KR900000660Y1 - Brushless motor - Google Patents

Abstract

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Description

Motor detection device

1 is a plan view of the motor.

2 is a cross-sectional view thereof.

3 is a perspective view of a rotation position detecting member.

4 is a plan view of the rotation speed detecting member.

5 and 6 are explanatory diagrams showing a detection apparatus of a conventional motor.

7 is a diagram showing a detection signal by the detection device of the motor.

* Explanation of symbols for main parts of the drawings

11 Base 13 Fusible Substrate

13a: lead portion of fusible substrate 14: stator coil

15: rotation position detecting member 17: fixing screw

18: output terminal 34: rotor

35: magnet for rotation drive 36: magnet for rotation speed detection

The present invention relates to a motor used as a driving source for a rotating head device of a VTR, and more particularly, to an apparatus for magnetically detecting a rotation position of a rotor.

A thin brushless motor is used as a driving source for a rotating head device of a VTR.

In this type of motor, a rotation speed detection member is provided to detect the rotation speed of the rotor and to control the rotation speed.

5 and below show the principle of this type of brushless motor and the principle of each detection member.

The rotor magnet is installed in the rotor of the brushless motor. This rotor magnet 1 is provided with the drive magnetization part 1a of an outer peripheral part, and the rotation detection part magnetization part 1b for an inner peripheral part.

In the magnetizing portion 1a for driving, they are alternately formed in the rotational direction. In the rotation detection magnet part 1b, the N pole and the S pole are alternately arranged at a short pitch.

Moreover, the magnetic pole 2 for detecting a rotation position is provided in the outer peripheral part of the rotor magnet 1. The magnetic poles 2 for detecting the rotational position are provided at two places at intervals of 180 degrees, one side of which is an N pole and the other is an S pole.

On the fixed side of the motor, a plurality of stator coils indicated by the reference numeral 3 are arranged in the rotor rotation direction with the same pitch.

The rotational force acts on the rotor magnet 1 by the current flowing in the straight portion of the stator coil 3 and the magnetic field of the driving magnetizing portion 1a of the rotor magnet 1.

Moreover, the rotation speed detection member 4 and the rotation position detection opening part 5 are provided in the fixed shaft side. As shown in FIG. 6, the rotation speed detection member 4 is comprised by the conductor pattern in which the uneven | corrugated part was continuously shown. Normally, the rotation speed detection member 4 is formed on the soluble substrate and disposed on the stator coil 3. When the rotor magnet 1 rotates, a pulse current is generated in the rotation speed detection member 4 as the magnetic pole of the rotation speed detection magnetization part 1b moves.

Waveform shaping this pulsed current results in an output signal shown in FIG. 7A. When the rotor magnet 1 rotates so that the magnetic pole 2 for rotational position detection passes through the front of the rotational position detection member 5, a pulse current is output from the rotational position detection member 5 at that moment.

By waveform shaping this pulsed current, the signal shown in FIG. 7B is obtained. The signal shown in Fig. 7B is alternately outputted by a positive signal every 180 degrees in accordance with the passage of the magnetizing section 2 for rotational position detection.

By counting the pulse signal shown in FIG. 7A, the rotation speed of the rotor magnet 1 can be known. Moreover, the rotation position of the rotor magnet 1 can be known by the pulse signal shown in FIG.

When using this type of motor, the detection timing of the magnetic pole 2 for detecting the rotation position must be adjusted.

For example, in the VTR rotating ED device, the switching timing of the plurality of heads is set based on the pulse signal for detecting the rotational position.

As an example of this reference setting, the rising (a1, a2, a3 ...) of the pulse signal for rotation speed detection shown in FIG. have. As a reference for knowing the rise (a ₁ ) of the signal, the rise (b ₁ ) of the pulse signal for detecting the rotation position shown in FIG. 7 (b) is used. That is, the count is started on the basis of the rise a ₁ of the signal of (A) detected after the rise of the signal b ₁ .

In order to perform such control accurately, it is necessary to adjust so that the rising b1 of the pulse signal for detecting the rotational position of FIG. 7B always occurs between the rising a ₁₁ and a _j of the pulse signal shown in FIG. 7A.

Conventionally, the timing of the above-described pulse signal has been electrically adjusted by a delay circuit or the like provided in the rotating head device.

As a result, the circuit side of politics increased and the price increased.

As a method of adjusting the timing of the pulse signal without providing this delay circuit or the like, it is considered to adjust the position of the rotation position detecting member 5 in accordance with the rotation direction on the mechanism of the motor. However, the lead connected to the output terminal of the position detecting member 5 of the rotation position detecting member 5 must be formed with the same degree of freedom as the wire rod.

However, when a lead wire or the like is connected to the output terminal, the wiring space is required, and the overall motor becomes large in shape. In addition, there is a concern that the lead wire may impede the rotation operation of the rotor magnet 1.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described conventional problems, and by adjusting the position of the rotation position detecting member, it is possible to adjust the timing of generation of the rotation position detecting pulse signal, and the lead connected to the output terminal of the rotation position detecting member It is an object of the present invention to provide a detection device for a motor that allows deformation to be made of a simple and simple structure.

According to the present invention, a flexible substrate is installed on a base, and a stator coil is installed on the flexible substrate, and a rotor having a magnet on the stator coil is freely opposed to the rotor and rotates around the rotor. A motor detecting device having a magnetic pole for position detection and a rotational position detecting member opposed to the magnetic pole on the base, wherein the rotational position detecting member can be freely adjusted in accordance with the rotor rotation direction. In addition, a part of the flexible substrate is deformably connected to the rotational position detecting member, and the output terminal of the rotational position detecting member is connected to the conductor pattern on the flexible substrate.

In the present invention, the timing of the detection pulse at the rotational position of the rotor can be adjusted by moving the rotational position detecting member. Therefore, even if a circuit for timing adjustment of the pulse signal is not provided on the device side such as a rotating head device of the VTR, Therefore, the circuit burden can be reduced. In addition, since a part of the flexible board for installing the stator coil is used as a lead for drawing the output of the rotation position detecting member, there is no need to install the lead wire of the rotation position detecting member, thus simplifying the wiring structure and assembling. Lose.

Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 to 4.

FIG. 1 is a plan view showing the structure of the motor, FIG. 2 is a sectional view of FIG. 1, FIG. 3 is a perspective view showing a rotation position detecting member, and FIG. 4 is a plan view showing a rotation speed detecting member.

FIG. 1 is a brushless motor used as a power source of a rotating head device of the VTR of the motor shown in FIG.

In the figure, reference numeral 11 denotes a base formed of a metal plate or the like.

The flexible substrate 13 is adhere | attached on the base 11, The stator coil 14 is provided on this flexible substrate 13. As shown in FIG.

A plurality of stator coils 14 are provided at equal intervals along the circumferential direction. Each stator coil 14 is wound in a substantially triangular shape along the surface of the flexible substrate 12, and a current flows in the radial direction of the base 11 at each straight portion 14a.

Moreover, the rotation position detection member 15 is provided on the base 11. The rotation position detecting member 15 is provided with a hall element 15a. The mounting plate 15b is integrally provided in the lower part of the rotation position detection member 15, and this mounting plate 15b is being fixed by the pin 16 and the fixing screw 17. As shown in FIG.

The pin 16 and the base 11 and the mounting plate 15b and the fixing screw 17 are engaged by a long hole. Loosen the fixing screw 17 to adjust the mounting position of the rotational position detecting member 15. It can be adjusted by moving in the direction of the arrow. In addition, a part of the flexible substrate 13 is provided with a lead portion 13a. The lead portion 13a is bent from the base 11, and the tip portion has a free portion A (see FIG. 3) that is free of deformation, and is connected to the output terminal 18 of the hall element 15a. . Although not shown in the drawing, a conductor pattern is provided in the lead portion 13a, and the output terminal 18 is soldered to the conductor pattern. The Hall element output current from the output terminal 18 is led out of the motor by the conductor pattern formed in the lead portion 13a and the main body of the flexible substrate 13.

On the stator coil 14, a rotation speed detecting board 21 is provided. As shown in FIG. 4, the detection pattern 21a is formed in this rotation speed detection board 21 by printing or the like. The detection pattern 21a is formed of an uneven portion 21b formed at a predetermined pitch.

Reference numeral 31 is a rotation axis. As shown in FIG. 2, the rotation 31 is freely supported by the bearing 33 with respect to the fixed side member 32. As shown in FIG. The rotor 34 is fixed to the front end of the rotating shaft 31. On the lower surface of the rotor 34, a magnet 35 for rotation driving and a magnet 36 for rotation speed detection are fixed.

In the magnet 35 for rotation driving, the N pole and the S pole are alternately arranged.

In the rotation speed detecting magnet 36, the N pole and the S pole are arranged at a short pitch toward the rotation direction. The magnet 35 for rotation drive opposes on the stator coil 14 with a small space | interval. Moreover, the magnet 36 for rotation speed detection opposes the detection pattern 21a of the said rotation speed detection board 21. As shown in FIG.

In addition, two magnets 37 for rotational position detection are fixed to the outer circumference of the rotor 34. The magnets 37 are arranged at intervals of 180 degrees, and each magnet 37 is a magnetic pole different from each other in the N pole and the S pole.

The position adjustment of the rotation position detecting member 15 in this motor is made by loosening the set screw 17 and moving it in the arrow direction along the rotation direction of the rotor 34. While moving the rotation position detecting member 15, the lead portion 13a of the flexible substrate 13 is stretched and contracted in accordance with the rotation position detecting member 15 by deforming the margin A. FIG.

The operation of the motor is performed by supplying a current to the stator coil 14. When a current flows through the stator coil 14, a rotational driving force acts on the rotor 34 by the current flowing in the radial direction in the straight portion 14a and the magnetic poles of the magnet 35 for the rotary tool fixed to the rotor 34. .

When the rotor 34 rotates, the signal shown in FIG. 7A is output from the detection pattern 21a of the rotation speed detection board 21 by the magnetic pole of the rotation detection magnet 36. Whenever the magnet 37 for rotation position detection fixed to the rotor 34 passes, the pulse signal shown in Fig. 7 (B) is output from the output terminal 18 of the rotation position detection member 15. do. This signal is derived from the output terminal 18 to the outside by a conductor pattern on the lead portion 13a and on the main body portion of the fusible engine 13.

By the position adjustment of the rotation position detection member 15, for example, the rise of the rotation position detection pulse signal (b ₁ ) shown in FIG. 7 (B) and the rise of the rotation speed detection pulse signal shown in (A) ( Adjustment such as timing with a ₀ and a) is performed.

In addition, although the magnet 35 for rotation drive, the magnet 36 for rotation speed detection, and the magnet 37 for rotation position detection are individually fixed to the rotor 34 in the embodiment of the figure, these magnets are integrated. The rotor may be configured.

According to the present invention as described above will have the following effects.

(1) Since the rotation position detecting member is free to move and a part of the flexible engine is used as the output lead of the rotation position detecting member, the wiring work is simpler than when using the conventional lead wire. In addition, the lead wire does not interfere with the rotation of the rotor.

(2) A part of the flexible substrate on which the stator coil is provided can form the output of the rotation position detecting member and the current supply lead to the stator coil on the common flexible substrate. Therefore, wiring can be unified, circuit processing becomes easy, and assembly is simplified.

(3) Since the timing of the detection signal can be adjusted by the motor itself by moving the rotation position detecting member, a circuit for adjusting the timing of the signal on the device side such as a rotating head device is unnecessary. Therefore, the circuit burden of an apparatus becomes small and price reduction can be aimed at.

Claims (1)

A flexible substrate is provided on the base, and a stator coil is installed on the flexible substrate, and a rotor having a magnet on the stator coil rotates freely to face each other, and a magnetic pole for detecting a rotation position is provided around the rotor. A motor detecting device provided with a rotational position detecting member opposed to the magnetic pole on the base, wherein the rotational position detecting member is mounted so as to freely adjust the position along the rotor rotational direction and is flexible. A part of the substrate is connected so as to be freely deformed with respect to the rotational position detecting member, and the output terminal of the rotational position detecting member is connected to the conductor pattern on the flexible substrate.