JP3649057B2 - Torque sensor - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a torque sensor for detecting torque generated on a rotating shaft, and more particularly, in a torque sensor having a pair of detection coils whose impedances change in opposite directions according to the generated torque, the detection coil and other circuits. The present invention relates to an improvement of a torque sensor that prevents erroneous detection of torque due to poor contact of a connecting portion with an element.
[0002]
[Prior art]
As a non-contact type torque sensor, there is one disclosed in Japanese Patent Laid-Open No. 10-38715 previously proposed by the present applicant. The conventional torque sensor disclosed in the above publication converts torsion of the torsion bar in proportion to the torque into a change in inductance of the detection coil, and this change in inductance is detected by a bridge circuit composed of a pair of detection coils and resistors. To do.
[0003]
That is, an AC voltage is supplied to a bridge circuit having a first and second arm composed of a pair of detection coils and a resistor, and the output that appears at the connection between the detection coil and the resistor of the first arm at that time The differential voltage between the voltage and the output voltage appearing at the connection between the detection coil of the second arm and the resistor is detected by a differential amplifier to obtain a torque signal.
[0004]
[Problems to be solved by the invention]
In the torque sensor having the above-described configuration, a pair of detection coils and a resistor are connected on a printed wiring board so as to form a bridge circuit. The detection coil and printed wiring board are connected by soldering, etc., but if the connection is not made securely due to poor soldering, contact resistance is generated between the detection coil or resistor and the printed wiring board, which is inaccurate. There is a disadvantage that a large torque signal is output.
[0005]
The present invention monitors the increase in contact resistance between the above-described detection coil or resistor and the printed circuit board. If the contact resistance increases, the detection torque signal is prevented from being output and an inaccurate torque signal is generated. An object of the present invention is to provide a highly reliable torque sensor that prevents output.
[0006]
[Means for Solving the Problems]
SUMMARY OF THE INVENTION The present invention solves the above-mentioned problems, and the invention according to claim 1 is configured so that each of the pair of detection coils and the pair of resistors whose impedances change in opposite directions according to the torque generated on the rotating shaft are individually provided. In a torque sensor that applies an alternating voltage to a bridge circuit connected in series to the bridge circuit and detects torque based on a differential voltage of the alternating voltage appearing at the terminal portions of the pair of detection coils, the waveform of the applied alternating voltage and the pair A monitoring circuit that detects a phase difference from the waveform of the difference of the AC voltage appearing at the detection coil terminal and determines that the detection coil resistance is abnormal when the phase difference exceeds a predetermined value. To do.
[0007]
The abnormality in the detection coil resistance includes an increase in contact resistance between the pair of detection coils and the pair of resistors.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. The embodiment described below is an example in which the torque sensor according to the embodiment of the present invention is applied to an electric power steering device for a vehicle.
[0009]
FIG. 1 is a cross-sectional view showing a configuration of a main part of an electric power steering apparatus including a torque detector, and FIG. 2 is a perspective view showing a configuration of the torque detector.
[0010]
1 and 2, reference numerals 5a and 5b denote housings, which have a two-part structure of an input shaft side 5a and an output shaft side 5b. Inside the housings 5a and 5b, an input shaft 1, a torsion bar 3 disposed therein, and an output shaft 2 connected to the input shaft 1 through the torsion bar 3 are rotated by bearings 6a, 6b and 6c. It is supported freely.
[0011]
The input shaft 1, the torsion bar 3, and the output shaft 2 are arranged coaxially. The input shaft 1 and the torsion bar 3 are spline-coupled, and the torsion bar 3 and the output shaft 2 are also spline-coupled. In FIG. 1, a steering wheel (not shown) is integrally attached to the left end side of the input shaft 1. Further, a pinion shaft 2a is formed integrally with the output shaft 2, and the pinion shaft 2a meshes with a rack 4 to constitute a known rack and pinion type steering mechanism.
[0012]
A worm wheel 7 that is coaxial with the output shaft 2 and rotates integrally therewith is fixed to the output shaft 2 and meshes with a worm 8 that is driven by an electric motor (not shown). The worm wheel 7 has a synthetic resin tooth 7b integrally fixed to a metal hub 7a. The rotational force of the electric motor is transmitted to the output shaft 2 via the worm 8 and the worm wheel 7, and a steering assist torque in an arbitrary direction is applied to the output shaft 2 by appropriately switching the rotation direction of the electric motor.
[0013]
Next, the configuration of the torque detector of the torque sensor will be described with reference to FIGS. The torque detection unit includes a sensor shaft portion 11 formed on the right end side in FIG. 1 of the input shaft 1, detection coils 13 and 14 disposed inside the housing 5a, and a cylindrical member 12 disposed therebetween. Composed.
[0014]
FIG. 2 is a perspective view showing the configuration of the torque detector. A sensor shaft portion 11 made of a magnetic material is formed on the outer side of the input shaft 1 near the right end in FIG. 1, and a plurality of (in the illustrated example, axially extending) surfaces are formed on the surface of the sensor shaft portion 11. Nine) ridges 11a are formed at equal intervals along the circumferential direction, and groove portions 11b wider than the width t1 of the ridges 11a are formed between the ridges 11a.
[0015]
Further, on the outside of the sensor shaft portion 11, a cylindrical member 12 made of a conductive and non-magnetic material, for example, aluminum, which is close to the sensor shaft portion 11, is arranged coaxially with the sensor shaft portion 11, The extension 12 e of the cylindrical member 12 is fixed to the outside of the end 2 e of the output shaft 2.
[0016]
The cylindrical member 12 includes a plurality (9 in FIG. 2) of rectangular windows 12a arranged at equal intervals in the circumferential direction at positions facing the protrusions 11a on the surface of the sensor shaft portion 11 described above. A plurality of (9 in FIG. 2) rectangular windows having the same shape as the window 12a but having different phases in the circumferential direction at positions shifted in the axial direction from the first window row. And a second window row made of 12b.
[0017]
The outer periphery of the cylindrical member 12 is surrounded by a yoke 15 around which detection coils 13 and 14 of the same standard are wound. That is, the detection coils 13 and 14 are arranged coaxially with the cylindrical member 12, the detection coil 13 surrounds the first window row portion formed of the window 12a, and the detection coil 14 includes the second window row portion formed of the window 12b. Siege. The yoke 15 is fixed inside the housing 5a, and the output lines of the detection coils 13 and 14 are connected to a circuit board 16 arranged inside the housing 5a.
[0018]
FIGS. 3A and 3B are views for explaining the protrusions on the surface of the sensor shaft portion and the window arrangement of the cylindrical member. FIG. 3A is a reference position (a state where the torsion bar 3 is not twisted). 3 shows the positional relationship between the projections 11a on the surface of the sensor shaft portion 11 and the windows 12a of the first window row of the cylindrical member 12, and FIG. 3 (b) shows a reference position (a state where the torsion bar 3 is not twisted). 3 is a diagram showing a positional relationship between a convex strip 11a on the surface of a sensor shaft portion 11 and a window 12b of a second window row of a cylindrical member 12. FIG.
[0019]
In this embodiment, since nine windows 12a and 12b are provided, respectively, the window 12a of the first window row and the window 12b of the second window row are each angle θ = 360 / N degrees in the circumferential direction ( In the example of FIGS. 2 and 3, the angle θ is shifted by 360/9 = 40 degrees.
[0020]
The angle a of the windows 12a and 12b is set smaller than the angle b of the portion without the windows 12a and 12b (a <b), and the angle c of the ridge 11a is set smaller than the angle d of the groove 11b (c <d). Is done. This is to make the change in impedance of the detection coil steep.
[0021]
As apparent from FIGS. 3A and 3B, when the torsion bar 3 is not twisted, that is, when the steering torque is zero (0), the sensor shaft is located at the center of the circumferential width of the window 12a. So that one end in the circumferential direction of the ridge 11a of the portion 11 is located and the other end in the circumferential direction of the ridge 11a is located in the center of the circumferential width of the window 12b. The circumferential width of 12a and 12b, the width of the ridge 11a, and the relative positional relationship in the circumferential direction between the windows 12a and 12b are set. That is, the positional relationship in the circumferential direction of the windows 12a and 12b with respect to the ridge 11a is opposite to each other.
[0022]
When the steering system is straight and the steering torque is zero, the torsion bar 3 is not twisted, and the input shaft 1 and the output shaft 2 do not rotate relative to each other. Therefore, relative rotation does not occur between the protrusion 11a on the surface of the sensor shaft portion 11 on the input shaft 1 side and the cylindrical member 12 on the output shaft 2 side.
[0023]
On the other hand, when a rotational force is applied to the input shaft 1 by operating the steering wheel, the rotational force is transmitted to the output shaft 2 via the torsion bar 3. At this time, a frictional force such as a frictional force between the steered wheel and the road surface or a meshing gear of a steering mechanism coupled to the output shaft 2 acts on the output shaft 2. Torsion occurs between the torsion bars connecting the two, and a relative rotation occurs between the projection 11a on the surface of the sensor shaft portion 11 on the input shaft 1 side and the cylindrical member 12 on the output shaft 2 side.
[0024]
When the cylindrical member 12 has no window, the cylindrical member 12 is made of a conductive and nonmagnetic material. Therefore, when an alternating current is generated in the detection coils 13 and 14 to generate an alternating magnetic field, the cylindrical member 12 Eddy currents in the direction opposite to the coil current are generated on the outer peripheral surface. When the magnetic field due to the eddy current and the magnetic field due to the coil current are superimposed, the magnetic field inside the cylindrical member 12 is canceled out.
[0025]
When a window is formed on the cylindrical member 12, the eddy current generated on the outer peripheral surface of the cylindrical member 12 cannot circulate around the outer peripheral surface by the windows 12a and 12b, so that the cylinder is formed along the end surfaces of the windows 12a and 12b. It wraps around the inner peripheral surface side of the member 12, flows in the same direction as the coil current, returns to the outer peripheral surface side along the end surfaces of the adjacent windows 12a and 12b, and forms a loop. That is, a state occurs in which eddy current loops are periodically arranged in the circumferential direction inside the detection coil.
[0026]
The magnetic field generated by the coil current and the magnetic field generated by the eddy current are superimposed, and a magnetic field that periodically changes in strength in the circumferential direction and a magnetic field having a gradient in the radial direction that decreases toward the center are formed inside and outside the cylindrical member 12. It is formed. The strength of the periodic magnetic field in the circumferential direction is strong at the center of the windows 12a and 12b affected by the adjacent eddy currents, and becomes weaker as it deviates from the center.
[0027]
A sensor shaft portion 11 made of a magnetic material is coaxially arranged inside the cylindrical member 12, and the ridges 11a are arranged at the same cycle as the windows 12a and 12b.
[0028]
A magnetic material placed in a magnetic field is magnetized to generate a magnetic flux, but the amount of magnetic flux increases according to the strength of the magnetic field until it is saturated. For this reason, the magnetic flux generated in the sensor shaft portion 11 by the cylindrical member 12 due to the strength of the periodic magnetic field in the circumferential direction and the magnetic field having a radial gradient that decreases toward the center is generated between the cylindrical member 12 and the sensor. It increases or decreases depending on the relative phase with the shaft portion 11.
[0029]
The phase at which the magnetic flux is maximum is such that the centers of the windows 12a and 12b of the cylindrical member 12 and the center of the ridge 11a of the sensor shaft portion 11 coincide with each other, and the inductances of the detection coils 13 and 14 according to the increase and decrease of the magnetic flux. Increase / decrease and change to a substantially sinusoidal shape.
[0030]
In the state where torque does not act, the center of the ridge 11a of the sensor shaft portion 11 is the ridge 11a with respect to the phase where the inductance is maximum (the phase where the windows 12a and 12b coincide with the center of the ridge 11a). Since the torque acts to twist the torsion bar 3 and a phase difference occurs between the sensor shaft portion 11 and the cylindrical member 12, One of the inductances of the detection coils 13 and 14 increases and the other decreases.
[0031]
FIG. 4 is a diagram for explaining the magnitude of torque and the change in inductance of the detection coils 13 and 14, where the horizontal axis indicates the torque T and the vertical axis indicates the inductance L. When the right steering torque is generated, the cylindrical member 12 rotates clockwise in FIGS. 3A and 3B. Therefore, as shown in FIG. 4, the inductance L13 of the detection coil 13 increases as the torque increases. The inductance L14 of the detection coil 14 decreases.
[0032]
In addition, when the left steering torque is generated, the cylindrical member 12 rotates counterclockwise in FIGS. 3A and 3B, so that the inductance L13 of the detection coil 13 increases as the torque increases as shown in FIG. As a result, the inductance L14 of the detection coil 14 increases.
[0033]
FIG. 5 is a block diagram of the torque detection circuit. The torque detection circuit 20 is connected to a control device (not shown) via a connector 29, and the power supply voltage V and the reference voltage Vref are supplied to each circuit element from the control device via the noise filter 28, and the detected main detection torque signal and A sub detection torque signal is output to the control device.
[0034]
The bridge circuit for detecting torque includes a first arm in which the detection coil 13 and the resistor R1 are connected in series, and a second arm in which the detection coil 14 and the resistor R2 are connected in series.
[0035]
The oscillating unit 21 is supplied with the power supply voltage V and the reference voltage Vref and outputs an AC voltage having a predetermined frequency. The output AC voltage is amplified by the current amplifying unit 22, and the amplified AC voltage Vosc is generated by the first arm of the bridge circuit composed of the detection coil 13 and the resistor R1, and the detection coil 14 and the resistor R2. It is supplied to the second arm of the constructed bridge circuit. It should be noted that the values of the resistors R1 and R2 are adjusted in advance so that the voltages appearing at both ends of the detection coils 13 and 14 are equal when no torque is applied.
[0036]
The voltage signals appearing at both ends of the detection coil 13 and the detection coil 14 are converted and amplified and rectified by the main amplification / full-wave rectification unit 23 into a difference signal between both detection coils, and the main smoothing / neutral adjustment unit 26. After the output waveform is adjusted, the signal is output to the control device through the noise filter 28 as a main detection torque signal.
[0037]
Further, the voltage signals appearing at both ends of the detection coil 13 and the detection coil 14 are converted and amplified and rectified by the sub-amplification / full-wave rectification unit 24 by being converted into a difference signal Vdef between both detection coils, and further sub-smooth / neutral. After the output waveform is adjusted by the adjustment unit 27, it is output to the control device through the noise filter 28 as a sub detection torque signal.
[0038]
Two sets of torque detection circuits 20 including a main amplification / full wave rectification unit 23 and a main smoothing / neutral adjustment unit 26 and a sub amplification / full wave rectification unit 24 and a sub smoothing / neutral adjustment unit 27 are provided. The reason for outputting the signal is to detect disconnection or short circuit of the detection coil, failure of the circuit element, or the like by comparing these two sets of signals in a control circuit (not shown).
[0039]
In the torque detection circuit 20, a monitoring unit 25 is provided between the sub amplification / full wave rectification unit 24 and the sub smoothing / neutral adjustment unit 27. The monitoring unit 25 detects a contact failure between the detection coil 13 or 14 and the resistor R1 or R2 by increasing the contact resistance. Hereinafter, the configuration and operation of the monitoring unit 25 will be described.
[0040]
FIG. 6 is a block diagram of the monitoring unit 25 and its peripheral circuits. The sub-amplification / full-wave rectification unit 24 includes an operational amplifier OP1 and a synchronous detector SR. The reference voltage Vref is connected to the input side (+) terminal of the operational amplifier OP1, and the output of the operational amplifier OP1 is fed back to the input side (−) terminal of the operational amplifier OP1 through the resistor R5.
[0041]
The voltage appearing at both ends of the detection coils 13 and 14 is input to the input side (+) terminal of the operational amplifier OP1 and the input side (−) terminal of the operational amplifier OP1 through the capacitor C3, the resistor R3, the capacitor C4, and the resistor R4, and the difference between them. The signal Vdef is output.
[0042]
The output signal Vdef of the operational amplifier OP1 is further rectified in synchronization with the alternating current output from the oscillation unit 21 supplied via the current amplification unit 22 in the synchronous detector SR, and output to the sub-smoothing / neutral adjustment unit 27 in the subsequent stage. Is done.
[0043]
The sub-smoothing / neutral adjustment unit 27 includes an operational amplifier OP2, a capacitor C5, and a resistor R9. A reference voltage Vref is connected to an input side (+) terminal of the operational amplifier OP2 through a resistor R8, and an input side of the operational amplifier OP2 The output of the synchronous detector SR is supplied to the (−) terminal via a resistor R7. The output of the operational amplifier OP2 is fed back to the input side (-) terminal via the capacitor C5 and the resistor R9, and the detected torque signal is output after being smoothed and adjusted in waveform.
[0044]
The monitoring unit 25 includes two comparators CP1 and CP2 and a transistor TR. Between the output side of the comparators CP1 and CP2 and the base of the transistor TR, a resistor R10 connected to a constant voltage Vcc, a resistor R11, A resistor R12 and a capacitor C6 are inserted.
[0045]
The AC voltage Vosc output from the oscillator 21 via the current amplifier 22 is input to the input (+) terminal of the comparator CP1, and the reference voltage Vref is input to the input (−) terminal. Further, the output signal Vdef of the operational amplifier OP1 is inputted to the input side (+) terminal of the comparator CP2, and the AC voltage Vosc outputted from the oscillation unit 21 is inputted to the input side (−) terminal. The outputs of the comparators CP1 and CP2 are combined, and the combined waveform is input to the base of the transistor TR.
[0046]
FIG. 7 is a diagram showing input waveforms and output waveforms of the comparators CP1 and CP2 during normal and abnormal times, and a combined waveform of the outputs of the comparators CP1 and CP2. The normal state refers to a state where there is no contact failure between the detection coil 13 or 14 and the resistor R1 or R2, and the abnormal state refers to a state where contact failure occurs and the contact resistance increases. Hereinafter, the normal operation and the abnormal operation will be described with reference to FIG.
[0047]
First, normal operation will be described. Since there is no contact failure between the detection coil 13 or 14 and the resistor R1 or R2 at the normal time (no abnormality occurs), the voltages appearing at both ends of the detection coils 13 and 14 are equal and there is no phase shift. The operational amplifier OP1 outputs a reference voltage Vref (sine wave).
[0048]
The AC voltage Vosc output from the oscillator 21 via the current amplifier 22 is input to the input side (+) terminal of the comparator CP1, and the reference voltage Vref is input to the input side (−) terminal of the comparator CP1. The input waveform is a sine wave, and the output waveform at this time is a positive potential rectangular waveform.
[0049]
Further, the output signal Vdef (sine wave) of the operational amplifier OP1 is input to the input side (+) terminal of the comparator CP2, and the AC voltage output from the oscillation unit 21 via the current amplification unit 22 is input to the input side (−) terminal. Since Vosc is input, all of the input waveforms are sine waves, and the output waveform at this time is a rectangular waveform with a negative potential, which is in phase with the output waveform of the comparator CP1.
[0050]
Accordingly, the combined waveform of the outputs of the comparators CP1 and CP2 has no phase shift between the output waveforms, and the positive potential and the negative potential cancel each other so that the output becomes zero. Therefore, the base of the transistor TR has a constant voltage Vcc. Is applied, and the transistor TR is kept in the OFF state. The OFF state of the transistor TR means that the control signal at the time of abnormality detection is not output from the monitoring unit 25.
[0051]
Since the monitoring unit 25 has not detected an abnormality and the transistor TR is OFF, the reference voltage Vref is applied to the input side (+) terminal of the operational amplifier OP2 of the sub-smoothing / neutral adjustment unit 27. The output of the sub-amplification / full-wave rectification unit 24 input to the (−) terminal is output through the operational amplifier OP2.
[0052]
Next, the operation at the time of abnormality will be described. When an abnormality occurs, a contact failure occurs between the detection coil 13 or 14 and the resistor R1 or R2 and the contact resistance increases (occurrence of abnormality), so that the detection coil 13 or 14 has an apparent increase in pure resistance. Since the impedance of the detection coil 13 or 14 increases, the operational amplifier OP1 outputs a signal whose phase is shifted as compared with the phase of the output signal at the normal time.
[0053]
Since the AC voltage Vosc output from the oscillation unit 21 via the current amplification unit 22 is applied to the input side (+) terminal of the comparator CP1, and the reference voltage Vref is applied to the input side (−) terminal, the input waveform is a sine wave. The output waveform at this time is a rectangular waveform with a positive potential. This point is the same as normal.
[0054]
The AC voltage Vosc output from the oscillator 21 through the current amplifier 22 is applied to the input side (−) terminal of the comparator CP2, and the output Vdef (sine wave) of the operational amplifier OP1 is input to the input side (+) terminal. However, as described above, since the impedance of the detection coil 13 or 14 is increased, the output waveform of the comparator CP2 is a rectangular waveform having a negative potential, but a phase shift occurs between the output waveform of the comparator CP1. doing.
[0055]
Accordingly, the combined waveform of the outputs of the comparators CP1 and CP2 outputs a rectangular waveform having a width corresponding to the phase shift between the output waveforms, which is applied to the base of the transistor TR, and the transistor TR is turned on (conducting state). It becomes. The ON state of the transistor TR means that the control signal at the time of abnormality detection is output from the monitoring unit 25.
[0056]
When the monitoring unit 25 detects an abnormality and the transistor TR is turned on (conductive state), the input side (+) terminal of the operational amplifier OP2 of the sub-smoothing / neutral adjustment unit 27 is grounded. The output of the input sub-amplifier / full-wave rectifier 24 is not output via the operational amplifier OP2. That is, when a circuit abnormality occurs such that a contact failure occurs between the detection coil 13 or 14 and the resistor R1 or R2 and the contact resistance increases, the output of the detected torque is prohibited.
[0057]
Next, a second embodiment of the monitoring unit will be described. The monitoring unit according to the second embodiment has a predetermined time before and after the point where the AC voltage (sine wave) output from the oscillation unit 21 intersects its midpoint (points of 0 ° and 180 ° of the sine wave). When the difference signal Vdef of the output signals appearing at both ends of the detection coils 13 and 14 within the width tm exceeds a predetermined voltage value Vref3, the phase difference from the AC voltage output from the oscillator 21 is an allowable value. It is judged that an abnormality has occurred beyond this point.
[0058]
FIG. 8 is a circuit block diagram showing a second embodiment of the monitoring unit described above, and can be replaced with the monitoring unit 25 described above.
[0059]
In the vicinity of the monitoring unit 30 of the second embodiment, the first arm in which the detection coil 13 and the resistor R1 are connected in series, the detection coil 14, and the resistor R2 described above are connected in series. The torque detection bridge circuit composed of the second arm, the oscillation unit 21, the current amplification unit 22, the sub-amplification / full-wave rectification unit 24, and the sub-smoothing / neutral adjustment unit 27 are connected to these circuit units. The configuration and operation of the monitoring unit 30 are the same as those described above, so the description thereof is omitted here, and the monitoring unit 30 will be described below.
[0060]
The monitoring unit 30 includes three comparators CP11, CP12, and CP13, an AND circuit AN that is an AND circuit, a transistor TR, and a resistor R10 that is a circuit element, a resistor R11, a resistor R12, and a capacitor C6. .
[0061]
The AC voltage Vosc output from the oscillation unit 21 via the current amplification unit 22 is input to the input side (+) terminal of the comparator CP11, and the first reference voltage Vref1 is input to the input side (−) terminal. The second reference voltage Vref2 is input to the input side (+) terminal of the comparator CP12, and the AC voltage Vosc output from the oscillation unit 21 via the current amplification unit 22 is input to the input side (−) terminal. The outputs of the comparators CP11 and CP12 are combined and input to the first input terminal of the AND circuit AN.
[0062]
The third reference voltage Vref3 is input to the input side (+) terminal of the comparator CP13, and the output signal Vdef of the operational amplifier OP1 of the sub-amplification / full-wave rectification unit 24 is input to the input side (−) terminal. The output of the comparator CP13 is input to the second input terminal of the AND circuit AN.
[0063]
The output terminal of the AND circuit AN is connected to the base of the transistor TR via the resistor R11. When the AND circuit AN is turned on, the signal makes the transistor TR conductive.
[0064]
Hereinafter, the operation of the monitoring unit 30 will be described with reference to FIGS. 9 and 10. First, a rectangular wave signal having a predetermined time width tm is prepared for determining the timing for executing abnormality detection.
[0065]
That is, the AC voltage Vosc is input to the input side (+) terminal of the comparator CP11, the first reference voltage Vref1 is input to the input side (−) terminal, and the second side is input to the input side (+) terminal of the comparator CP12. The reference voltage Vref2 is input, and the AC voltage Vosc is input to the input side (−) terminal. The output waveforms of the comparators CP11 and CP12 and their combined output waveforms are as shown in FIG. 9, and a signal having a predetermined time width tm is obtained by combining the outputs of the comparators CP11 and CP12. As described above, this signal is input to the first input terminal of the AND circuit AN (see FIG. 8).
[0066]
Next, in order to determine whether or not the difference signal between the output signals appearing at both ends of the detection coils 13 and 14 is equal to or less than a predetermined voltage value Vref3, the input side (+) terminal of the abnormality detection comparator CP13 becomes a determination criterion. The reference voltage Vref3 is input, and the output signal Vdef of the operational amplifier OP1 of the sub-amplification / full-wave rectification unit 24 is input to the (−) terminal. This signal is input to the second input terminal of the AND circuit AN (see FIG. 8).
[0067]
The normal operation will be described with reference to FIG. Under normal conditions, the output signal Vdef of the operational amplifier OP1 has no phase shift and does not become lower than the reference voltage Vref3, so that the output of the comparator CP13 becomes zero (0). Since the AND circuit AN takes the logical product of the output signal of the comparator CP13 and the signal of the predetermined time width tm (the combined output of the comparators CP11 and CP12), the output of the AND circuit AN is also turned off (0), and the transistor TR is in the conductive state. Thus, it is detected that no abnormality has occurred.
[0068]
Next, the operation at the time of abnormality will be described with reference to FIG. When a phase shift occurs in the output signal Vdef of the operational amplifier OP1, and it falls below the reference voltage Vref3 within a predetermined time width tm, it is determined that an abnormality has occurred.
[0069]
The comparator CP13 outputs (1) when the output signal Vdef of the operational amplifier OP1 is lower than the reference voltage Vref3, and outputs (0) when the output signal Vdef of the operational amplifier OP1 is higher than the reference voltage Vref3.
[0070]
In the AND circuit AN, a logical product of the output signal of the comparator CP13 and a signal having a predetermined time width tm (combined output of the comparators CP11 and CP12) is obtained, so that the output of the comparator CP13 is a reference voltage within the range of the predetermined time width tm. When Vref3 or less, the transistor TR is turned on (1), and during this period, the transistor TR is in a conducting state, and it is detected that an abnormality has occurred.
[0071]
In addition, the circuit configuration of the monitoring unit described in the first and second embodiments described above is an exemplification, and various other modified circuits having the same function are conceivable. Such a modified circuit is within the scope of circuit design that can be easily implemented by those skilled in the art, and the present invention is not limited to the illustrated circuit configuration.
[0072]
The example in which the torque sensor according to the embodiment of the present invention is applied to an electric power steering device for a vehicle has been described above. However, the torque sensor of the present invention is a torque in various mechanical devices other than the electric power steering device for a vehicle. Needless to say, the present invention can also be applied to a detection device.
[0073]
【The invention's effect】
As described above, the present invention provides alternating current to a bridge circuit in which each of a pair of detection coils whose impedances change in opposite directions according to the torque generated on the rotating shaft and each of the pair of resistors are individually connected in series. In a torque sensor that applies a voltage and detects torque based on a difference between AC voltages appearing at the terminal portions of the pair of detection coils, the contact failure of the contact portion between the detection coil that detects torque and another circuit element Since the detection is based on the occurrence of a phase difference between the difference waveform of the AC voltage appearing on the detection coil terminal of the contact coil, the contact failure of the contact portion between the detection coil and other circuit elements is detected with a simple configuration. And a highly reliable torque sensor can be provided.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a configuration of a main part of an electric power steering apparatus.
FIG. 2 is a perspective view showing a configuration of a torque sensor of the electric power steering apparatus.
FIG. 3 is a diagram for explaining the protrusions on the surface of the sensor shaft and the window arrangement of the cylindrical member.
FIG. 4 is a diagram for explaining changes in the magnitude of torque and the inductance of two detection coils.
FIG. 5 is a block diagram of a torque detection circuit.
FIG. 6 is a block diagram of a monitoring unit and its peripheral circuits.
7A and 7B are diagrams for explaining input waveforms, output waveforms, and output composite waveforms of comparators CP1 and CP2 when normal and abnormal.
FIG. 8 is a circuit block diagram showing a second embodiment of the monitoring unit.
FIG. 9 is a view for explaining generation of a signal having a predetermined time width tm.
FIG. 10 is a diagram for explaining a combined waveform of comparators CP11 and CP12, an output waveform of a comparator CP13, and an output waveform of an AND circuit at normal time and abnormal time;
[Explanation of symbols]
1 Input shaft
2 Output shaft
3 Torsion bar
4 racks
5a, 5b housing
6a, 6b, 6c Bearing
7 Worm wheel
8 Worm
11 Sensor shaft
11a ridge
11b Groove
12 Cylindrical member
12a window (of the first window row)
12b Window (second window row)
13, 14 Detection coil
15 York
16 Circuit board
20 Torque detection circuit
21 Oscillator
22 Current amplifier
23 Main amplification and full wave rectification
24 Sub-amplification / Full-wave rectifier
25 Monitoring unit
26 Main smoothing / neutral adjustment section
27 Sub-smooth / neutral adjustment section
28 Noise filter
30 Monitoring unit
R1 and R2 resistance
SR synchronous detector
OP1, OP2 operational amplifier
CP1, CP2 comparator
CP11, CP12, CP13 comparator
AN AND circuit
TR transistor

Claims (2)

An AC voltage is applied to each of a pair of detection coils whose impedances change in opposite directions according to torque generated on the rotating shaft and a pair of resistors individually connected in series, and the pair of detections In a torque sensor that detects torque based on the difference in AC voltage that appears at the terminal of the coil,
A phase difference between the waveform of the applied AC voltage and the waveform of the differential voltage of the AC voltage appearing at the pair of detection coil terminal portions is detected, and the detection coil resistance is abnormal when the phase difference exceeds a predetermined value. A torque sensor comprising a monitoring circuit for determining The torque sensor according to claim 1, wherein the abnormality in the detection coil resistance includes an increase in contact resistance between the pair of detection coils and the pair of resistors.

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