JP4668805B2 - Gas sensor heater failure detection device - Google Patents

Description

  The present invention relates to a heater failure detection device for a gas sensor.

  For example, in a device that measures the gas concentration by driving the heater of the sensor element such as a gas alarm, it is important for the user to detect a failure of the sensor element. In particular, when driving a heater at a high temperature, such as a catalytic combustion gas sensor or semiconductor gas sensor, it is highly necessary to consider failures such as disconnection. When a heater failure is detected, an alarm sound or display is displayed to the user. Was informing.

In the prior art, when a failure such as a short (short circuit) or open (disconnection) of the heater of the gas sensor is detected, the failure is notified by an alarm sound, or by an alarm display using a power indicator (for example, (See Patent Documents 1 and 2).
JP 2001-235441 A Registered Utility Model No. 2532682

  However, if the heater fails in a short state, not only will the current consumption increase significantly, it will also cause heat generation of electronic components, etc., and in the worst case, it may cause damage to devices other than sensors or fire. There is.

  In actual use, there is no guarantee that the user will turn off the power of the alarm device in this failure state, and there is a high risk that the short state will be left for a long time.

  Therefore, conventionally, when a short-circuit state of the heater is detected, not only the failure is notified, but also the heat generation of the heater drive circuit device is suppressed and unnecessary current consumption is not generated, so the failure is determined. There was a type that stopped the heater current supply at that time.

  FIG. 6 is a circuit diagram showing a configuration example of a heater failure detection device for a conventional gas sensor of this type. The heater failure detection device for a gas sensor includes a heater drive circuit 1, a semiconductor gas sensor 2, a heater current detection unit 3, and a microcomputer (hereinafter referred to as CPU) 4.

  The heater drive circuit 1 is turned on / off in response to a heater reference voltage generation unit 5 including resistors R1 to R3 connected to a + Vb constant voltage power supply and a control signal connected in parallel to the resistor R1 and output from the output port P2 of the CPU 4. The pnp transistor Tr1 to be controlled, the npn transistor Tr2 connected between the heater power source + Vc and the heater 2a of the semiconductor gas sensor 2 via the current detection resistor Rd, and the connection point of the resistors R2 and R3 are non-inverted An operational amplifier OP1 having an input terminal connected thereto, an inverting input terminal connected to a connection point between the current detection resistor Rd and the heater 2a of the semiconductor gas sensor 2, and an output terminal connected to the base of the transistor Tr2 via the resistor R4; Connected between the base of Tr2 and the ground, and output from the output port P1 of the CPU 4 via the resistor R9 In the paper it is the control signal consisting of the heater current supply stop control unit 6 for containing a transistor Tr3 of npn type which is turned on / off control.

  The heater current detector 3 has a non-inverting input terminal connected to a connection point between the transistor Tr2 and the current detection resistor Rd via a resistor R5, and a resistor R7 connected to a connection point between the current detection resistor Rd and the heater 2a of the semiconductor gas sensor 2. The operational amplifier OP2 has an inverting input terminal connected thereto, a resistor R6 connected between the non-inverting input terminal and the ground, and a resistor R8 connected between the inverting input terminal and the output terminal. The output terminal of the operational amplifier OP2 is connected to the input port A / D1 of the CPU 4, and the inverting input terminal is connected to the input port A / D2 of the CPU 4 via the resistor R7.

  In the above configuration, the voltage determined by the voltage dividing ratio of the resistors R1, R2, and R3 is the heater voltage applied to the semiconductor gas sensor 2, and the heater Tr is turned on / off by the control signal from the output port P2 of the CPU 4. The voltage is switched between high (Hi) level and low (Lo) level. The heater current detection unit 3 detects the current flowing through the heater 2a with the voltage across the current detection resistor Rd and measures it at the input port A / D1 of the CPU 4.

  When the measured heater current value is, for example, the specification range of the semiconductor gas sensor 2 is set to a normal range (for example, 0.12 to 0.14A), the CPU 4 has some failure abnormality when deviating from the normal range. A failure alarm is issued from an alarm unit (not shown).

  In particular, when the heater current value is recognized as an abnormal value on the short side (that is, when the heater current value has decreased from the normal value), a control signal is output from the output port P1 of the CPU 4, and the heater current supply stop control unit The transistor Tr3 is turned on, the base current of the transistor Tr2 supplying the heater current is drawn, and the transistor Tr2 is turned off to stop the supply current to the heater 2a.

  After the stop, the alarm device is powered off (that is, the CPU 4 is reset), and the return operation is not performed unless the current value measured again becomes a normal value.

  If the supply of the heater current is not stopped, the current flows to the limit that the heater power supply + Vc and the transistor Tr2 can supply, causing not only the heat generation of the transistor Tr2 or the current detection resistor Rd, but also the current consumption of the device is several times higher than usual. And the state persists until the device is destroyed.

  FIG. 7 is a diagram illustrating an operation state of the heater failure detection device of FIG. As the failure portion, the contents of each item of the failure mode for the current detection resistor Rd and the heater 2a, the software determination by the CPU 4, the heater current supply and the return operation are shown.

  In FIG. 7, when the heater 2a is short-circuited, it is as described above.

  Further, when the heater 2a is opened, the heater current does not flow and the voltage across the current detection resistor Rd becomes zero, so the CPU 4 determines that the heater 2a is open. In this case, the heater drive circuit 1 is operating normally, and the operation state of supplying the heater current to the heater 2a is continued. Therefore, when the opening of the heater 2a is a temporary phenomenon and the open state is subsequently released, normal heater current supply to the heater 2a is restored.

  Further, when the current detection resistor Rd is short-circuited, the voltage across the current detection resistor Rd becomes zero in the same manner as when the heater 2a is open, so the CPU 4 determines that the heater 2a is open in terms of software. Therefore, when the short circuit of the current detection resistor Rd is a temporary phenomenon and the short circuit state is subsequently released, normal heater current supply to the heater 2a is restored in the same manner as when the heater 2a is opened.

  Furthermore, when the current detection resistor Rd is open, the voltage across the current detection resistor Rd becomes the voltage of the heater power supply + Vc, so the CPU 4 determines that the heater 2a is short on software. Therefore, in this case, even if the opening of the current detection resistor Rd is a temporary phenomenon and the open state is subsequently released, the return operation to the normal heater current is not performed as in the case of the short circuit of the heater 2a.

  In the above-described failure detection device, the heater current supply itself is stopped. For example, due to malfunction such as noise, the heater current becomes an abnormal value higher than normal and a short circuit of the heater is temporarily detected to detect the heater current. Even if the supply is returned to a normal state after the supply is stopped, the alarm device cannot have a means for canceling the failure, and the return operation cannot be performed. Therefore, in order to prevent the function of the alarm device from being stopped due to a temporary factor such as noise, complicated processing such as providing a plurality of current detection timings in software is required.

  Accordingly, an object of the present invention is to provide a heater failure detection device for a gas sensor that can be restored to a normal state when a heater failure of the gas sensor is temporarily detected.

The invention according to claim 1, which has been made to solve the above-mentioned problems, includes a gas sensor that detects gas with a sensor element that is heated by a heater to which a heater current is supplied from a heater current supply means, and the heater current that flows through the heater. A heater failure detection device for a gas sensor that detects a failure of the heater when the heater current detected by the current detection unit is equal to or higher than an abnormal value higher than a normal heater current value. A current limiting means provided in the heater current supply means for limiting the heater current to a preset limit current value; and the heater current detected by the current detection means is a normal heater current value. In comparison, when the heater current exceeds an abnormal value higher than the normal heater current value, the current A control means for operating a limiting means; and the heater current detected by the current detecting means after the current limiting means is operated is compared with a preset normal current determination value lower than the limit current value, and the heater current is Release means for releasing the operation of the current limiting means when the normal current judgment value is reached , the heater current supply means includes a constant voltage power supply, and the current limiting means is a voltage of the constant voltage power supply. And a constant voltage circuit that applies a voltage to the heater as a heater voltage corresponding to the limit current value .

In the first aspect of the present invention, the control means compares the heater current detected by the current detection means with the normal heater current value, and the heater current exceeds an abnormal value higher than the normal heater current value. In addition, a current limiting unit is provided in the heater current supply unit and operates to limit the heater current to a preset limit current value. Further, the release means releases the operation of the current limiting means when the heater current detected by the current detection means after the operation of the current limiting means reaches a preset normal current determination value lower than the limit current value. . The heater current supply means includes a constant voltage power supply, and the current limiting means includes a constant voltage circuit that divides the voltage of the constant voltage power supply and applies it to the heater as a heater voltage corresponding to the limit current value.

The invention according to claim 2, which has been made to solve the above-described problems, includes a gas sensor that detects gas by a sensor element heated by a heater to which a heater current is supplied from a heater current supply means, and the heater current that flows through the heater. A heater failure detection device for a gas sensor that detects a failure of the heater when the heater current detected by the current detection unit exceeds an abnormal value higher than a normal heater current value. A heater power supply that is provided in the heater current supply means and supplies a heater current to the heater; and a current limit that is provided in the heater current supply means and limits the heater current to a preset current limit value. A constant current source for supplying the limit current value; the heater power source; and the constant current source. When the heater current detected by the current detecting means and the current detecting means is compared with a normal heater current value, and the heater current exceeds an abnormal value higher than the normal heater current value. And a control means for switching the heater power source to the constant current source and operating the current limiting means so as to supply the limit current value to the heater from the constant current source, and after the operation of the current limiting means, the heater The heater voltage applied to the normal voltage determination value is compared, and when the heater voltage reaches the normal voltage determination value, the operation of the current limiting means is canceled, and the switch is switched from the constant current source to the heater power source. A heater failure detection device for a gas sensor, characterized in that it includes a release means for switching to a gas sensor.

In the invention according to claim 2 , when the heater current detected by the current detecting means is compared with the normal heater current value by the control means, and the heater current becomes higher than the abnormal value higher than the normal heater current value In addition, the current limiting means for limiting the heater current to a preset limit current value is activated. Further, when the heater voltage becomes a normal voltage determination value after the operation of the current limiting unit, the operation of the current limiting unit is canceled by the canceling unit, and the switch is switched from the constant current source to the heater power source.

According to the first aspect of the present invention, the gas sensor for detecting the gas with the sensor element heated by the heater supplied with the heater current from the heater current supply means, and the current detection means for detecting the heater current flowing through the heater are provided. A heater failure detection device for a gas sensor for detecting a heater failure when the heater current detected by the current detection means exceeds an abnormal value higher than a normal heater current value, and is provided in the heater current supply means. The current limiting means that limits the heater current to a preset current limit value, and the heater current detected by the current detection means is compared with the normal heater current value and the heater current is higher than the normal heater current value. In such a case, it is detected by the control means for operating the current limiting means and the current detection means after the current limiting means is activated. That the heater current is compared with a preset normal current determination value lower than the limit current value, and a releasing means heater current releases the operation of the current limiting means when it becomes a normal current determination value, the heater current supply The means includes a constant voltage power supply, and the current limiting means comprises a constant voltage circuit that divides the voltage of the constant voltage power supply and applies it to the heater as a heater voltage corresponding to the limited current value. , Operate the constant voltage circuit to limit the heater current, suppress the heat generation of the device of the heater drive circuit and increase in current consumption, and then resume the normal heater current supply when a normal state is detected Can be done.

According to the second aspect of the present invention, the gas sensor for detecting the gas with the sensor element heated by the heater supplied with the heater current from the heater current supply means, and the current detection means for detecting the heater current flowing through the heater are provided. A heater failure detection device for a gas sensor for detecting a heater failure when the heater current detected by the current detection means exceeds an abnormal value higher than a normal heater current value, and is provided in the heater current supply means. A heater power supply for supplying a heater current to the heater; a current limiting means for limiting the heater current to a preset limit current value provided in the heater current supply means, and a constant current source for supplying the limit current value; A current limiting means comprising a switch for switching between the heater power source and the constant current source, and a current detected by the current detecting means. The heater current is compared with the normal heater current value.If the heater current exceeds the abnormal value higher than the normal heater current value, the heater power supply is switched to a constant current source, and the current limit is set to the heater from the constant current source. The control means for operating the current limiting means to supply and the heater voltage applied to the heater after the current limiting means is operated are compared with the normal voltage judgment value, and the current restriction is performed when the heater voltage becomes the normal voltage judgment value. And release means for switching the switch from the constant current source to the heater power supply, so that the heater current supply means can be switched to a constant current circuit to limit the heater current when the gas sensor heater is short-circuited. In addition, while suppressing the increase in heat generation and current consumption of the heater drive circuit device, if a normal state is detected after that, the normal heater It can perform a return operation to supply the flow again.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  (First Embodiment) FIG. 1 is a circuit diagram showing the configuration of the main part of a gas alarm device equipped with a heater failure detection device for a gas sensor according to a first embodiment of the present invention. The heater failure detection device for a gas sensor includes a heater drive circuit 1, a semiconductor gas sensor 2, a heater current detection unit 3, and a microcomputer (hereinafter referred to as CPU) 4.

  The heater drive circuit 1 is turned on / off in response to a heater reference voltage generation unit 5 including resistors R1 to R3 connected to a + Vb constant voltage power supply and a control signal connected in parallel to the resistor R1 and output from the output port P2 of the CPU 4. The pnp transistor Tr1 to be controlled, the npn transistor Tr2 connected between the heater power source + Vc and the heater 2a of the semiconductor gas sensor 2 via the current detection resistor Rd, and the connection point of the resistors R2 and R3 are non-inverted An operational amplifier OP1 having an input terminal connected thereto, an inverting input terminal connected to a connection point between the current detection resistor Rd and the heater 2a of the semiconductor gas sensor 2, and an output terminal connected to the base of the transistor Tr2 via the resistor R4; The current limiting unit 7 is included. The heater drive circuit 1 functions as heater current supply means in the claims.

  The heater current limiter 7 has a collector and an emitter connected via a resistor R10 between the base of the transistor Tr2 and the ground, and is turned on / off by a control signal output from the output port P1 of the CPU 4 and supplied via the resistor R9. Npn-type transistor Tr3.

  The semiconductor gas sensor 2 includes a heater 2a and a plate electrode 2b as a sensor element that is heated by flowing a heater current through the heater 2a and senses the gas concentration.

  The heater current detector 3 has a non-inverting input terminal connected to a connection point between the transistor Tr2 and the current detection resistor Rd via a resistor R5, and a resistor R7 connected to a connection point between the current detection resistor Rd and the heater 2a of the semiconductor gas sensor 2. The operational amplifier OP2 has an inverting input terminal connected thereto, a resistor R6 connected between the non-inverting input terminal and the ground, and a resistor R8 connected between the inverting input terminal and the output terminal. The output terminal of the operational amplifier OP2 is connected to the input port A / D1 of the CPU 4, and the inverting input terminal is connected to the input port A / D2 of the CPU 4 via the resistor R7.

  The current detection resistor Rd and the heater current detection unit 3 function as current detection means in the claims. The heater current limiting unit 7 functions as a current limiting unit in the claims. The CPU 4 functions as control means and release means in the claims. The heater reference voltage generator 5, the operational amplifier OP1, the resistor R4, the resistor R10, and the transistors Tr2 and Tr3 function as a constant voltage circuit in the claims.

  The outline of the failure detection operation of the heater failure detection apparatus having the above configuration will be described. When the heater current of the semiconductor gas sensor 2 is determined to be abnormal on the short side, conventionally, the supply current to the heater 2a is supplied as the heater current. As shown in FIG. 1, the base voltage V1 of the transistor Tr2 is fixed by the voltage dividing ratio of the resistor R4 and the resistor R10, and the heater applied to the heater 2a of the semiconductor gas sensor 2 is stopped by the stop control unit 6. The voltage V2 is made constant at a voltage about 0.6V lower than the base voltage V1. By adjusting the resistance values of the resistors R4 and R10, the heater current I can be suppressed to the current value of V2 / Rd even when the heater 2a is short-circuited. It is possible to suppress.

  Further, in this state, by monitoring the voltage across the current detection resistor Rd, even if a short state occurs due to a temporary factor such as noise and then the short state is resolved, it is stored in advance in the internal memory of the CPU 4. By comparing with the normal heater current value, it can be determined whether or not the normal state has been restored.

  Next, details of the gas alarm operation and the failure detection operation of the gas alarm will be described. The voltage determined by the voltage dividing ratio of the resistors R1, R2, and R3 is set as a heater voltage to be applied to the semiconductor gas sensor 2, and the heater voltage is increased (Hi) by turning on / off the transistor Tr1 according to a control signal from the output port P2 of the CPU 4. ) Switch between level / low (Lo) level. The high (Hi) level heater voltage heats the heater 2a to a temperature suitable for detection of combustible gas, for example, methane, and the low (Lo) level heater voltage is generated, for example, during incomplete combustion. The heater 2a is heated to a temperature suitable for detecting CO.

  During the period when the heater 2a of the semiconductor gas sensor 2 is driven with a high (Hi) level heater voltage, the sensor output output from the plate electrode 2b is input to an input port (not shown) of the CPU 4 to be output as the sensor output. Corresponding methane concentration is detected. When the detected methane concentration exceeds the methane alarm concentration prestored in the internal memory of the CPU 4, the CPU 4 drives an alarm unit (not shown) to give an alarm. Further, during the period in which the heater 2a is driven with a low (Lo) level heater voltage, the sensor output output from the plate electrode 2b is input to an input port (not shown) of the CPU 4 and the CO output corresponding to the sensor output. The concentration is detected. When the detected CO concentration exceeds the CO alarm concentration stored in the internal memory of the CPU 4, the CPU 4 drives an alarm unit (not shown) to give an alarm.

  The heater current detection unit 3 detects the current flowing through the heater 2a with the voltage across the current detection resistor Rd and measures it at the input port A / D1 of the CPU 4.

  When the measured heater current value deviates from the normal range of the semiconductor gas sensor 2, for example, the CPU 4 determines that some failure abnormality has occurred, and issues a failure alarm from an alarm unit (not shown).

  In particular, when the heater current value is recognized as an abnormal value on the short side, a high (Hi) level control signal is output from the output port P1 of the CPU 1, the transistor Tr3 of the heater current control unit 7 is turned on, and the heater current is turned on. Is fixed to a divided voltage value determined by a voltage dividing ratio of the resistor R4 and the resistor R10 lower than the maximum output voltage Vo of the operational amplifier OP1, thereby suppressing a supply current to the heater 2a. .

  After that, when the short-circuit state of the heater 2a is released, the resistance value of the heater 2a is added in series with the current detection resistor Rd, so the supply current to the heater 2a is further reduced from the current value suppressed as described above. To do.

  The CPU 4 determines that the short-circuit state of the heater 2a is canceled and returns to the normal state due to the current decrease, and the level of the control signal output from the output port P1 is changed from the high (Hi) level to the low (Lo) level. Then, the transistor Tr3 of the heater current control unit 7 is turned off. As a result, the heater current control unit 7 is deactivated, and the supply current to the heater 2a is returned to the normal value.

  Next, details of the failure detection operation performed under the control of the CPU 4 will be described with reference to the flowchart of FIG. First, the heater current is measured by measuring the voltage corresponding to the current flowing through the heater 2a at the input port A / D1 of the CPU 4 by the current detection resistor Rd and the heater current detection unit 3 (step S1).

  Next, whether the measured heater current value deviates from the normal heater current value range (referred to as range A) in the normal state of the semiconductor gas sensor 2 stored in the internal memory of the CPU 4 in advance. Is determined (step S2). If not deviating, the failure alarm is canceled (step S3), and then the process returns to step S1. If it deviates, then, it is determined that the heater 2a has failed (step S4), and then a failure alarm process for issuing a failure alarm from an alarm unit (not shown) is performed (step S5).

  Next, it is determined whether or not the heater 2a has a short side failure (step S6). This determination is a short-side failure if the heater current has an abnormal value higher than the normal range A, and a non-short-side failure (open failure) if the heater current has an abnormal value lower than the normal range A. It is. If there is no short-side failure, the process returns to step S1.

  If it is a short-side failure, then, a high (Hi) level control signal is output from the output port P1 of the CPU 1 to turn on the transistor Tr3 of the heater current control section 7 (step S7). Thereby, the supply current to the heater 2a is suppressed to a low value, and the subsequent return monitoring mode is entered. That is, the return monitoring mode is a mode for determining whether or not the heater current value has returned to the normal range after the heater failure is confirmed and the transistor Tr3 is turned on by a process described later.

  Next, the heater current is measured by measuring the voltage corresponding to the current flowing through the heater 2a at the input port A / D1 of the CPU 4 by the current detection resistor Rd and the heater current detection unit 3 (step S8).

  Next, it is determined whether the measured heater current value is within the normal range (referred to as range B) when the semiconductor gas sensor 2 is restored after the short-circuit failure is determined, which is stored in advance in the internal memory of the CPU 4. (Step S9). Here, the range B is a heater current value (normal current determination value) range in the normal semiconductor gas sensor 2 in a state where the transistor Tr3 is turned on after the heater failure is determined. If it is not within the range, the failure alarm is continued (step S10), and then the process returns to step S8. If it is within the range, the level of the control signal output from the output port P1 of the CPU 1 is then changed from the high (Hi) level to the low (Lo) level, and the transistor Tr3 of the heater current control unit 7 is turned off ( Step S11). As a result, the heater current control unit 7 is deactivated, the supply current to the heater 2a is restored to the value in the normal state, the normal monitoring mode is set, and then the process returns to step S1.

  FIG. 3 is a diagram illustrating an operation state of the heater failure detection device of FIG. As the failure portion, the contents of each item of the failure mode for the current detection resistor Rd and the heater 2a, the software determination by the CPU 4, the heater current supply and the return operation are shown.

  In FIG. 3, when the heater 2a is short-circuited, it is as described above.

  Further, when the heater 2a is opened, the heater current does not flow and the voltage across the current detection resistor Rd becomes zero, so the CPU 4 determines that the heater 2a is open. In this case, the heater drive circuit 1 is operating normally, and the operation state of supplying the heater current to the heater 2a is continued. Therefore, when the opening of the heater 2a is a temporary phenomenon and the open state is subsequently released, normal heater current supply to the heater 2a is restored.

  Further, when the current detection resistor Rd is short-circuited, the voltage across the current detection resistor Rd becomes zero in the same manner as when the heater 2a is open, so the CPU 4 determines that the heater 2a is open in terms of software. Therefore, when the short circuit of the current detection resistor Rd is a temporary phenomenon and the short circuit state is subsequently released, normal heater current supply to the heater 2a is restored in the same manner as when the heater 2a is opened.

  Furthermore, when the current detection resistor Rd is open, the voltage across the current detection resistor Rd becomes the voltage of the heater power supply + Vc, so the CPU 4 determines that the heater 2a is short on software. Therefore, in this case, when the opening of the current detection resistor Rd is a temporary phenomenon and the open state is subsequently released, the return operation to the normal heater current is performed in the same manner as when the heater 2a is short-circuited.

  As described above, according to the first embodiment of the present invention, when the short circuit failure of the heater 2a of the semiconductor gas sensor 2 is detected, the heat generation of the device of the heater driving circuit and the increase in the current consumption are suppressed, and thereafter the normal state is restored. If detected, a return operation can be performed in which normal heater current is supplied again.

Next, a specific example of adjusting the resistors R4 and R10 in the first embodiment described above will be described. For example, when Vb = 5V, Vc = 2.3V, the resistance value of the heater 2a is 3.4Ω, and the current detection resistance Rd = 3.3Ω, the resistance values of the resistors R4 and R5 are R4 = 560Ω and R10 = 220Ω, respectively. When the maximum output voltage Vo of the operational amplifier OP1 that controls the heater voltage V2 is set to 3.5 V, the base voltage V1, the emitter voltage V2, and the heater current I are obtained by the following equations.
V1 = 3.5V × 220Ω / (560Ω + 220Ω) = 0.99V (1)
V2 = 0.99V-0.6V = 0.36V (2)
I = 0.36V / 3.3Ω = 0.109A (3)

The current value obtained by the above equation (3) is the heater current value when the heater 2a is short-circuited. When the short-circuit state is canceled after the heater 2a is short-circuited, the heater current value is I = 0.36V / (3.3Ω + 3.4Ω) = 0.053A.
When the judgment threshold value when the heater current returns to the normal state from the short state (when the short state is canceled) is set to a predetermined range (range B) including this value, the normal state is restored. Can be determined.

  (Second Embodiment) FIG. 4 is a circuit diagram showing the structure of the main part of a gas alarm device equipped with a heater failure detection device for a gas sensor according to a second embodiment of the present invention. In the second embodiment, the configuration of the heater current control unit 7 is different from that of the first embodiment described above, and other configurations are the same as those of the first embodiment.

  The heater current control unit 7 has a non-inverting input terminal connected to the connection point of the resistors R1 and R2, an output terminal connected to the base of the pnp transistor Tr4, an inverting input terminal connected to the emitter of the transistor Tr4, and It comprises an operational amplifier OP3 connected to a + Vb constant voltage power supply via a resistor Ri, and a one-circuit two-contact type switch SW1 that is switched and controlled by a control signal output from an output port P1 of the CPU 4. The common terminal SW1a of the switch SW1 is connected to the collector of the transistor Tr2, the contact terminal SW1b is connected to the collector of the transistor Tr4, and the contact terminal SW1c is connected to the heater power supply + Vc. The operational amplifier OP3 and the resistor Ri constitute a constant current source. The operational amplifier OP3, the transistor Tr4, and the resistor Ri function as a constant current source in the claims, and the switch SW1 functions as a switch in the claims.

  An outline of the operation of the heater failure detection apparatus having the above configuration will be described. When the heater current of the semiconductor gas sensor 2 is determined to be abnormal on the short side, the current supply source connected to the transistor Tr2 is determined from the heater power supply + Vc. The constant current source is switched to the constant current source composed of the operational amplifier OP3, the transistor Tr4, and the resistor Ri, and a constant heater current is supplied. Therefore, even when the heater 2a is short-circuited, the heater current can be suppressed to a constant value, so that an increase in current consumption and heat generation of the electronic component can be suppressed. In this state, by monitoring the voltage across the current detection resistor Rd, the normal state stored in advance in the internal memory of the CPU 4 even if the short state occurs due to a temporary factor such as noise and then the short state is resolved. By comparing with the heater current value at the time, it can be determined whether or not the normal state has been restored.

  Next, details of the operation of the heater failure detection device of the present invention will be described. The voltage determined by the voltage dividing ratio of the resistors R1, R2, and R3 is set as a heater voltage to be applied to the semiconductor gas sensor 2, and the heater voltage is increased (Hi) by turning on / off the transistor Tr1 according to a control signal from the output port P2 of the CPU 4. ) Switch between level / low (Lo) level. The high (Hi) level heater voltage heats the heater 2a to a temperature suitable for detection of combustible gas, for example, methane, and the low (Lo) level heater voltage is generated, for example, during incomplete combustion. The heater 2a is heated to a temperature suitable for detecting CO.

  The switch SW1 of the heater current control unit 7 is switched so that the collector of the transistor Tr2 is connected to the heater power supply + Vc when normal. The heater current detection unit 3 detects the current flowing through the heater 2a with the voltage across the current detection resistor Rd and measures it at the input port A / D1 of the CPU 4.

  When the measured heater current value deviates from the normal range of the semiconductor gas sensor 2, for example, the CPU 4 determines that some failure abnormality has occurred, and issues a failure alarm from an alarm unit (not shown).

  In particular, when the heater current value is recognized as an abnormal value on the short side, a control signal is output from the output port P1 of the CPU 4, the switch SW1 of the heater current control unit 7 is switched, and the collector of the transistor Tr2 is changed to the collector of the transistor Tr4. Connect to the side. Thereby, the supply current to the heater 2a is suppressed to a constant current value.

  Thereafter, when the short-circuit state of the heater 2a is released, the resistance value of the heater 2a is added in series with the current detection resistor Rd. Therefore, the voltage V4 at the connection point between the current detection resistor Rd and the heater 2a is constant from about 0V. It rises by the voltage drop in the heater 2a due to the current.

  The CPU 4 measures this voltage at the input port A / D2 of the CPU 4, determines that the short-circuit state of the heater 2a has been released and has returned to the normal state, stops the control signal output from the output port P1, and switches Switch SW1 to the heater power supply + Vc side again. Thereby, the supply current to the heater 2a is returned to the value in the normal state.

  Next, details of the failure detection operation performed under the control of the CPU 4 will be described with reference to the flowchart of FIG. First, the heater current is measured by measuring the voltage corresponding to the current flowing through the heater 2a at the input port A / D1 of the CPU 4 by the current detection resistor Rd and the heater current detection unit 3 (step S21).

  Next, whether the measured heater current value deviates from the normal heater current value range (referred to as range A) in the normal state of the semiconductor gas sensor 2 stored in the internal memory of the CPU 4 in advance. Is determined (step S22). If not deviating, the failure alarm is canceled (step S23), and then the process returns to step S21. If it deviates, then, it is determined that the heater 2a has failed (step S24), and then a failure alarm process for issuing a failure alarm from an alarm unit (not shown) is performed (step S25).

  Next, it is determined whether or not there is a short side failure of the heater 2a (step S26). This determination is a short-side failure if the heater current has an abnormal value higher than the normal range A, and a non-short-side failure (open failure) if the heater current has an abnormal value lower than the normal range A. It is. If there is no short-side failure, the process returns to step S21.

  If it is a short-side failure, then, a control signal is output from the output port P1 of the CPU 1, and the switch SW1 of the heater current control unit 7 is switched so that the common terminal SW1a is short-circuited to the contact terminal SW1b. The collector is connected to the collector side of the transistor Tr4 (step S27). Thereby, the supply current to the heater 2a is suppressed to a low constant current value by the constant current source, and the subsequent return monitoring mode is entered.

  Next, the heater voltage V4 is measured by measuring the voltage applied to the heater 2a at the input port A / D2 of the CPU 4 (step S28).

  Next, whether or not the value of the measured heater voltage V4 is within the normal range (referred to as range C) at the time of return after the short circuit failure of the semiconductor gas sensor 2 is stored in the internal memory of the CPU 4 Is determined (step S29). Here, the range C is a heater voltage value (normal voltage determination value) range in a normal semiconductor gas sensor 2 in a state where a constant current is supplied from a constant current source after the heater failure is confirmed. If it is not within the range, the failure alarm is continued (step S30), and then the process returns to step S28. If it is within the range, the output of the control signal from the output port P1 of the CPU 1 is then stopped, the switch SW1 of the heater current control unit 7 is switched so that the common terminal SW1a is short-circuited to the contact terminal SW1c, and the contact terminal transistor Tr2 Are connected to the heater power source + Vc side (step S31). Thereby, the supply current to the heater 2a is returned to the value in the normal state, the normal monitoring mode is set, and then the process returns to step S21.

  The operating state of the heater failure detection device of the second embodiment is the same as that of the first embodiment shown in FIG.

  As described above, according to the second embodiment of the present invention, when the heater 2a of the semiconductor gas sensor 2 is short-circuited, the heating of the device of the heater driving circuit and the increase in current consumption are suppressed, and thereafter the normal state is detected. In this case, a return operation can be performed in which normal heater current is supplied again.

  Compared to the configuration of the first embodiment, the configuration of the second embodiment has characteristic value tolerances such as the maximum output Vo of the operational amplifier and the collector-emitter saturation voltage of the transistor Tr2 (temperature characteristics and other tolerances are relatively large). (Characteristic value) can be ignored, so that the accuracy of the heater current supplied to the semiconductor gas sensor 2 is high, and thus the failure detection accuracy is high.

  Next, a specific example of the constant current source configured by the operational amplifier OP3, the transistor Tr4, and the resistor Ri in the above-described second embodiment will be described. For example, when Vb = 5V, Vc = 2.3V, the resistance value of the heater 2a is 3.4Ω, and the current detection resistor Rd = 3.3Ω, the inverting input terminal of the operational amplifier OP3 determined by the voltage dividing ratio of the resistors R1, R2, and R3 The voltage V3 and a constant current value to be supplied are set, and the value of the resistor Ri is calculated.

When setting the inverting input terminal V3 of the operational amplifier OP3 to V3 = 3V and a constant current value Ic to be supplied Ic = 0.13A,
Ri = (5V-3V) /0.13A≈15Ω (4)
Therefore, the resistance value of the resistor Ri may be set to 15Ω.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to this, A various deformation | transformation and application are possible.

  For example, in the first embodiment described above, a constant voltage device such as a Zener diode or a shunt regulator may be substituted for the resistor R10 of the heater current control unit 7.

  Further, in the first and second embodiments described above, short-circuit failure of the heater 2a (and open failure of the current detection resistor Rd) and other failures are detected in step S6 in the flowchart of FIG. 2 and step S26 in the flowchart of FIG. The recovery monitoring mode is set only when the heater 2a is short-circuited. However, the present invention is not limited to this, and by omitting steps S6 and S26, a short-circuit failure of the heater 2a (and the current detection resistor Rd) It is possible to change to the return monitoring mode when either of the failure of the open failure) or the open failure of the heater 2a (and the short failure of the current detection resistor Rd) occurs.

  In the above-described embodiment, an example in which a semiconductor gas sensor is used as the gas sensor has been described. However, the present invention is not limited to this, and can be applied to other types of sensors having a heater.

It is a circuit diagram which shows the structure of the principal part of the gas alarm device provided with the heater failure detection apparatus of the gas sensor which concerns on the 1st Embodiment of this invention. (First embodiment) It is a flowchart of the heater failure detection operation | movement in 1st Embodiment. (First embodiment) It is a figure which shows the operation state of the heater failure detection apparatus of this invention. It is a circuit diagram which shows the structure of the heater failure detection apparatus of the gas sensor which concerns on the 2nd Embodiment of this invention. (Second Embodiment) It is a flowchart of the heater failure detection operation in 2nd Embodiment. (Second Embodiment) It is a circuit diagram which shows the structural example of the heater failure detection apparatus of the conventional gas sensor. It is a figure which shows the operation state of the conventional heater failure detection apparatus.

Explanation of symbols

1 Heater drive circuit (heater current supply means)
2 Semiconductor gas sensor 3 Heater current detector (part of current detector)
4 Microcomputer (CPU) (control means, release means)
5 Heater reference voltage generator 7 Heater current limiter (current limiter)
Rd Current detection resistor (part of current detection means)
Ri resistance (part of constant current source)
OP3 operational amplifier (part of constant current source)
Tr4 transistor (part of constant current source)

Claims (2)

A gas sensor for detecting gas by a sensor element heated by a heater to which a heater current is supplied from a heater current supply means; and a current detection means for detecting the heater current flowing through the heater, and is detected by the current detection means. A heater failure detection device for a gas sensor that detects a failure of the heater when the heater current is equal to or higher than an abnormal value higher than a normal heater current value,
Current limiting means provided in the heater current supply means for limiting the heater current to a preset limit current value;
Control for operating the current limiting means when the heater current detected by the current detection means is compared with a normal heater current value and the heater current is higher than an abnormal value higher than the normal heater current value. Means,
When the heater current detected by the current detection means after operation of the current limiting means is compared with a preset normal current determination value lower than the limit current value, and the heater current becomes the normal current determination value And a release means for releasing the operation of the current limiting means ,
The heater current supply means includes a constant voltage power source,
The heater failure detection device for a gas sensor, wherein the current limiting means includes a constant voltage circuit that divides the voltage of the constant voltage power source and applies the voltage to the heater as a heater voltage corresponding to the limit current value . A gas sensor for detecting gas by a sensor element heated by a heater to which a heater current is supplied from a heater current supply means; and a current detection means for detecting the heater current flowing through the heater, and is detected by the current detection means. A heater failure detection device for a gas sensor that detects a failure of the heater when the heater current is equal to or higher than an abnormal value higher than a normal heater current value,
A heater power supply provided in the heater current supply means, for supplying a heater current to the heater;
Current limiting means provided in the heater current supply means for limiting the heater current to a preset limit current value, a constant current source for supplying the limit current value, the heater power supply, and the constant current source Current limiting means comprising a switch for switching between,
The heater current detected by the current detection means is compared with a normal heater current value, and when the heater current is not less than an abnormal value higher than the normal heater current value, the heater power supply is connected to the constant current source. Control means for operating the current limiting means to supply the limited current value to the heater from the constant current source,
The heater voltage applied to the heater after the operation of the current limiting means is compared with a normal voltage determination value, and when the heater voltage reaches the normal voltage determination value, the operation of the current limiting means is canceled, and the switch A release means for switching from the constant current source to the heater power source;
A heater failure detection device for a gas sensor, comprising:

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