KR0133031B1 - Noise reduction speed signal(fg) detection pattern of rotating device - Google Patents

Abstract

The present invention relates to a noise attenuation speed signal (FG) detection pattern of a rotator. In the related art, since the detected three harmonic signals have a lot of noise, a filter must be used in a double triplet, which causes a cost increase. In view of this, the present invention has a phase opposite to the noise of the input / output line 11 in the three harmonic velocity FG detection pattern of the rotor formed to detect the velocity pulse FG corresponding to three times the pole pair in one rotation. The noise reduction speed signal (FG) detection pattern of the rotor is formed by additionally forming a predetermined inverse noise generation pattern 20 in which a reverse noise signal having the same magnitude as the noise of the input / output line 11 is generated at the angle at which the signal is generated. The noise canceling effect enables signal detection without noise, and eliminates the need for a separate filter.

Description

Noise Reduction Speed Signal Detection Pattern of Rotator

1 is a speed signal detection pattern diagram of a conventional rotating machine.

2 is a waveform diagram comparing three harmonics and a fundamental wave of a rotating machine.

3 is a waveform diagram according to a speed signal detection pattern of a conventional rotating machine.

4 is a speed signal detection pattern diagram of a rotating machine according to the present invention.

5 is a detailed view of the inverse noise generation pattern of FIG.

Figure 6 is a speed detection waveform diagram according to the pattern according to the present invention.

7 is a speed signal detection pattern diagram showing a modified embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: 3 harmonic detection pattern 11, 11 ': I / O line

20,20 ': Reverse noise generation pattern

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a speed signal (FG) detection pattern of a rotating machine. In particular, when detecting a speed (FG) signal and a phase (PG) signal using a pattern, an error is generated by inserting a pattern for generating an inverse error signal in advance. A noise attenuation speed signal (FG) detection pattern of a rotor for attenuating a signal. In general, in order to control the speed and phase of the rotor (motor), the speed and phase must be detected. As a method of detecting the speed and phase, the rotation speed and the phase can be detected using a sensor element such as a hall sensor and a photo interrupter. There is a method of detecting phase and a method of detecting rotation speed and phase by using an encoder and resolver. In a motor used for a very precise device, an encoder and a resolver are used, but an expensive There are disadvantages. Therefore, there is a cost problem in home appliances such as BBC, etc., and the economical efficiency is low, and in a very small and thin product (for example, MD), the space occupied by a rotor and an encoder is very large, and thus it is not suitable to be applied. In addition, as a rotation speed and phase detection method that is frequently used in small household appliances, many speed detection devices using Hall elements are used, but this is also a factor of cost increase due to the high price of Hall elements. Due to the size of the Hall element, there is a problem in use. Accordingly, in a small precision instrument, a signal pattern such as PG or FG is formed on the stator pattern to detect phase PG and rotational speed FG. Sensorless type rotors using such a pattern are difficult to control precisely at very low speeds (for example, 100 rpm or less), but they are not difficult to use in a commonly used speed range (for example, 500-4000 rpm). However, in the precision drive control using signals such as FG and PG of the sensorless rotor, it is a problem to obtain a very high resolution FG signal with high accuracy. In this way, a speed signal pulse that is half the number of poles in one rotation of the rotor, that is, an FG signal = number of poles / 2 can be obtained. As a result, FG pulses corresponding to the number of pole pairs per revolution can be obtained, and thus many devices have high use restrictions. Therefore, in recent years, the 3rd harmonic method which can obtain FG pulse of 3 times the number of pole pairs in one rotation is used a lot. FIG. 1 is a three harmonic velocity signal detection pattern diagram of a conventional rotor, and as shown therein, a velocity detection pattern 1 is formed to detect three pulse signals for each pole pair (two poles). According to such a three harmonic detection pattern, as shown in FIG. 2, the speed signal of three cycles can be detected for each pole pair corresponding to the fundamental wave which detects one cycle of signal for each pole pair. That is, three harmonics have three times as many cycles as fundamental waves having as many periods as pole pairs in one rotation, so that the magnitude is 1/3 and the frequency is tripled. Therefore, the detection of the speed signal by the 3rd harmonic is more affected by the noise than when the speed is detected by the fundamental wave, which is shown in FIG. 3 in the 3rd harmonic as the noise flows in the vicinity of the input / output line 2 of the pattern. As shown in the figure, three harmonic signals containing a lot of noise are detected. Therefore, the three harmonic detection method has a disadvantage in that an expensive filter having a separate pass band must be used in duplicate due to noise of the sensing input unit, that is, the FG and PG sensing noise, which is a sensorless maximum weakness. Accordingly, there is a problem that the economy is inferior due to additional additional costs. SUMMARY OF THE INVENTION In view of such a conventional problem, an object of the present invention is to add an inverse noise generation pattern corresponding to noise generated in a pattern signal line lead-out portion in a three harmonic emission pattern so that noise is attenuated, without using an expensive filter. The present invention also provides a noise attenuation speed signal (FG) detection pattern of a rotor capable of obtaining a precise speed detection pulse signal. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. 4 is a speed signal detection pattern diagram of the rotor according to the present invention. As shown therein, in the speed detection pattern formed to detect the speed pulse FG corresponding to three times the pole pair in one rotation, the input / output line 11 ) Is formed to a minimum thickness and distance d1, and a signal having the same magnitude as the noise of the input / output line 11 is generated at an angle at which a signal is out of phase with respect to the noise of the input / output line 11. The reverse noise generation pattern 20 of a predetermined shape is additionally formed. The reverse noise generation pattern 20 may be formed at a 30 ^o position with respect to the input / output line 11, but since the reverse noise generation pattern 20 may be affected by the input / output line 11 because it is too close to the input / output line 11, the input / output line It is preferable to form in the 90 ^degree position with respect to (11). In addition, the inverse noise generation pattern 20 is formed in a stepped manner as shown in FIG. 5, but the distance (a) with the neighboring pattern and the length (b) first bent toward the neighboring pattern are equal to each other. The distance d2 of the reverse noise generating pattern 20 and the thickness of the pattern are formed to be the same as the distance d1 and the thickness of the lead-out line 11. Here, the minimum means the minimum thickness capable of inputting and outputting an electrical signal and forming a conductor in a pattern, and may configure the interval and thickness by about 0.15 mm. According to the three harmonic generation pattern according to the present invention configured as described above, the inverse noise generation pattern 20 is formed at a position of 90 ^° with respect to the input / output line 11, and the inverse noise generation pattern 20 is formed in the input / output line. A signal having the same magnitude and opposite phase as the noise generated in (11) should be obtained, but designing the pattern to minimize the noise generated in the input / output line 11 should be prioritized. Accordingly, the pattern is designed such that the distance d1 of the input / output line 11 is minimized, and is formed to be minimum with the thickness of the input / output line 11 to minimize the counter electromotive force (noise signal) induced in the input / output line 11. Reduce to In addition, the distance d2 of the reverse noise generation pattern 20 is reduced to a minimum, and the thickness of the pattern is also reduced to a minimum so that the noise generated in the input / output 11 can be canceled when the reverse noise occurs. Incidentally, the inverse noise generation pattern 20 is formed in a stepwise manner to prevent unnecessary noise from being generated when the inverse noise is generated, and the distance a between the neighboring pattern and the inverse noise generation pattern 20 and its The lengths (b) first bent toward the neighboring patterns are formed to be the same. If the intervals of a and b are not equal to each other, the noise generated in the inverse noise generation pattern 20 becomes a non-negligible noise, which adversely affects the signal-to-noise ratio (S / N ratio). It is preferable to form the distance d2 of the reverse noise generation pattern 20 and the thickness of the pattern to be the same as the distance d1 and the thickness of the lead-out line 11. Therefore, according to the speed detection pattern according to the present invention, noise such as counter electromotive force flowing in the input / output line 11 is attenuated by the antiphase noise signal generated in the reverse noise generation pattern 20, which is illustrated in FIG. As described above, a waveform with little influence of noise can be obtained as compared with the waveform diagram of the conventional pattern of FIG. Accordingly, conventionally, expensive filters are required as two of three types to remove noise. However, according to the present invention, as shown in FIG. 6 without using a separate filter, a three-frequency velocity detection waveform without the influence of noise can be obtained. Will be. FIG. 7 is a pattern diagram showing a modified embodiment of the present invention. As shown in FIG. 7, the one pattern is opened to draw out both edge lines, and the input and output lines 11 'are formed. A stepwise 90 ^° position inverse noise generation pattern 20 'is formed in a stepwise manner, but the distance (a) and the bent length (b) with neighboring patterns are the same, and the inverse noise generation pattern 20' ) Is configured to be equal to the distance D1 of the input / output line 11 '. In this modified embodiment, the noise attenuation phenomenon is generated by the same operation as in the embodiment shown in FIG. 4 to obtain a waveform as shown in FIG. However, since the distance D1 of the input / output line 11 'and the distance D2 of the inverse noise generation pattern 20' can be made wider than those of the exemplary embodiment, the manufacturing process is simplified. As described in detail above, according to the present invention, the noise of the speed detection signal FG is small so that a separate filter is not required, and even if it is used, the noise can be removed using only one filter, thereby reducing the cost. The speed change rate of the rotor can be reduced. This can be applied to the drum motor of small precision instruments such as camcorders, capstan motors and sensorless-type motors of V-Cal.

Claims (4)

In the three harmonic velocity (FG) detection pattern of the rotor formed so as to detect the velocity pulse (FG) corresponding to three times the pole pair in one rotation, it is formed at the 90 ^° position with respect to the input / output line 11 and is formed stepwise. In addition, an inverse noise generation pattern 20 having a predetermined shape in which an inverse noise signal having the same magnitude as the noise of the input / output line 11 is generated at an angle at which a signal in which a phase is reversed with respect to the noise of the input / output line 11 is added. And attenuating speed signal (FG) detection pattern of the rotating machine, characterized in that it is formed. The reverse noise generating pattern 20 is formed such that a distance a between a neighboring pattern and a length b firstly bent toward the neighboring pattern are equal to each other, and the reverse noise generating pattern is the same. And a distance d2 of (20) and a thickness of the pattern equal to the distance d1 and the thickness of the input / output line (11). The noise attenuation speed signal FG of the rotor according to claim 1, wherein the input and output lines 11 and the reverse noise generating pattern 20 have a thickness and a distance d1 and d2 of 0.15 mm, respectively. Detection pattern. The input / output line (11) according to claim 1, wherein the input / output line (11) is opened to draw out both edge lines to constitute the input / output line (11 '), and the position is reversed to 90 ^o with respect to the input / output line (11'). The noise generating pattern 20 'is formed in a stepped manner, but the distance a and the bent length b with the neighboring pattern are the same, and the distance D2 of the inverse noise generating pattern 20' is described above. A noise attenuation speed signal (FG) detection pattern of a rotor, characterized in that it is configured to be equal to the distance (D1) of the input / output line (11 ').