JP2009236536A - Self-diagnostic device of meter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a self-diagnostic device of a meter which is capable of detecting an incomplete abnormality not appearing in meter indication. <P>SOLUTION: The self-diagnostic device of the meter is provided with a diagnostic false sensor resistance 25 having a resistance value set beforehand within a resistance value range of a sensor 3, a switch 26 for switching whether the sensor 3 is connected to a supply voltage 23 and a split resistance 24, or whether the diagnostic false sensor resistance 25 is connected to them, and abnormality determination processing of steps S7-S21 which are executed by a processing operation part 21 and make the determination of the abnormality from a detection signal on the occasion when the diagnostic false sensor resistance 25 is connected. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention belongs to the technical field of a meter self-diagnosis device for a vehicle meter that displays information on a vehicle.

Conventionally, a disconnection of a sensor signal line is detected, and a self-diagnosis is activated and a pseudo sensor signal is generated from the duration of the disconnection. And the inspection in a factory is implemented using this pseudo sensor signal (for example, refer to patent documents 1).
JP-A 64-10126 (page 1-6, all figures)

  However, conventionally, it is possible to detect disconnection of the sensor signal line, but it is not possible to detect an incomplete abnormality that does not appear in the meter instruction.

  The present invention has been made paying attention to the above-mentioned problems, and an object of the present invention is to provide a meter self-diagnosis device that can detect an incomplete abnormality that does not appear in a meter instruction.

  In order to achieve the above object, in the present invention, a sensor that changes a resistance value with respect to a detection amount is connected, and a detection signal generation unit that generates a detection signal according to the detection amount of the sensor, and a meter instruction from the detection signal A meter self-diagnosis device for diagnosing the presence or absence of an abnormality with a meter device comprising a processing operation means for calculating a value, a pseudo sensor having a resistance value set in advance within a resistance value range of the sensor, and the detection Switching means for switching whether the sensor or the pseudo sensor is connected to the signal generating means, and a processing calculation means provided in the processing calculation means, and judging an abnormality from the detection signal when the pseudo sensor is connected And an abnormality determining means.

  Therefore, in the present invention, an incomplete abnormality that does not appear in the meter instruction can be detected.

  DESCRIPTION OF EMBODIMENTS Embodiments for realizing a meter self-diagnosis device of the present invention will be described below based on Examples 1 and 2 corresponding to the inventions according to claims 1, 2, 3, and 4.

First, the configuration will be described.
FIG. 1 is an explanatory diagram of a meter self-diagnosis apparatus according to the first embodiment.
The meter self-diagnosis apparatus according to the first embodiment is configured to be incorporated in an input circuit 2 for the sensor value detected by the sensor 3 to the meter apparatus 1.
As an example, the meter device 1 of the first embodiment is a fuel fuel gauge.
The input circuit 2 includes a processing calculation unit 21, a storage unit 22, a power supply voltage 23, a dividing resistor 24, a diagnostic pseudo sensor resistor 25, and a switch 26.
The processing calculation unit 21 processes and calculates the sensor value from the sensor 3 and outputs it to the meter device 1 as a meter drive signal. Further, the switch 26 is controlled to read data from the storage unit 22 and perform self-diagnosis. The diagnosis result is output to the outside as a fail signal output.

The storage unit 22 stores in advance initial values and the like used by the processing calculation unit 21 at the time of factory shipment, outputs the stored data in response to a request from the processing calculation unit 21, and responds to a request from the processing calculation unit 21. Data storage processing is performed. In addition, you may not memorize | store as needed. A specific example is an EEPROM in a meter circuit.
The power supply voltage 23 supplies power to the dividing resistor 24 and the sensor signal input line.
The dividing resistor 24 divides the power supply voltage 23 together with the sensor 3 or the diagnostic pseudo sensor resistor 25. When the sensor 3 is disconnected, the sensor signal line is pulled up.

The diagnostic pseudo sensor resistor 25 is a resistor connected in place of the sensor 3 at the time of self-diagnosis. The resistance value of the diagnostic pseudo sensor resistor 25 is a predetermined resistance value, and the resistance value is stored as data in the storage unit 22 at the time of factory shipment.
The switch 26 is provided in the middle of the sensor signal input line from the sensor 3 to the processing calculation unit 21 and at a position closer to the sensor 3 than the dividing resistor 24, and switches as follows. First, the switch 26 is switched so that the input from the sensor 3 is directed to the processing operation unit 21, the connection state where the diagnostic pseudo sensor resistance 25 is not connected, and the connection state where the diagnosis pseudo sensor resistance 25 is not connected. Is switched to a connection state connected to the input line to the processing calculation unit 21.
The switch 26 switches the connection state according to a control signal from the processing calculation unit 21.

Further explanation will be given.
In the first embodiment, the input circuit 2 and the sensor 3 have a configuration in which the power supply voltage 23 is divided by the dividing resistor 24 and the sensor 3 and a voltage value therebetween is input to the processing calculation unit 21 in a normal state. That is, the sensor 3 can be regarded as a variable resistor that changes the resistance value according to the detected value.
When the switch 26 is switched, the power supply voltage 23 is divided by the dividing resistor 24 and the diagnostic pseudo sensor resistor 25 and the voltage value therebetween is input to the processing calculation unit 21.

The operation will be described.
[Diagnostic control processing]
FIG. 2 is a flowchart showing the flow of diagnostic control processing executed by the processing calculation unit 21.

  In step S1, the diagnosis control process is started.

  In step S2, a measurement counter is added. That is, the measurement counter A = A + 1 is executed.

  In step S3, it is determined whether the measurement counter satisfies the condition of A <100. If the condition is satisfied (A <100), the process proceeds to step S4, and if the condition is not satisfied (A ≧ 100), the process proceeds to step S7.

  In step S4, the sensor signal from the sensor 3 is taken in as measurement.

  In step S5, a meter instruction value is calculated from the sensor signal.

  In step S <b> 6, the meter drive signal is determined from the meter instruction value, and the meter drive signal is output to the meter device 1.

  In step S7, the measurement counter is cleared. That is, A = 0.

  In step S8, the switch 26 of the input circuit 2 is switched to the diagnostic pseudo sensor resistor 25.

  In step S9, the resistance value of the diagnostic pseudo sensor resistor 25 is taken in as a measurement for diagnosis.

  In step S10, the measured resistance value of the pseudo sensor resistance for diagnosis 25 is compared with the determination value.

  In step S11, it is determined whether or not the resistance value of the diagnostic pseudo sensor resistor 25 is normal. If normal, the process proceeds to step S12, and if abnormal, the process proceeds to step S14.

  In step S <b> 12, the switch 26 of the input circuit 2 is switched to connection to the sensor 3.

  In step S13, the process returns to step S1.

  In step S14, an abnormality determination counter is added. That is, the abnormality determination counter B = B + 1 is executed.

  In step S15, it is determined whether the abnormality determination counter B satisfies the condition of B <3. If the condition is satisfied (B <3), the process proceeds to step S16, and if the condition is not satisfied (B ≧ 3), the process proceeds to step S18.

  In step S <b> 16, the switch 26 of the input circuit 2 is switched to connection to the sensor 3.

  In step S17, the process returns to step S1.

  In step S18, a fail signal is output.

  In step S19, the abnormality determination counter B is cleared. That is, the abnormality determination counter B = 0.

  In step S20, the switch 26 of the input circuit 2 is switched to the connection to the sensor 3.

  In step S21, the process returns to step S1.

[Abnormality detection]
In the meter self-diagnosis device according to the first embodiment, a diagnostic pseudo sensor resistor 25 is first connected at the time of initial shipment, and a resistance value calculated from an input value to the processing calculation unit 21 at this time is stored in the storage unit 22. .
Then, when used after shipment, the processing calculation unit 21 takes in sensor signals for normal display of the meter device 1 (step S4), calculates a meter indication value (step S5), and inputs to the meter device 1. Each time the drive signal is output (step S6), the measurement counter A is incremented by one.

Whenever the measurement counter A exceeds 100, the switch 26 switches the connection from the sensor 3 to the pseudo sensor resistance 25 for diagnosis (step S8).
That is, the self-diagnosis is performed every time the normal process is performed 100 times.
In a normal state, in the flow of current flowing from the power supply voltage 23 through the dividing resistor 24 to the ground from the sensor 3, the interval between the dividing resistor 24 and the sensor 3 is output to the processing arithmetic unit 21 as a detection point.

Therefore, when the sensor 3 changes the resistance value according to the detection value of the sensor 3, the voltage value divided by the dividing resistor 24 and the sensor 3 changes.
By reading this with the processing calculation unit 21, the detection value of the sensor 3 is calculated, the indication value of the meter device 1 is determined, and the drive signal is output.
In the self-diagnosis, by switching the switch 26, a detection point is detected between the divided resistor 24 and the diagnostic pseudo sensor resistor 25 in the flow of current flowing from the power supply voltage 23 through the divided resistor 24 to the ground from the diagnostic pseudo sensor resistor 25. Is output to the processing operation unit 21.

Therefore, the voltage value obtained by dividing the voltage value of the power supply voltage 23 by the dividing resistor 24 and the diagnostic pseudo sensor resistor 25 is read by the processing calculation unit 21 (steps S8 and S9).
The value of the diagnostic pseudo sensor resistor 25 is measured in advance at the time of initial shipment and stored in the storage unit 22. When this stored value is compared with the read measurement value (step S10), it is determined that an abnormality has occurred in the input circuit 2 when the difference reaches a preset determination value. This determination value is determined in advance through experiments or the like.

If it is determined that there is an abnormality, the abnormality determination counter B is incremented by 1 (step S14). If the abnormality counter B exceeds 3 (step S15), a fail signal is output (step S18).
When the fail signal is output, the warning lamp is turned on and an abnormality is displayed on the vehicle diagnosis device (consult).
The abnormality determination based on the comparison between the stored value of the diagnostic pseudo sensor resistor 25 and the measured value is detected when the abnormality does not appear on the meter display.
Therefore, an incomplete abnormality that does not appear in the meter instruction is detected before occurrence of disconnection or short circuit in the circuit or wiring.

Further explanation will be given.
FIG. 3 is an explanatory diagram of abnormality determination of the meter self-diagnosis apparatus of the first embodiment.
For example, when the disconnection occurs in the sensor 3 as an abnormality, the input signal is stuck to the upper limit (Hi) because it is input from the power supply voltage 23 to the processing arithmetic unit 21 via the dividing resistor 24.
And as meter device 1, it comes to stick to the indication minimum.
Therefore, even in the determination of the processing calculation unit 21, it is possible to recognize the abnormality even when viewed by the user who looks at the meter device 1 and the inspector.

In addition, when a short circuit occurs in the sensor 3 as an abnormality, the downstream of the dividing resistor 24 in the current path flowing from the power supply voltage 23 to the ground via the dividing resistor 24 is detected and input to the processing calculation unit 21. The input signal is stuck to the lower limit (Lo).
And as meter device 1, it comes to stick to the indication upper limit.
Therefore, even in the determination of the processing calculation unit 21, it is possible to recognize the abnormality even when viewed by the user who looks at the meter device 1 and the inspector.

  Further, on the input circuit 2 side, particularly in the case of the dividing resistor 24, an abnormal state opposite to that of the sensor 3 is caused. Can be recognized. These are the range 300 in FIG.

In the first embodiment, the upper and lower limit states of the input signal are continued in this way, that is, the error is taken into account in the normal meter indication even if it does not reach the obvious or abnormal state recognized by visual observation of the meter display. An abnormal state (range 200 in FIG. 3) that deviates from the range (range 100 in FIG. 3) and is close to a clear abnormal state is detected.
As a result, before an abnormality appears on the meter display, inspection or repair can be promoted by a warning display or the like, and the vehicle can be used in a better state.
In addition, in the abnormality determination before abnormality appears in this meter display, it can be determined by quantitatively determining from the measured value of the diagnostic pseudo sensor resistor 25.
In the abnormal state close to the obvious abnormal state detected in the first embodiment, in most cases, the meter indication value (display value) deviates from the range in which the error is taken into consideration in the normal indication value, and the display is shifted. It is in a state of being performed, and it is not preferable to use it as it is.

  Further, during this self-diagnosis, the process proceeds from step S3 to step S7, the processing of steps S8 to S21 is performed, and the reading of the value of the sensor 3 and the meter display processing of steps S4 to S6 are avoided. As a result, during the self-diagnosis, the meter indication value is not changed, the value obtained by detecting the resistance value of the diagnostic pseudo sensor resistor 25 is not reflected in the meter display, and the meter display does not feel uncomfortable. .

  Next, the effect will be described. In the meter self-diagnosis device of the first embodiment, the effects listed below can be obtained.

  (1) The sensor 3 that changes the resistance value with respect to the detection amount is connected, and the meter indication value is calculated from the power supply voltage 23 and the dividing resistor 24 that generate a detection signal corresponding to the detection amount of the sensor 3 and the detection signal. A meter self-diagnosis device for diagnosing the presence / absence of an abnormality with the meter device 1 including the processing calculation unit 21, a pseudo sensor resistance 25 for diagnosis having a resistance value set in advance within the resistance value range of the sensor 3, and a power supply voltage 23 and the switch 26 for switching between connecting the sensor 3 and the diagnostic pseudo sensor resistor 25 to the divided resistor 24 and the processing operation unit 21 and connecting the diagnostic pseudo sensor resistor 25 Since the abnormality determination process in steps S7 to S21 for determining abnormality from the detected signal is provided, an incomplete abnormality that does not appear in the meter instruction can be detected.

  (2) In the above (1), the power supply voltage 23 and the dividing resistor 24 include a dividing resistor 24 for dividing the voltage with the sensor 3 downstream of the power supply voltage 23, and the sensor 3 is connected downstream of the dividing resistor 24. The switch 26 is configured to output a detection signal from between the dividing resistor 24 and the sensor 3, and the switch 26 switches between connecting the sensor 3 and the diagnostic pseudo sensor resistor 25 downstream of the dividing resistor 24. The voltage value obtained by dividing the power supply voltage 23 by the dividing resistor 24 and the sensor 3 is used as a detection signal, the change in the resistance of the sensor 3 is detected by the voltage signal, and the sensor 3 is switched to the diagnostic pseudo sensor resistor 25, Since the resistance value is detected by the same detection circuit and detection signal line as in FIG. 3 to determine whether there is an abnormality, an incomplete abnormality that does not appear in the meter instruction can be detected.

  (3) In the meter self-diagnosis device described in (1) or (2) above, the meter instruction value is not changed while the pseudo sensor resistance 25 for diagnosis is provided in the processing calculation unit 21. Since the processing of maintaining steps S7 to S21 is performed separately from the processing of steps S4 to S6, the detection of the diagnostic pseudo sensor resistor 25 is not reflected in the meter display, and the meter display does not give the user a sense of incongruity. Can be.

  (4) In the above (1) to (3), the abnormality determination is performed by counting the detection from the sensor 3 and detecting when the diagnostic pseudo sensor resistor 25 is connected every time the measurement count A reaches 100. The resistance value of the diagnostic pseudo sensor resistor 25 calculated from the signal is compared with the resistance value of the diagnostic pseudo sensor resistor 25 in the initial stage of shipment stored in the storage unit 22 in advance, and the difference reaches a predetermined amount. Then, the abnormality determination counter B is counted, and when the abnormality determination counter B reaches 3 times, it is determined that there is an abnormality. Therefore, once in the normal use state, detection for diagnostic processing is performed intermittently, so that It is possible to prevent the meter display from being affected, and it is possible to make the abnormality determination more reliable by determining the abnormality when the predetermined condition reaches a plurality of times.

Example 2 is an example in which a switch and a pseudo sensor resistance for diagnosis are provided in a sensor.
The configuration will be described.
FIG. 4 is an explanatory diagram of the meter self-diagnosis apparatus of the second embodiment.
In the second embodiment, as shown in FIG. 4, a diagnostic pseudo sensor resistor 31 and a sensor 3 connected downstream to the ground are provided inside a sensor 33 as an apparatus, and a switch 32 is provided to provide the input circuit 2 and Whether to connect the sensor 3 or the pseudo sensor resistance 31 for diagnosis is switched.
A control signal from the processing calculation unit 21 to the switch 32 is output as a control signal to the sensor 33.
Since other configurations are the same as those of the first embodiment, description thereof is omitted.

The operation will be described.
[Action corresponding to sensor types and vehicle variations]
A plurality of sensors may be used for the meter display, and a plurality of meter displays are often displayed as the meter display. In that case, the sensor 33 can be provided with a diagnostic pseudo-sensor resistor 31 and a switch 32, and the input circuit 2 can be made as common as possible to reduce the cost, and it is easy to handle various types of sensors and meter displays. It may become.
In addition, there are cases where it is necessary to deal with various types of sensors and meter displays due to vehicle variations.
In such a case, the sensor 33 may include the diagnostic pseudo sensor resistor 31 and the switch 32 as in the second embodiment.

Explain the effect. In addition to the above (1) to (4), the meter self-diagnosis device of Embodiment 2 has the following effects.
(5) In the above (1) to (4), the sensor pseudo-sensor resistance 31 having a resistance value set in advance within the resistance value range of the sensor 3, the power supply voltage 23 and the dividing resistor 24 of the input circuit 2 are transferred to the sensor. 3 is provided in the sensor 33 to switch between the connection of the sensor 3 and the diagnostic pseudo-sensor resistor 31. Therefore, it is possible to easily cope with the sensor type and the vehicle variation while suppressing the cost. .
Since other functions and effects are the same as those of the first embodiment, description thereof is omitted.

The meter self-diagnosis device of the present invention has been described based on the first and second embodiments. However, the specific configuration is not limited to these embodiments, and each claim of the claims Design changes and additions are permitted without departing from the spirit of the invention.
For example, in the first embodiment, the abnormality diagnosis is performed when the normal measurement is performed 100 times. However, the detection may be performed every different number of times. For example, it may be performed when the IGN is turned on.
Further, for example, the abnormality diagnosis may be performed while the vehicle is running or while the vehicle is stopped.

It is explanatory drawing of the meter self-diagnosis apparatus of Example 1. FIG. It is a flowchart which shows the flow of the diagnostic control process performed in a process calculating part. It is explanatory drawing of the abnormality determination of the meter self-diagnosis apparatus of Example 1. FIG. It is explanatory drawing of the meter self-diagnosis apparatus of Example 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Meter apparatus 2 Input circuit 21 Processing calculating part 22 Memory | storage part 23 Power supply voltage 24 Dividing resistance 25 Pseudo sensor resistance for diagnosis 26 Switch 3 Sensor 31 Pseudo sensor resistance for diagnosis 32 Switch 33 Sensor (as apparatus)

Claims (4)

A sensor that changes a resistance value with respect to the detection amount is connected, and a detection signal generation unit that generates a detection signal according to the detection amount of the sensor;
Processing arithmetic means for calculating a meter indication value from the detection signal;
A meter self-diagnosis device for diagnosing the presence or absence of an abnormality with a meter device equipped with
A pseudo sensor having a preset resistance value within a resistance value range of the sensor;
Switching means for switching whether to connect the sensor or the pseudo sensor to the detection signal generation means;
An abnormality determining means that is provided in the processing calculation means and determines an abnormality from a detection signal when the pseudo sensor is connected;
A meter self-diagnosis device comprising: The meter self-diagnosis device according to claim 1,
The detection signal generating means includes a dividing resistor that divides a voltage with a sensor downstream of a power supply voltage, and connects the sensor downstream of the voltage dividing resistor so that the detection signal is between the dividing resistor and the sensor. Is output, and
The switching means switches whether to connect the sensor or the pseudo sensor downstream of the dividing resistor.
This is a meter self-diagnosis device. In the meter self-diagnosis device according to claim 1 or 2,
Provided in the processing calculation means, comprising meter indication value maintaining means for maintaining the meter indication value so as not to change during detection of the pseudo sensor,
This is a meter self-diagnosis device. In the meter self-diagnosis device according to any one of claims 1 to 3,
The abnormality determining means is
Each time the detection signal from the sensor reaches a predetermined number of times, the resistance value of the pseudo sensor calculated from the detection signal when the pseudo sensor is connected and the pre-stored pseudo sensor Compare the resistance value and judge that it is abnormal when the difference reaches a predetermined number of times.
This is a meter self-diagnosis device.

Images