Therefore, in the present invention, when it is determined as a temporary abnormality, the heater 43 is heated by energizing the heater 43 with an intermediate voltage between the maximum voltage and a voltage capable of maintaining the activation temperature of the cells 14 and 24. This prevents the gas sensor 1 from getting too cold.

In the present invention, when a temporary abnormality occurs over a predetermined frequency, the abnormality is determined and the gas sensor 1 is deenergized (set to P mode). Accordingly, the heater 43 is appropriately heated at an intermediate voltage while the gas sensor 1 is de-energized after the abnormality is confirmed, so that the temperature of the gas sensor 1 is prevented from being excessively raised and the gas sensor 1 is continuously heated. The poisoning of the gas sensor 1 due to carbon or the like in the gas can be prevented.
Furthermore, in the present invention, since whether or not the provisional abnormality exceeds a predetermined frequency is used as a criterion for determining abnormality, for example, it is only necessary to detect the number of occurrences of provisional abnormality within a predetermined time. It will be easy.

  In the present invention, the heater 43 may be further de-energized when the abnormality is determined. In this way, the heater 43 is continuously heated after the abnormality is confirmed, and the gas sensor 1 is reliably prevented from being heated too much. Note that whether to continue heating the heater 43 at an intermediate voltage even after the abnormality is determined or to turn off the heater 43 can be determined as follows according to the type and application of the gas sensor. For example, under the condition that a poisoning substance (carbon or the like) in the measurement gas causes a problem, the heater 43 may be continuously heated at an intermediate voltage even after the abnormality is determined. Further, when the heater 43 is excessively heated when the gas sensor 1 is restarted after the abnormality is confirmed (for example, when the heater 43 is set to be heated immediately at the maximum voltage after the activation), the abnormality is confirmed. The heater 43 may be de-energized later.

  In the present embodiment, the sensor energization control process, which is the main routine, is performed by the engine control device 9, and the heater energization control process and the gas sensor de-energization process described above are called and executed as subroutines. Therefore, the sensor energization control process that is the main routine will be described first.

First, the engine control device 9 (and the control unit 55 of the sensor control circuit 2) is activated when the internal combustion engine control system 1 is turned on and executes initialization processing (initialization of internal variables, etc.). After the above is completed, the following various control processes are started.
As various control processes, a specific gas concentration detection process for detecting a specific gas concentration in the exhaust gas based on a gas detection signal from the sensor control circuit 2 or the like, and an energization state switching command to the sensor control circuit 2 are output. There are command output processing, air-fuel ratio control processing for performing air-fuel ratio control of the engine using a specific gas concentration (oxygen concentration) detected based on a gas detection signal, and the like.

Then, the engine control device 9 starts the process when the automobile is turned on, and executes the sensor energization control process for controlling the energization state of the sensor element 10 as one of various control processes after the initialization process is completed. To do. In the sensor energization control process, an optimum energization state is determined as an energization state to the sensor element 10 based on various conditions, and a process of outputting a switching command corresponding to the energization state of the determination result to the sensor control circuit 2 is executed. To do.
As an optimal energization state determination method, for example, under conditions such as immediately after sensor activation, the pre-activation energization state is determined as the optimal energization state, and under conditions where the sensor element 10 is activated, the gas concentration The measurement energization state is determined as the optimum energization state.
On the other hand, when a wiring abnormality (such as a wiring short-circuit) occurs, a heater energization control process and a gas sensor de-energization process described later are performed.
The engine control device 9 receives a current state flag indicating the current energization state from the sensor control circuit 2, and can know the current energization state based on the current state flag.

As a more specific determination method of the optimum energized state, it is determined whether or not the gas sensor 8 is activated based on the element resistance value signal of the gas sensor 8. Is determined as the optimum energized state, and if activated, the gas concentration measurement energized state is determined as the optimum energized state. If the abnormality detection circuit 58 determines that the gas sensor 8 or the energization path is abnormal (temporary abnormality), heater energization control processing and gas sensor de-energization processing described later are performed. When it is determined by the abnormality detection circuit 58 that the abnormality of the gas sensor 8 or the energization path has been eliminated, the optimum energization state is determined based on the element resistance value signal of the gas sensor 8.
The element resistance value signal is obtained by periodically supplying a current or voltage of a predetermined magnitude to one of the oxygen pump cell 14 and the oxygen concentration detection cell 24 constituting the gas sensor 8, and then obtained via the cell. Signal. Since the element resistance value signal can be obtained by a known method (circuit configuration), description in this embodiment is omitted. However, specifically, a current of a predetermined magnitude is periodically passed to the oxygen concentration detection cell 24, and the output obtained through the oxygen concentration detection cell 24 at that time is sample-held, and this sample-held output Is output to the engine control device 9 as an element resistance value signal.

Next, the heater energization control process (including the deenergization process of the gas sensor) in the gas sensor control apparatus 1 according to the embodiment of the present invention will be described with reference to FIG.
When the heater energization control process is activated when the vehicle is turned on, first, the engine control device 9 reads the abnormality confirmation information stored in the EEPROM 9m. The abnormality confirmation information includes the number n of abnormality confirmations, and the engine control device 9 determines whether n is 2 or less (step S10).
Here, the gas sensor control device 1 starts when the automobile is powered on and stops when the automobile is powered off. When an abnormality is determined between the start and stop of the gas sensor control device 1, the EEPROM 9m stores that the number of abnormality determinations is 1. In addition, the number of times of abnormality determination is 2 is that the abnormality is determined once during the period from the start to the stop of the gas sensor control device 1, and another time after the gas sensor control device 1 is started again after the stop until the next stop. This means that the abnormality has been confirmed. The abnormality confirmation information is held in the EEPROM 9m even after the gas sensor control device 1 is stopped.

  If n is 2 or less in step S10, the process proceeds to step S12, and the engine control device 9 determines whether or not a provisional abnormality has occurred. The temporary abnormality is output from the abnormality detection circuit 58 to the engine control device 9 as the abnormality detection flag DIAG = 1 as described above.

When a temporary abnormality occurs in step S12 (DIAG = 1), the process proceeds to step S14, and the engine control device 9 determines whether or not the temporary abnormality has occurred over a predetermined frequency. Here, the “predetermined frequency” is, for example, the number of times the abnormality detection flag DIAG = 1 indicating a temporary abnormality is detected within a predetermined time in step S12.
On the other hand, when a provisional abnormality is not detected in step S12 (DIAG = 0), the process proceeds to step S20, and the engine control device 9 performs a process of setting the energization state of the sensor drive circuit 52 to the PI control mode. Specifically, the engine control device 9 outputs an ON / OFF switching command for the switches SW1 to SW5 for setting the gas concentration measurement energization state (PI control mode) shown in FIG. . And the control part 55 switches the electricity supply state of the sensor drive circuit 52 to PI control mode.
Further, the engine control device 9 clears a temporary abnormality counter (for example, the number of detections of DIAG = 1) (step S28). Then, it returns to step S10 and it is determined again in step S12 whether provisional abnormality generate | occur | produces again.
In addition, after step S20, step S28 may be performed when the process of returning from step S20 to step S10 is repeated several times without immediately performing the process of step S28. This is to prevent the process of step S28 from being erroneously performed due to noise or the like. For example, the timer may be started after performing the process of step S20, and step S28 may be performed in the PI control mode after a predetermined time has elapsed.

When the provisional abnormality is less than or equal to the predetermined frequency in step S14, the process proceeds to step S18, and the engine control device 9 outputs a command to energize the heater 43 with the intermediate voltage to the heater control circuit 60. Based on this command, the heater control circuit 60 sets the voltage of the heater 43 to an intermediate voltage and adjusts the degree of heating of the heater 43. And it returns to step S10 from step S18, and it is determined again in step S12 whether a temporary abnormality generate | occur | produces.
Here, the intermediate voltage is between the maximum voltage of the heater 43 (12 V, which is the battery voltage in this embodiment) and the voltage (6-7 V in this embodiment) that can maintain the activation temperature of the cells 14, 24. Is the voltage. The voltage that can maintain the activation temperature of the cells 14 and 24 is, for example, a voltage at which the resistance of the cells 14 and 24 becomes a predetermined value or less.

As described above, when a temporary abnormality is detected for the time being, but the abnormality is not fixed, the heater 43 is appropriately heated with the intermediate voltage, and the process returns to step S12 to determine again whether there is a temporary abnormality. Then, it is determined whether or not the provisional abnormality is resolved, and the normal operation (step S20) of the gas sensor 8 can be immediately restored if the provisional abnormality is resolved.
In addition, when the number of abnormality determinations is 0 in step S10, the process may be shifted to step S20 regardless of the determination result in step S12. That is, in step S10, the lower limit of the number of abnormality determinations may be added to the determination criterion. This is because it is considered that there is no problem even if the transition to the PI control mode is once performed if the number of abnormality determinations is zero.

On the other hand, when the provisional abnormality occurs in step S14 beyond the predetermined frequency, the engine control device 9 determines the abnormality and proceeds to step S16, and turns off the heater 43 voltage to the heater control circuit 60 (non-energized). ) Is output. Based on this command, the heater control circuit 60 deenergizes the heater 43 and stops heating the heater 43. In step S16, the engine control device 9 increments the abnormality determination count 1 to the EEPROM 9m.
The increment of the number of times of abnormality determination in step S16 is performed when “Yes” continues in both step S12 and step S14.
Note that, as described above, the voltage of the heater 43 in step S16 may not be turned off, and the process may proceed to step S22. If it does in this way, the gas sensor de-energization process of step S24 will be performed, continuing heating the heater 43 with an intermediate voltage.

  Next, the process proceeds from step S16 to step S22, and the engine control device 9 determines whether or not the incremented abnormality determination count (“n + 1”, which is a value obtained by adding 1 to the previous n) is 2 or less. If the number of abnormality determinations incremented in step S22 is 2 or less, the process proceeds to step S24, and the engine control device 9 deenergizes the gas sensor 8. Here, the deenergization of the gas sensor 8 refers to an ON / OFF switching command for the switches SW1 to SW5 for setting the sensor protection energization state (P mode) shown in FIG. Is a process of outputting to the control unit 55. And the control part 55 switches the electricity supply state of the sensor drive circuit 52 to P mode.

On the other hand, when n exceeds 2 in step S10 or step S22, the process proceeds to step S26, and the engine control device 9 makes the above-described gas sensor de-energization process (the gas sensor 8 de-energized (P mode), and if necessary) In addition to the heater 43 being deenergized, an abnormality notification process for turning on a MIL (Multifunction indicator lamp) is performed. The process of step S26 is referred to as “abnormal end process”.
As described above, when abnormality confirmation occurs a predetermined number of times (three times in this embodiment) or more, an abnormality notification process (abnormal end process) is performed, so that an operator (automobile driver or the like) can be notified to the gas sensor 8. Can be informed of the abnormality and prompt the response (engine stop). This is because once the gas sensor control device 1 is stopped and then restarted, the abnormality is resolved even if the abnormality is confirmed by the previous activation (for example, a foreign object that has been short-circuited on the wiring is dropped, etc.) This is because the abnormality is often serious when it is stored that the abnormality is confirmed multiple times.

  In addition, once it transfers to step S24 or S26, unless the gas sensor control apparatus 1 is stopped (that is, the engine switch of the automobile is turned off) and the gas sensor control apparatus 1 is started again (the engine switch is turned on, that is, hot start), It does not return to the process of step S10 of the heater energization control process (including the abnormality confirmation process).

  In the present embodiment, step S12 corresponds to the “wiring abnormality detection process” in the claims. Steps S14 and S18 correspond to the “heater energization control process” in the claims. Steps S14, S16, S22, and S24 correspond to the “gas sensor non-energization process” in the claims. Writing to the EEPROM 9m in step S16 corresponds to the “storage process” in the claims. Step S26 corresponds to the “notification process” in the claims.

It goes without saying that the present invention is not limited to the above-described embodiment, but extends to various modifications and equivalents included in the spirit and scope of the present invention.
For example, the full-range air-fuel ratio sensor is taken up as the sensor element 10, but the present invention is not limited to this, and another sensor cell may be added to the sensor element 10 and applied to a NO _x sensor having two measurement chambers. Is possible.
However, if of the NO _x sensor, is performed in a batch control of the gas sensor is one microcomputer (controller), the control means, the heater control circuit, a wiring abnormality detecting means is implemented both on a single controller Yes. The controller corresponds to a gas sensor control device.

1 Gas sensor controller (internal combustion engine control system)
2 sensor control circuit 5 electronic control unit 8 gas sensor 9 control means, notification means (engine control device)
9m storage means (EEPROM)
13, 23 Solid electrolyte body 14, 24 cell (oxygen pump cell, oxygen concentration detection cell)
12, 16 A pair of electrodes (first pump electrode, second pump electrode)
22, 28 A pair of electrodes (first detection electrode, second detection electrode)
43 heater 52 sensor drive circuit 58 wiring abnormality detection means (abnormality detection circuit)
60 Heater control circuit

Claims (6)

A gas sensor having at least one cell including a solid electrolyte body and a pair of electrodes provided on the solid electrolyte body;
A heater for heating the solid electrolyte body;
A sensor driving circuit connected to the gas sensor and energizing the cell to drive the gas sensor;
A heater control circuit for controlling the heater;
Wiring abnormality detection means for detecting wiring abnormality of the sensor driving circuit or the gas sensor;
When the wiring abnormality detection means detects the wiring abnormality, the heater control circuit is driven to energize the heater with an intermediate voltage that is less than the maximum voltage of the heater and that is equal to or higher than the voltage that can maintain the activation temperature of the cell. When the occurrence of the wiring abnormality exceeds a predetermined frequency, a control means for fixing the abnormality and driving the sensor drive circuit to deenergize the gas sensor;
A gas sensor control device comprising: The gas sensor control device according to claim 1, wherein after the abnormality is determined, the control unit further drives the heater control circuit to deenergize the heater. Information indicating that the abnormality has been determined by the control means is stored, and the information is stored even after the gas sensor control device is stopped,
The gas sensor control device according to claim 1, further comprising a notifying unit that determines presence / absence of notification based on the information held in the storage unit when the control unit determines the abnormality. A gas sensor having at least one cell including a solid electrolyte body and a pair of electrodes provided on the solid electrolyte body, a heater for heating the solid electrolyte body, and the gas sensor connected to the gas sensor to drive the gas sensor A control method of a gas sensor control device comprising a sensor drive circuit for energizing a cell,
Wiring abnormality detection process for detecting wiring abnormality of the sensor drive circuit or the gas sensor;
When the wiring abnormality is detected, a heater energization control process of energizing the heater with an intermediate voltage that is less than the maximum voltage of the heater and that can maintain the activation temperature of the cell;
When the occurrence of the wiring abnormality exceeds a predetermined frequency, a gas sensor non-energization process for fixing the abnormality and driving the sensor drive circuit to de-energize the gas sensor;
A gas sensor control method comprising: The gas sensor control method according to claim 4, wherein the heater is further de-energized after the abnormality is determined in the de-energization process of the gas sensor. Storing information indicating that an abnormality has been established, and storing the information even after the gas sensor control device is stopped;
The gas sensor control method according to claim 4, further comprising: a notification process for determining presence / absence of notification based on the information when the abnormality is determined in the gas sensor de-energization process.

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