KR19990013038U - Switching noise elimination circuit of VCA capstan motor - Google Patents

Abstract

The present invention relates to a switching noise canceling circuit of a BC capstan motor, and a switching transistor connected to the emitter end of the capstan motor driving transistor to switch the driving voltage of the magnet coil, and an input current control connected to the base end of the switching transistor. An amplifier for amplifying and outputting a signal, and a clamping means connected between one end of the driving transistor and the magnet coil to crimp a switching noise pulse signal generated in the magnet coil, and generated at the magnet coil when the capstan motor is switched. Since the local voltage is clamped, the operation characteristics of the system are considerably improved, and the capstan motor driving circuit is prevented from being damaged due to the relatively simple circuit configuration, thereby reducing the manufacturing cost of the capstan motor.

Description

Switching noise elimination circuit of VCA capstan motor

The present invention relates to a switching noise elimination circuit of a VCA capstan motor, and in particular, by connecting a zener diode to a driving power input terminal applied to the magnet coil of the capstan motor, a western area voltage generated in the magnet coil when the capstan motor is switched. It is related to the switching noise cancellation circuit of V-Cal capstan motor, which greatly improves the operating characteristics of the system.

In general, the VRC system has a very small dimension of recording a video signal, a track width of about 0.2-0.02 mm, a recording wavelength of about several microns, and is recorded in the tape width direction. Therefore, during recording and playback, it is necessary to perform stable control of the head drum rotation so as not to change as the time axis of the video signal increases. In addition, in order to maintain tracking of the video track, it is necessary to maintain the head drum rotation and the tape running state (speed and positional relationship) as in recording.

In addition, referring to FIG. 1, the conventional driving circuit of the capstan motor of V-Cal as described above, the Hall sensor 71 detecting the rotation of the capstan motor 70 of the V-Cal, and the detection of the hall sensor 71. A NPN type detection transistor 72 which is turned on in response to a signal and performs a switching action, and a PNP connected to the collector terminal of the detection transistor 72 to control the driving current of the magnet coils 73A and 73B of the capstan motor 70. Type driving transistor 74, a switching transistor 75 connected to the emitter end of the driving transistor 74 to switch the driving voltage of the magnet coils 73A and 73B, and a base end of the switching transistor 75. And an amplifier 76 connected to amplify and output the input current control signal.

A microcomputer 77 of V-C is connected to the input terminal of the amplifier 76.

In addition, a bias power supply (VCC) is connected to the collector terminal of the detection transistor 72 and the base terminal of the driving transistor 74 through resistors R1 and R2, and a resistor (to the collector terminal of the driving transistor 74). The magnet coil 73A of the head drum motor 70 is connected via R3), and the bias power supply VCC is connected to the collector terminal of the switching transistor 75 via a resistor R1. In addition, a capacitor C is connected between the base of the driving transistor 74 and the collector end.

On the other hand, looking at the action of the conventional capstan motor driven by the drive circuit having the configuration described above, when the play mode or recording mode signal is input to the V-Cell microcomputer 77 drives the capstan motor 70, At this time, a predetermined detection voltage is applied to the hall sensor 71 during the first driving. Then, the hall sensor 71 inputs a detection signal to the base end of the detection transistor 72 according to the detection voltage, and accordingly the detection transistor 72 is turned on. When the detection transistor 72 is turned on, the bias voltage flows through the detection transistor 72. Accordingly, since no bias voltage flows to the base terminal of the driving transistor 74, a low signal is applied to the base terminal of the driving transistor 74. However, the driving transistor 74 is of the PNP type and is turned on in accordance with this low signal. Accordingly, the bias voltage flows current through the switching transistor 75 and the driving transistor 74 to the magnet coil 73A of the drum motor 70. As the driving current flows to the magnet coil 73A, magnetic flux is generated to rotate the rotor (not shown) magnetized with the magnetic pole. On the other hand, if the rotor (not shown) is rotated according to the above process, the hall sensor 78 connected to the next phase (detected) detects this and operates the magnet coil (73B) of the next phase as the driving process, so that the rotor It rotates by a certain rotation angle.

Therefore, if this process is repeated, the drum motor rotates continuously and accordingly, the head drum (not shown) linked with the drum motor also rotates so that the head mounted on the head drum plays or records information from the videotape. It is done.

However, in the driving circuit of the conventional capstan motor 70 as described above, when the driving transistor 73A is driven and the bias voltage flows through the magnet coil 72A of the capstan motor 70, the capstan motor 70 rotates at a predetermined angle. In this case, when the next driving transistor (73B) is to be driven to the magnet coil (72A) As shown in the formula of the noise pulse, for example, switching noise is generated as shown in P of FIG. Therefore, since the generated switching noise flows into the A / C head, there is a problem of causing audio noise (HIGH-PITCH NOISE) of the system.

The present invention is designed to solve the above problems, by connecting the zener diode to the driving power input terminal is applied to the magnet coil of the capstan motor, thereby increasing the local voltage generated in the magnet coil during the switching of the capstan motor The purpose is to provide a switching noise cancellation circuit of V-Cal capstan motor, which is thus reduced, thereby significantly improving the operating characteristics of the system.

Still another object of the present invention is to provide a switching noise elimination circuit of V-Cal capstan motor, which can prevent the capstan motor driving circuit from being damaged by a relatively simple circuit configuration.

The present invention for achieving the above object is a switching transistor connected to the emitter end of the capstan motor driving transistor for switching the drive voltage of the magnet coil, and connected to the base end of the switching transistor to amplify and output the input current control signal It is characterized in that it consists of an amplifier and a clamping means connected between one end of the driving transistor and the magnet coil to crimp the switching noise pulse signal generated in the magnet coil.

1 is an explanatory diagram illustrating a conventional head drum motor,

2 is a waveform illustrating switching noise generated in a conventional head drum motor.

3 is an explanatory diagram illustrating the present invention circuit,

4 is a driving waveform in which switching noise is removed by the circuit of FIG. 3.

<Description of the code | symbol about the principal part of drawing>

1: Head drum motor 2: Hall sensor

3: amplifier 4a-n: magnet coil

5: transistor 6: switching transistor

7: Amplifier 8: Low Pass Filter

9: micom R1-4: resistance

C1, C2: Capacitor

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

The present invention, as shown in Figure 2 Hall sensor 2 for detecting the rotation of the head drum motor (1) of V-Cal, NPN type that is turned on in accordance with the detection signal of the Hall sensor 2 is switching A detection transistor (3), a drive transistor (5) of the PNP type connected to the collector end of the detection transistor (3) to control the drive current of the magnet coils (4A, 4B) of the head drum motor (1), and this drive A switching transistor 6 connected to the emitter terminal of the transistor 5 to switch the driving voltages of the magnet coils 4A and 4B, and an amplified output of the input current control signal connected to the base terminal of the switching transistor 6; Clamping means 8 connected between an amplifier 7 and one end of the drive transistor 5 and the magnet coils 4A and 4B to crimp the switching noise pulse signal generated in the magnet coils 4A and 4B. )

Here, although the clamping means 8 is referred to only as a zener diode in the present invention, any type of clamping means capable of removing switching noise is not limited to the device type.

In addition, the microcomputer 9 of V-C is connected to the input terminal of the amplifier 7, and the collector terminal of the detection transistor 3 and the base terminal of the driving transistor 5 are biased via resistors R2 and R3. A VCC is connected, and a bias power supply VCC is connected to the collector terminal of the switching transistor 6 via a resistor R2. In addition, a capacitor C2 is connected between the base of the driving transistor 5 and the collector end.

Here, although the magnet coil 4A has been described only as a single phase, it is usually a multi-phase, for example, since it is composed of a three-phase motor, such a configuration circuit is similarly connected to the next-phase magnet coil 4B.

Next will be described the operation of the present invention having the configuration as described above.

As shown in FIG. 3, the microcomputer 9 drives the capstan motor 1 when the play mode or the recording mode signal is input to the V-Cal, as shown in FIG. It is applied to the sensor (2). Then, the Hall sensor 2 inputs a detection signal to the base end of the detection transistor 3 in accordance with the detection voltage, thereby turning on the detection transistor 3. When the detection transistor 3 is turned on, all of the bias voltages flow through the detection transistor 3. Accordingly, since the bias voltage does not flow to the base terminal of the driving transistor 5 at all, a low signal is applied to the base terminal of the driving transistor 5. However, the driving transistor 5 is of the PNP type and is turned on in accordance with this low signal. Accordingly, the bias voltage flows current through the switching transistor 6 and the driving transistor 5 through the magnet coil 4A of the capstan motor 1, wherein the driving voltage via the driving transistor 5 It goes through the ranking means (8). Then, as the driving current flows to the magnet coil 4A, magnetic flux is generated to rotate the rotor (not shown) in which the magnetic pole is magnetized. Here, the microcomputer 9 compares the speed pulse signal input from the FG circuit of the capstan motor and inputs the speed control signal of the drum motor 1 suitable for the currently set mode to the amplifier 7. Therefore, the amplifier 7 amplifies the speed control signal of the microcomputer 9 and applies it to the base end of the switching transistor 6, and the output current of the amplifier 7 is the base current of the switching transistor 6. It will be controlled. Accordingly, the current supplied to the magnet coil 4A of the drum motor 1 through the driving transistor 5 is reduced according to the base current of the switching transistor 6, and thus the rotational speed of the drum motor 1 is also reduced. Belong.

On the other hand, when the rotor (not shown) is rotated according to the above process, the hall sensor 10 connected to the next phase detects it and inputs the detection signal to the detection transistor of the next phase and accordingly the next phase detection transistor. And the driving transistor are turned on. Accordingly, the driving transistor of the next phase causes the driving current to flow the driving current to the magnet coil 4B of the next phase in a direction opposite to the driving current of the magnet coil 4A. Magnet coil (4A) As can be seen from the formula of noise pulse, for example, when switching noise as shown in FIG. 4C is generated, the generated switching noise is the cranking means 8, that is, one end of the driving transistor 5 and the magnet coil. It is removed by a zener diode connected between (4A, 4B).

Accordingly, the present invention, as in the above process, the switching generated when the driving circuit is switched to the next phase through the Hall sensors (2, 10) to apply the driving current to rotate the motor (1) Noise is completely removed by the clamping means 8.

As described above, the present invention allows the zener diode to be connected to the driving power input terminal applied to the magnet coil of the capstan motor, thereby clamping the western region voltage generated in the magnet coil when the capstan motor is switched. In addition, the operation characteristics of the capstan motor drive circuit is prevented from being damaged due to a relatively simple circuit configuration as well as significantly reducing the manufacturing cost of the capstan motor.

Claims (2)

In the head drum motor of V-Cal equipped with a drive transistor 5 for controlling the drive current of the magnet coils 4A and 4B in accordance with the speed control signal of the VC microcomputer 9, Clamping means 8 is provided between the one end of the drive transistor 5 and the magnet coils 4A and 4B to crimp the switching noise pulse signal generated in the magnet coils 4A and 4B. Switching noise elimination circuit of VCA capstan motor. 2. The switching noise elimination circuit according to claim 1, wherein the clamping means (8) is a zener diode.