KR19980050189U - Back EMF Elimination Circuit of V-Cal Head Drum Motor - Google Patents

Abstract

The present invention relates to a counter electromotive force elimination circuit of a V-Cal head drum motor. The driving current is supplied to the magnet coil in accordance with the speed control signal of the V-Cal microcomputer. And a freewheeling transistor connected to one end of the magnet coil to remove the magnetic energy generated by the magnet coil, by applying a driving voltage to another magnet coil adjacent thereto. Since it removes unnecessary magnetic energy that is induced, it is possible to prevent overheating of the head drum motor accordingly.

Description

Back EMF Elimination Circuit of V-Cal Head Drum Motor

This paper relates to the back electromotive force elimination circuit of V-Cal head drum motor, and in particular, it is possible to connect the transistor that performs the freewheeling operation to the magnet coil of the head drum motor. The present invention relates to a counter electromotive force removing circuit of a V-Cal head drum motor, which can prevent overheating of the head drum motor.

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 position relationship) as in recording.

In addition, referring to FIG. 1, the conventional driving circuit of the head drum motor of V-Cal is referred to as a Hall sensor 71 which detects the rotation of the head drum motor 70 of the BC-R and the hall sensor 71. NPN-type detection transistor 72 which is turned on according to the detection signal of the switching transistor and connected to the collector terminal of the detection transistor 72 to drive the driving current of the magnet coils 73A and 73B of the head drum motor 70. A driving transistor 74 of a PNP type to be controlled, a switching transistor 75 connected to an emitter end of the driving transistor 74 to switch driving voltages of the magnet coils 73A and 73B, and the switching transistor 75 of the switching transistor 75 An amplifier 76 is connected to the base terminal to amplify and output the input current control signal.

The 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 via resistors R1 and R2. 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.

Here, the magnet coil 73A has been described only in a single phase, but is usually connected in a multi-phase, for example, three-phase or the like.

On the other hand, looking at the operation of the conventional head drum 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 to drive the head drum motor 70 At this time, the first driving is to apply a predetermined detection voltage to the Hall sensor (71). 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. Therefore, 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, since the driving transistor 74 is of the PNP type, the low signal is applied to this base transistor. It turns on according to the signal. Accordingly, the bias voltage causes a current to flow through the switching transistor 75 and the driving transistor 74 to the magnet coil 73A of the drum motor 70. Then, as the driving current flows to the magnet coil 73A, magnetic flux is generated to rotate the rotor (not shown) with the magnetic pole magnetized. Meanwhile, if the rotor (not shown) is rotated according to the above process, Since the hall sensor connected to the phase detects this and operates the magnet coil 73B of the next phase as in the driving process, the rotor rotates.

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

However, the conventional head drum motor 70 as described above, for example, when the drive current flows to the magnet coil 73A to drive the magnet of the rotor to rotate the drive current to the next magnet coil (73B) magnet coil ( In 73A), back EMF is generated according to Fleming's left-hand law and is accumulated as magnetic energy. Therefore, since the magnetic energy of the magnet coil 73A acts as a factor of overheating the head drum motor 70, there is a disadvantage in that the operation characteristics of the head drum motor are deteriorated accordingly.

In this regard, the present invention was devised to solve the above shortcomings, and is induced by applying a driving voltage to another adjacent magnet coil by connecting a transistor for freewheeling to the magnet coil of the head drum motor. The purpose of the present invention is to provide a counter electromotive force elimination circuit of V-Cal head drum motor, which can remove unnecessary magnetic energy, thereby preventing overheating of the head drum motor.

The present invention for achieving the above object is a Hall sensor for detecting the rotation of the head drum motor is driven because the drive current is supplied to the magnet coil in accordance with the speed control signal of VRC microcomputer, and according to the detection signal of the Hall sensor And a freewheeling transistor connected to one end of the magnet coil to remove magnetic energy generated from the magnet coil.

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

2 is an explanatory diagram for explaining the head drum motor of the present design.

Explanation of symbols for the main parts of the drawings

1: Head drum motor 2: Hall sensor

3: amplifier 4a-n: magnet coil

5: transistor 6: switching transistor

7: Amplifier 8: Freewheeling Transistor

9: micom

R1-3: Resistance C: Capacitor

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in Fig. 2, the present design has a Hall sensor 2 for detecting the rotation of the head drum motor 1 of V-Cal, and an NPN type which is turned on according to the detection signal of the Hall sensor 2 to perform a switching action. 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; It consists of an amplifier 7 and a freewheeling transistor 8 connected to one end of the magnet coils 4A-N to remove magnetic energy generated from the magnet coils 4A-N.

The microcomputer 9 of V-C is connected to the input terminal of the amplifier 7, and the base terminal of the driving transistor 5 and the collector terminal of the detection transistor 3 are connected to the base terminal of the freewheeling transistor 8. The magnet coil 4A of the head drum motor 1 is connected to the collector terminal of the driving transistor 5 via a resistor R3.

In addition, a bias power supply (VCC) is connected to the collector terminal of the detection transistor 3, the base terminal of the driving transistor 5, and the base terminal of the freewheeling transistor 8 via resistors R1 and R2. A bias power supply VCC is connected to the collector terminal of the transistor 6 via a resistor R1. A capacitor C is connected between the base of the driving transistor 5 and the collector end.

Here, although the magnet coil 4A has been described only in a single phase, it is usually connected in a multi-phase, for example, three-phase or the like.

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

As shown in FIG. 2, the microcircuit 9 drives the head drum motor 1 when the play mode or the recording mode signal is input to the V-Cal, as shown in FIG. 2. It is applied to the Hall 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. Therefore, since no bias voltage flows to the base end of the drive transistor 5, a low signal is applied to the base end of the drive transistor 5. However, since this drive transistor 5 is a PNP type, this low signal is applied. It turns on according to the signal. Accordingly, the bias voltage causes current to flow through the magnet coil 4A of the drum motor 1 via the switching transistor 6 and the driving transistor 5. As the driving current flows to the magnet coil 4A, magnetic flux is generated to rotate the rotor (not shown) magnetized with the magnetic pole. At this time, the microcomputer 8 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. Will be controlled. Therefore, the current supplied to the magnet coil 4A of the drum motor 1 through the driving transistor 5 is also subtracted according to the base current of the switching transistor 6, and thus the rotational speed of the drum motor 1 is also reduced. Acceleration and deceleration.

On the other hand, when the rotor (not shown) is rotated according to the above process, the hall sensor connected to the next phase detects it and inputs the detection signal to the detection transistor of the next phase. Accordingly, the next phase detection transistor and the driving transistor are turned on. do. At this time, when the detection transistor is turned on, since the bias power source vcc is input via the resistors R1 and R2 to the base end of the freewheeling transistor 8, the freewheeling transistor 8 is 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 that of the magnet coil 4A. Then, magnetic flux is generated in the magnet coil 4B of the drum motor 1 to push the magnetic poles of the rotor of the drum motor 1 and the rotor rotates accordingly.

However, when the driving current is flowed into the magnet coil 4A as in the above process, and then the driving current is flowed into the magnet coil 4B of the next phase, the counter electromotive force is generated in the magnet coil 4B according to the Fleming's left hand law. Like formula (1)

* L ₁ * i ² ------------ Formula (1)

Magnetic energy will accumulate. At this time, the magnetic energy is discharged to the ground by the free-wheeling action through the free-wheeling transistor 8 which is already turned on.

Therefore, if this process is repeated, the drum motor 1 rotates continuously and accordingly the head drum (not shown) interlocked with the drum motor 1 also rotates, so that the head mounted on the head drum is moved from the video tape. Information will be played back or recorded.

As described above, this paper connects the offset coil coiled to the magnet coil of the head drum motor as opposed to the winding direction of the magnet coil, thereby eliminating unnecessary magnetism induced by applying a driving voltage to other adjacent magnet coils. Since the energy is removed, the rotational speed of the head drum motor can be made uniform, and the head drum motor is driven at normal speed, thereby eliminating jitter.

Claims (2)

The head of V-Cal having a Hall sensor 2 for detecting rotation of the head drum motor 1 being driven since the drive current is supplied to the magnet coils 4A-n according to the speed control signal of the V-Cal microcomputer 9. In drum motors, NPN-type detection transistor 3, which is turned on according to the detection signal of the hall sensor 2 and switches, and is connected to one end of the magnet coils 4A-n and is generated in the magnet coils 4A-n. The back electromotive force removing circuit of the BC head drum motor, comprising a freewheeling transistor (8) for removing magnetic energy. 2. The counter electromotive force elimination circuit of a BC head drum motor according to claim 1, wherein said detection transistor (3) is an NPN transistor.