JPH01248826A - Trouble detector for sensor with variable internal impedance - Google Patents

Abstract

PURPOSE:To obtain the same output as that when the low impedance presents in case of a sensor is normal by changing a reference voltage with a reference voltage changing means when the voltage outside the voltage range to be caused in case of the sensor is normal occurs at one side input of an operational amplifier. CONSTITUTION:When the impedance of an input circuit is increased by the disconnection of its own thermister S, the disconnection of the wiring of the thermister S, discharging, etc., the input of the (+) terminal of an operational amplifier OP is regulated by a Zener diode ZD, the reference voltage of a reference voltage generating means is supplied to the (-) terminal side of the operational amplifier OP with a diode, and made higher than the input voltage of the (+) terminal of the operational amplifier OP. Thus, even when the output of the operational amplifier OP is inverted and the impedance of the sensor circuit becomes higher, the same output as that when the impedance of the sensor circuit becomes lower is obtained.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a sensor failure detection device, and in particular,
The present invention relates to a failure detection device for a sensor whose internal impedance is variable and determines the state of the sensor when the internal impedance of the sensor changes.

[Prior Art] A conventional hydraulic motor fan control device has an overall configuration as shown in the schematic configuration diagram of FIG. 5. That is, an air conditioner switch signal and a water temperature sensor signal are input to the hydraulic motor controller unit, and a linear solenoid drive signal is output.

The relationship between the water temperature, solenoid current, and fan rotation speed of this hydraulic motor fan control device is shown in Figure 6.
It looks like the solenoid current/fan rotation speed characteristic diagram. That is, as the water temperature increases, the solenoid current decreases in inverse proportion to the water temperature from about 80° C. to 100° C., becomes zero at 100° C. or higher, and reaches its maximum value at 80° C. or lower. Further, the fan rotation speed increases as the solenoid current decreases, and decreases as the solenoid current increases.

[Problems to be Solved by the Invention] However, in the conventional hydraulic motor fan control device as described above, when the connection of a temperature sensor such as a thermistor is opened or disconnected, the resistance value of the thermistor becomes infinitely large, and the water temperature decreases. Outputting a drop signal, the hydraulic motor fan controller unit maximizes the solenoid current. When the solenoid current reaches its maximum, the fan speed slows down.
This situation has the potential to overheat,
There was a failsafe problem.

Therefore, the present invention was made to solve the above problems, and when the impedance of the sensor becomes abnormally high,
It is an object of the present invention to provide a failure detection device for a sensor with variable internal impedance that can obtain the same output as when the impedance of the sensor is low.

[Means for Solving the Problems] A failure detection device for a sensor with variable internal impedance according to the present invention includes a current supply means for supplying current to a sensor whose internal impedance changes depending on the external environment;
an operational amplifier; a resistor having one end connected to the sensor and the other end connected to one input of the operational amplifier; and a reference voltage generating means connected to the other input of the operational amplifier and generating a reference voltage; The voltage regulating means and the reference voltage changing means are provided.

In particular, the voltage regulating means in claim 1 is connected to one input of an operational amplifier, and when a voltage outside the voltage range that occurs when the sensor is normal is generated at one input of the operational amplifier, the voltage regulating means is connected to one input of the operational amplifier. The voltage of one input is regulated to a predetermined voltage, and the reference voltage changing means is configured to adjust the reference voltage when a voltage outside the voltage range that occurs when the sensor is normal occurs at one input of the operational amplifier. The reference voltage generated by the reference voltage generating means is changed.

Further, the voltage regulation means in claim 2 is connected to one input of the operational amplifier, and when a voltage outside the voltage range that occurs when the sensor is normal occurs at one input of the operational amplifier, the voltage regulating means is connected to one input of the operational amplifier. The voltage at one input of the resistor is regulated to a predetermined voltage, and the reference voltage changing means is connected to one end of the resistor and the reference voltage generating means, and the reference voltage changing means is connected to one end of the resistor and the reference voltage generating means so that the voltage at one end of the resistor exceeds a predetermined voltage value. In this case, the reference voltage generated by the reference voltage generating means is changed.

Furthermore, the voltage regulating means in claim 3 is connected to one input of the operational amplifier, and regulates the voltage of one input of the operational amplifier to a predetermined voltage when the amount of current flowing inside increases, and also regulates the voltage of one input of the operational amplifier to a predetermined voltage. The changing means is connected to one input of the operational amplifier and the current supply means, and when the voltage at one input of the operational amplifier reaches a voltage value regulated by the voltage regulating means, the change means generates the reference voltage of the reference voltage generating means. The voltage regulating means according to claim 4 is connected to one input of the operational amplifier and changes the voltage of one input of the operational amplifier to a predetermined voltage when the amount of current flowing inside increases. Further, the reference voltage changing means is connected to one end of the resistor and the reference voltage generating means, and when the voltage at one end of the resistor exceeds a predetermined voltage value, the reference voltage changing means generates the reference voltage. This changes the reference voltage.

[Function] In the invention of claim 1, a current is supplied from the current supply means to a sensor whose internal impedance changes depending on the external environment, one end of a resistor is connected to the sensor, and the other end of the resistor is connected to the sensor. Connected to one input of the operational amplifier, and connected to the other input of the operational amplifier, a reference voltage generating means for generating a reference voltage is connected to one input of the operational amplifier, and is generated when the sensor is normal. When a voltage outside the voltage range occurs at one input of the operational amplifier,
A voltage regulating means regulates the voltage of one input of the operational amplifier to a predetermined voltage, and is connected to one input of the operational amplifier and the reference voltage generating means, so that a voltage outside the voltage range generated when the sensor is normal is controlled. When the voltage is generated at one input of the operational amplifier, the reference voltage changing means changes the reference voltage generated by the reference voltage generating means. Therefore, when the impedance of the sensor becomes abnormally high, it is possible to obtain the same output as when the impedance of the sensor is normally low.

Further, in the invention of claim 2, when a voltage outside the voltage range that occurs when the sensor is normal is generated at one input of the operational amplifier, the voltage regulation means adjusts the voltage at one input of the operational amplifier to a predetermined voltage. a reference voltage changing means connected to one end of the resistor and the reference voltage generating means; when the voltage at one end of the resistor exceeds a predetermined voltage value, the reference voltage generated by the first two reference voltage generating means; It changes the voltage.

In the invention of claim 3, when the amount of current flowing inside the voltage regulating means connected to one input of the operational amplifier increases, the voltage of one input of the operational amplifier is regulated to a predetermined voltage, and the voltage of one input of the operational amplifier is A reference voltage changing means connected to the input of the operational amplifier and the current supply means changes the reference voltage generated by the reference voltage generating means when the voltage at one input of the operational amplifier reaches a voltage value regulated by the voltage regulating means. This is to change the

In the invention of claim 4, when the amount of current flowing inside the voltage regulating means connected to one input of the operational amplifier increases, the voltage of one input of the operational amplifier is regulated to a predetermined voltage, and the voltage at one end of the resistor is increased. Reference voltage changing means connected to the reference voltage generating means changes the reference voltage generated by the reference voltage generating means when the voltage at one end of the resistor exceeds a predetermined voltage value.

[Example] Examples of the present invention will now be described.

FIG. 1 is an overall configuration diagram of a failure detection device for a sensor with variable internal impedance according to an embodiment of the present invention.

In the figure, a thermistor S as a temperature sensor is connected in parallel with a protective resistor R1 that suppresses a sudden rise in terminal voltage and a capacitor C1 for noise removal, and whose internal impedance changes depending on the external environment. Configure the circuit. A constant voltage VCC is applied to the parallel circuit of the sensor circuit through a resistor R2 serving as a current supply means.

The output of the sensor circuit is an input resistor R3 and an input resistor R
7 to the input of the child terminal of the operational amplifier OP.

Further, a threshold voltage divided by a series circuit of a resistor R4 and a resistor R5 as a reference voltage generating means is connected to the input of one terminal of the operational amplifier OP via an input resistor R6 and an input resistor R8. The resistor R4 and the resistor R5 are connected to the operational amplifier O.
A reference voltage generating means for supplying a reference voltage connected to one terminal of P is constituted.

The diode D1 as a reference voltage changing means changes the voltage between the input resistance R3 and the input resistance R7 when the potential at the connection point between the input resistance R3 and the input resistance R7 is higher than the potential at the connection point between the input resistance R6 and the input resistance R8. The potential at the connection point is set to the input resistor R6.
This is a switching diode that sets the potential at the connection point between R8 and input resistor R8.

The Zener diode ZD as a voltage regulating means limits the input voltage of the child terminal of the operational amplifier OP.

In addition, resistor R9 is a feedback resistor that determines the amplification factor together with input resistor R8, resistor RIO is an output resistor, diode D1 is for preventing reverse connection, and capacitor C2 and capacitor C3 are for compensation or noise removal. .

The failure detection device for a sensor with variable internal impedance is configured as described above. Next, the water temperature-output voltage characteristic diagram of the embodiment shown in FIG. 2, the output voltage-solenoid current characteristic diagram of the embodiment shown in FIG. 3, and the water temperature of the operational amplifier OP of the embodiment shown in FIG. -Explain its operation using an output voltage characteristic diagram.

First, the thermistor S lowers its internal impedance as the water temperature rises, and the output of the sensor circuit lowers its voltage drop in response to the decrease in the internal impedance of the thermistor S. During this time, the reference voltage at the connection point between resistor R4 and resistor R5 that constitutes the reference voltage generating means must remain constant.
Diode D1 and diode D2 are reverse biased and in an off state. Furthermore, the Zener diode ZD is also in an off state.

Therefore, as shown in the water temperature-output voltage characteristic diagram of the embodiment shown in Fig. 1 of Fig. 2, the output voltage VO becomes zero at a predetermined water temperature, e.g. From 80°C to 100°C, the solenoid current reaches an output voltage of 0, which decreases in proportion to the water temperature. Therefore, normal linear output characteristics are obtained.

Therefore, if the impedance of the input circuit increases due to a disconnection in the thermistor S itself or a disconnection or open circuit in the wiring of the thermistor S, the voltage drop in the sensor circuit will increase, and the child terminal input of the operational amplifier OP will become high, causing the Zener diode ZD operates, and the child terminal input of the operational amplifier OP becomes a constant voltage state of voltage ZD. The current flowing through the Zener diode ZD becomes a voltage drop across the resistor R7, and when the voltage drop across the resistor R7 becomes the forward bias of the diode D1, the diode D1 is turned on, and the voltage drop across the resistor R7 becomes a voltage drop across the resistor R7.
It becomes an input to one terminal of the operational amplifier OP via , that is,
As shown in the water temperature-output voltage characteristic diagram of the operational amplifier OP in FIG. 4, the output of the operational amplifier OP is inverted. Therefore, the output voltage vs. solenoid current characteristic is as shown in Figure 3. When the impedance of the sensor circuit increases due to a break in the thermistor S itself or a break or open circuit in the wiring of the thermistor S, the output voltage It can be reversed and the solenoid current can be reduced. Therefore, when the failure detection device of a sensor with variable internal impedance of this embodiment is used as a hydraulic motor fan control device, the fan rotation speed may be reduced due to a disconnection of the thermistor S itself or a disconnection or openness of the wiring of the thermistor S. can be made high, so overheating etc. do not occur.

In this way, the failure detection device for a sensor with variable internal impedance according to the above embodiment consists of a connection point between a sensor such as a thermistor S, a resistor R2 serving as a current supply means, and a reference voltage generation means □ for generating a reference voltage. Obtain the connection point potential of resistor R4 and resistor R5 as the potential difference of the bridge circuit, which connection point potential of thermistor S and resistor R2 is input to the child terminal of operational amplifier OP, and regulate the input value with Zener diode ZD. , a resistor R4 and a resistor R5 connected to one terminal of the operational amplifier OP and supplying a reference voltage.
and a diode D that increases the reference voltage of the reference voltage generation means by the input when an input regulated by the Zener diode ZD occurs.
1.

Therefore, when the voltage drop in the sensor circuit becomes large, the input to the child terminal of the operational amplifier OP is regulated by the Zener diode ZD, and at this time, the resistor R4 and the resistor R
The reference voltage of the reference voltage generating means consisting of
By supplying a diode to one terminal side of P and making it higher than the input voltage of the child terminal of the operational amplifier OP, the output of the operational amplifier OP is inverted, and the impedance of the sensor circuit whose internal impedance changes depending on the external environment is high. Even when the impedance of the sensor circuit becomes low, the same output can be obtained as when the impedance of the sensor circuit becomes low. Therefore, the safety of a device such as a hydraulic motor fan control device that is fail-safe when the impedance of the sensor circuit is high can be improved.

In the above embodiment, a current is supplied from a resistor R2 serving as a current supply means to a sensor such as a thermistor S whose internal impedance changes depending on the external environment, and a resistor R3 is supplied to the sensor.
and a resistor R7, and the other end of the resistor is connected to one input of the operational amplifier OP, and a reference voltage generating means consisting of a series circuit of a resistor R4 and a resistor R5 that generates a reference voltage is connected. connected to the other input of the operational amplifier OP, and connected to one input of the operational amplifier OP, when a voltage outside the voltage range generated when the sensor is normal occurs at one input of the operational amplifier OP;
regulating the voltage of one input of the operational amplifier OP to a predetermined voltage by a voltage regulating means consisting of a Zener diode ZD;
When a voltage that is connected to one input of the operational amplifier OP and the reference voltage generation means and is outside the voltage range that occurs when the sensor is normal is generated at one input of the operational amplifier OP, when the sensor is normal. The reference voltage changing means changes the reference voltage generated by the reference voltage generating means according to a voltage outside the voltage range generated in the reference voltage generating means. Therefore, when a sensor such as thermistor S has an abnormally high internal impedance, it can be detected at the input side of the operational amplifier OP, and the same output as when the sensor has a normal low impedance can be obtained. . This configuration can be considered as the first invention.

Furthermore, when a voltage outside the voltage range that occurs at the normal point of the sensor, such as the thermistor S, occurs at one input of the operational amplifier OP, voltage regulation means consisting of a Zener diode ZD is used to control the voltage at one input of the operational amplifier OP. regulated the voltage at a predetermined voltage, and comprises a diode D1 connected to one end of the resistor and the reference voltage generating means, and when the voltage at one end of the resistor exceeds a predetermined voltage value, The reference voltage generated by the reference voltage generating means is changed. Therefore, when a sensor whose internal impedance changes depending on the external environment has an abnormally high internal impedance, the diode D
By setting the voltage on the input side or the output side of the reference voltage changing means consisting of 1, it is possible to obtain an output similar to that when the sensor has a normal low impedance, and it is also possible to process it digitally. This configuration can be made into a second invention.

Further, when the amount of current flowing inside the voltage Il1 means connected to one input of the operational amplifier OP increases, the voltage of one input of the operational amplifier OP is regulated to a predetermined voltage, and the voltage of one input of the operational amplifier OP and When the voltage at one input of the operational amplifier OP reaches a voltage value regulated by the voltage regulating means, a reference voltage changing means connected to the current supplying means controls the voltage value Q generated by the reference voltage generating means;
Since lightning voltage is changed, for example, by detecting the amount of current flowing inside a voltage regulation means such as a circuit that causes a voltage drop in order to maintain a constant voltage in a circuit such as a constant voltage circuit, it is possible to When a sensor whose internal impedance changes depending on the environment has an abnormally high internal impedance, it is possible to obtain the same output as when the sensor has a normally low impedance. This configuration can be made into a third invention.

Further, when the amount of current flowing inside the voltage regulating means connected to one input of the operational amplifier OP increases, the voltage of one input of the operational amplifier OP is regulated to a predetermined voltage, and one end of the resistor and the reference voltage The reference voltage changing means connected to the generating means changes the reference voltage generated by the reference voltage generating means when the voltage at one end of the resistor exceeds a predetermined voltage value. By setting a predetermined threshold value for , when a sensor whose internal impedance changes depending on the external environment has an abnormally high internal impedance, it is possible to obtain an output similar to that when the sensor has a normal low impedance. be able to. This configuration can be made into a fourth invention.

By the way, the current supply means for supplying current to the sensor whose internal impedance changes depending on the external environment in the above embodiment is composed of a resistor R2 connected in series with the sensor, but when implementing the present invention Alternatively, a constant current circuit or the like may be used.

Further, the resistor in the above embodiment has one end connected to the sensor whose internal impedance changes depending on the external environment, and the other end connected to one input of the operational amplifier.
It consists of a series circuit of resistor R3 and resistor R7,
When implementing the present invention, a single resistor or a plurality of resistors may be used.

Therefore, the reference voltage generating means that is connected to the other input of the operational amplifier of the above embodiment and generates the reference voltage is the resistor R4.
Although the divided voltage of resistor R5 is used, when the present invention is implemented, a constant voltage circuit output can be used.

Furthermore, although the voltage regulating means in the above embodiment uses a Zener diode ZD, when implementing the present invention, a plurality of diodes may be connected in series in the forward direction, and the sum of their forward bias voltages may be used as the threshold value. Alternatively, it can be configured with a circuit such as a constant voltage circuit.

Furthermore, although the reference voltage changing means in the above embodiment is composed of the diode D1, when implementing the present invention, it is possible to use a Zener diode or a comparison circuit that detects a voltage higher than a predetermined voltage. It's possible. In addition, at this time, the voltage outside the voltage range that is connected to one input of the operational amplifier OP and the reference voltage generation means and that is generated by the current supply means supplying current to the sensor when the sensor is normal. When a voltage is generated at one input of the operational amplifier OP, the reference voltage changing means for changing the reference voltage generated by the reference voltage generating means includes a resistor R3.
The reference voltage can also be changed by the divided voltage of the resistor R7 and the resistor R7, the divided voltage of the resistor R4 and the resistor R5, and the resistance values of the resistor R6 and the resistor R8.

[Effects of the Invention] As described above, the failure detection device for a sensor whose internal impedance is variable according to the present invention includes a current supply means for supplying current to a sensor whose internal impedance changes according to the external environment, and one end of which is connected to the a resistor connected to the sensor and having its other end connected to one input of the operational amplifier; a reference voltage generating means connected to the other input of the operational amplifier and generating a reference voltage; furthermore, a voltage regulating means and a reference voltage. Particularly, the voltage regulating means according to claim 1 is configured to change the voltage of the operational amplifier when a voltage outside the voltage range generated when the sensor is normal occurs at one input of the operational amplifier. The voltage of one input is regulated to a predetermined voltage, and the reference voltage changing means is configured to adjust the reference voltage to the reference voltage when a voltage outside the voltage range that occurs when the sensor is normal occurs at one input of the operational amplifier. This changes the reference voltage generated by the voltage generating means.

Therefore, the output of the operational amplifier is inverted by setting the reference voltage before and after the change generated by the reference voltage generating means.
When the impedance of the sensor becomes abnormally high, it is possible to obtain the same output as when the impedance of the sensor is low.

Further, the voltage regulating means according to claim 2 is connected to one input of the operational amplifier, and when a voltage outside the voltage range that occurs when the sensor υ is normal occurs at one input of the operational amplifier, the voltage regulating means is connected to one input of the operational amplifier. The voltage at one input of the resistor is regulated to a predetermined voltage, and the reference voltage changing means is connected to one end of the resistor and the reference voltage generating means, and the voltage at one end of the resistor exceeds a predetermined voltage value. At this time, the reference voltage generated by the reference voltage generating means is changed. Therefore, if it is detected that the voltage at one end of the resistor exceeds a predetermined voltage value, the same effect as the invention of claim 1 can be obtained even in digital threshold setting.

Furthermore, when the amount of current flowing inside the voltage regulating means in claim 3 increases, the voltage at one input of the operational amplifier is regulated to a predetermined voltage, and the reference voltage changing means is configured to regulate the voltage at one input of the operational amplifier and the voltage at the one input of the operational amplifier. It is connected to a current supply means, and changes the reference voltage generated by the reference voltage generation means when the voltage at one input of the operational amplifier reaches a voltage value regulated by the voltage regulation means. Therefore, when the amount of current flowing inside the voltage regulating means increases,
Even if the reference voltage generated by the base Q voltage generating means is changed by detecting this, the same effects as in claim 1 can be obtained.

The voltage regulating means according to claim 4 is connected to one input of the operational amplifier, and regulates the voltage of one input of the operational amplifier to a predetermined voltage when the amount of current flowing inside increases, and also changes the reference voltage. The means is connected to one end of the resistor and the reference voltage generating means, and changes the reference voltage generated by the reference voltage generating means when the voltage at one end of the resistor exceeds a predetermined voltage value; Similarly, the same effects as in claim 1 above can be obtained.

[Brief explanation of the drawing]

Fig. 1 is an overall configuration diagram of a failure detection device for a sensor with variable internal impedance according to an embodiment of the present invention, Fig. 2 is a water temperature-output voltage characteristic diagram of this embodiment, and Fig. 3 is an output of this embodiment. Voltage-Solenoid current characteristic diagram, Figure 4 is a water temperature-output voltage characteristic diagram of the operational amplifier of this embodiment, Figure 5 is a schematic configuration diagram of a conventional hydraulic motor fan control device, and Figure 6 is a conventional hydraulic motor fan control diagram. FIG. 2 is a water temperature-solenoid current/fan rotation speed characteristic diagram of the device. In the figure, S: thermistor, OP: operational amplifier, ZD: Zener diode, DI, D2: diode, R1 to RIO: resistor, C1 to C3: capacitor. In addition, in the figures, the same reference numerals and the same symbols indicate the same or equivalent parts. Patent applicant Aisin Seiki Co., Ltd.

Claims (4)

[Claims] (1) Current supply means for supplying current to a sensor whose internal impedance changes depending on the external environment; an operational amplifier; a resistor whose one end is connected to the sensor and the other end is connected to one input of the operational amplifier; a reference voltage generating means connected to the other input of the operational amplifier and generating a reference voltage; a current supply means connected to one input of the operational amplifier supplying current to the sensor when the sensor is normal; Voltage regulating means for regulating the voltage at one input of the operational amplifier to a predetermined voltage when a voltage outside the voltage range generated by the operation occurs at one input of the operational amplifier; one input of the operational amplifier and the reference voltage generation. When a voltage outside the voltage range generated by the current supply means supplying current to the sensor when the sensor is normal is generated at one input of the operational amplifier, the reference voltage is generated. 1. A failure detection device for a sensor with variable internal impedance, comprising: reference voltage changing means for changing a reference voltage generated by the means. (2) Current supply means for supplying current to a sensor whose internal impedance changes depending on the external environment; an operational amplifier; a resistor whose one end is connected to the sensor and the other end is connected to one input of the operational amplifier; a reference voltage generating means connected to the other input of the operational amplifier and generating a reference voltage; a current supply means connected to one input of the operational amplifier supplying current to the sensor when the sensor is normal; Voltage regulation means for regulating the voltage at one input of the operational amplifier to a predetermined voltage when a voltage outside the voltage range generated by the operation is generated at one input of the operational amplifier; connected,
When the voltage at one end of the resistor exceeds a predetermined voltage value, a reference voltage changing means changes the reference voltage generated by the reference voltage generating means; a failure of a sensor with variable internal impedance, comprising: Detection device. (3) Current supply means for supplying current to a sensor whose internal impedance changes depending on the external environment; an operational amplifier; a resistor whose one end is connected to the sensor and the other end is connected to one input of the operational amplifier; A reference voltage generating means connected to the other input of the operational amplifier and generating a reference voltage; connected to one input of the operational amplifier, when the amount of current flowing inside increases, the voltage of one input of the operational amplifier is set to a predetermined value. Voltage regulating means for regulating the voltage; connected to one input of the operational amplifier and the current supply means, and generating the reference voltage when the voltage at one input of the operational amplifier reaches a voltage value regulated by the voltage regulating means; 1. A failure detection device for a sensor with variable internal impedance, comprising: reference voltage changing means for changing a reference voltage generated by the means. (4) Current supply means for supplying current to a sensor whose internal impedance changes depending on the external environment; an operational amplifier; a resistor whose one end is connected to the sensor and the other end is connected to one input of the operational amplifier; A reference voltage generating means connected to the other input of the operational amplifier and generating a reference voltage; connected to one input of the operational amplifier, when the amount of current flowing inside increases, the voltage of one input of the operational amplifier is set to a predetermined value. voltage regulating means for regulating the voltage; connected to one end of the resistor and the reference voltage generating means;
When the voltage at one end of the resistor exceeds a predetermined voltage value, a reference voltage changing means changes the reference voltage generated by the reference voltage generating means; a failure of a sensor with variable internal impedance, comprising: Detection device.