SU817895A1 - Rotor postion sensor - Google Patents

Description

(54) ROTOR POSITION SENSOR

The invention relates to electromechanics, in particular, to rotor position sensors of valve motors with position-dependent pulse-width modulation of phase voltages. A rotor position sensor is known, for example, for a contactless DC motor with regulation of the duration of control pulses, which contains alternating coils of primary and secondary windings on the stator teeth. The coils of the primary winding are connected in separate groups, separately regulated by. voltage, and the coils of the secondary winding are connected to phase-sensitive demodulators 1. A disadvantage of the rotor position sensor is a large discreteness in measuring the angular position of the rotor signal element. The closest in technical essence to the present invention is a magnetically-modulated angular position sensor, for example, a rotor of a contactless DC motor, containing inductive sensing elements and additional magnets installed in pairs on a stator with a fixed shear angle, and a rotating constant-magnet modulator. The sensor is equipped with a magnetic shunt mounted on the stator between the sensitive elements and the magnet-modulator, made of an even number of toroidal cores that are magnetically directed in opposite directions, carrying control windings 2. The main disadvantage of the sensor is its narrow functionality. The sensor works satisfactorily in the composition of the valve motor, ensuring the smoothness of the torque of the electric machine. At the same time, when using a magnetic modulation sensor as a source of information for devices measuring the rotational speed of valve electric motors, due to the sinusoidal shape of the envelope of the average component of its output voltage, significant pulsations of the tachometer signal occur, which limit the field of application of the sensor. Thus, contradictory requirements are imposed on the external characteristics of the device: a) for the valve

the best motor, from the viewpoint of obtaining a minimum of torque ripple, is the sinusoidal form of the external characteristic; b) for tachometric devices, the shape should approach that of a sawtooth, which makes it possible to reduce tacho signal pulsations.

The purpose of the invention is to extend the functionality of a magnetic modulating rotor position sensor.

This goal is achieved by the fact that the rotor position sensor, for example, for a valve motor, contains magnetic modulation sensitive elements, the windings of which are connected to the output of the power amplifier through the load resistors, the input of which is connected to the output of the reference frequency generator, and a signal element in the form of a permanent magnet The resistors are connected to series-connected rectifiers and a driver, the sensor is equipped with an additional two keys, two coincidence circuits, an inverter and an additional with an effective generator, the output frequency of which is twice as high as the reference frequency, the source of the reference frequency is made in the form of two master oscillators, one of which is designed to generate square-shaped voltage, and the other to generate a voltage of a variable form of the pulse top, moreover, two master oscillators are connected to the input of the power amplifier through two keys, one inputs of the matching circuits are connected to the driver output, and the second inputs are connected to the control inputs of the first and second switches and serially connected to the outputs of the additional generator and an inverter.

FIG. 1 shows a functional diagram of the device; in fig. 2 - graphs illustrating the principle of operation of the device.

The rotor position sensor, for example, for a valve electric motor, contains, in the case of a two-phase design, magnetic modulation sensitive elements 1 and 2, the windings of which are connected through the load resistors 3 and 4 to the output of the power amplifier 5, and the signal element b in the form of a permanent magnet, and the load resistors 3 and 4 are connected to series-connected rectifiers 7 and 8 and formers 9 and 10.

The sensor contains two master oscillators 13 and 14 connected to the power amplifier 5 through two switches 11 and 12, as well as in each phase two coincidence circuits 15, 16 and 17, 18, one inputs of which are connected to the output of the driver 9 and 10, and the second inputs are connected to the control inputs of the first 11 and second 12 keys and to the outputs of series-connected additional generator 19 and inverter 20. If the number of phases of the sensor is more than two, the same channels are added to the circuit, consisting of series-connected sensitive elements, ezistora, rectifier and conditioners, which are connected to the output of the first inputs of the two coincidence circuits, whose second inputs are connected to the additional generator and inverter outputs.

When the rotor signal element 6 is rotated, the degree of bias of the sensitive elements changes. 1 and 2, which causes corresponding changes in the duration of the current pulses in the load resistors 3 and 4. When the windings of the sensitive elements 1 and 2 are powered by rectangular voltage, the relative durations of the current pulses in the load resistors 3 and 4 depend on the rotation angle of the rotor 6 sinusoidal, shown in FIG. 3 lines TJ, ir, having a phase shift corresponding to the relative spatial arrangement of the sensitive elements 1 and 2.

The third generator 19 generates a square wave, the carrier frequency of which is twice lower than the frequencies of the generators 13 and 14. Through the inverter 20, the generator 19 controls the operation of the keys 11 and 12 and the matching circuits 15-18 so that in one half-period of the output voltage of the third generator 19 the first key is opened 11 and the matching schemes 15 and 17. In the second half period, the second key 12 and the matching schemes 16 and 18 are open, and the schemes 15 and 17 are closed. Therefore, in the first half period, the voltages of the third generator 19 are supplied to the sensitive elements via the power amplifier 5 by the voltage of the first generator 13, which is rectangular in shape. In this case, from the coincidence circuits 15 and 17, the pulse sequences V,, V – n come in, having sinusoidal laws for varying the duration from the angle oi. In the second half-period of the output voltage of the third generator 19, the elements 1 and 2 are supplied with voltage with a special form, and produced by the second generator 14. In this case, the pulses come from the outputs of the matching circuits 16 and 18. The output voltage of the second generator provides the desired the law of change with respect to the duration of the signals V | 6. Vjg from the angle o. So, for example, to increase the accuracy of devices measuring the rotational speed of a valve electric motor, it must be linear, which is achieved in the proposed position sensor circuit by selecting the appropriate shape of the change in the voltage pulse of the second generator 14.

When feeding sensing elements 1 and 2 with a meander type voltage having a flat top, the shape of the external characteristic is determined by the magnetic field induction distribution of the signal element - rotor (permanent magnet) along the sensor gap and depends on the angle, as shown by the fj curves, this duration the output signals of the sensor V | 5 is determined by the induction of the magnetic field of the rotor 6 at its certain angular position. The duration of these pulses is also determined by the volt-second area of the supply voltage of the sensing elements i and 2. Thus, if the volt-second area at a given rotor position is constant, then you can increase the duration of the pulses V (5) by decreasing the amplitude of the power supply. when the rotor 6 rotates, the duration of the signal Uzg decreases, its dependence on the angle o (has the form of the sine TJ, i.e., each section of the line-Сз corresponds to its “piece The power supply pulse is Vfj. Therefore, for example, where the sine is greater than the line (i.e., the signal must be shorter for the line), the power amplitude needs to be increased. In areas where the duration needs to be increased, i.e. sensor performance to the desired, it is necessary to reduce the amplitude of the power supply.

So, to form the desired sensor characteristic, it is necessary to determine the actual characteristic, display the desired one in the same drawing, and then deform the power supply pulse inversely proportional to the difference between the desired and actual sensor characteristics. A master oscillator for a sinusoidal characteristic, as is known, must generate a square wave (for example, oscillator 13). The second master oscillator (for example, 14) must be in the form of a pulse width, deformed in accordance with the procedure given above. Thus, for example, for the linear form of the Vt characteristic, the form Ush corresponds.

The shape of the pulse width of the generator 14 can be arbitrary. It all depends on the characteristics that must be obtained from the sine. For example, it is possible to obtain a relay characteristic in the form of a voltage y-iff in the form of a step.

In the general case, the rotor position sensor can produce several arbitrary laws for changing its output pulses depending on the rotation angle o (rotor 6. In this case, the number of master oscillators, keys, coincidence circuits must be increased accordingly, and the control circuit of these elements presented in Fig. 1, the third generator 19 and the inverter may be, for example, an annular pulse distributor.

So, in the position sensor circuit, by alternating the shapes of the supply voltage sensing elements, various laws of varying the relative duration of the output pulses depending on the angle of rotation of the rotor are developed. The noted property of the invention allows the use of one set of sensing elements for various purposes, for example, as a rotor motor position sensor of a valve motor, an information source for speed measuring devices of said engines, etc.

Claims (2)

1. USSR author's certificate number 313343, cl. H 02 K 29/02, 1971. 2. USSR author's certificate number 481968, cl. H 02 K 29/02, 1975. WIG