JPS6142294A - Drive device for pulse motor - Google Patents

Abstract

PURPOSE:To smoothly drive a rotor without vibration by varying an exciting voltage in response to the frequency of a drive pulse. CONSTITUTION:When an input drive pulse (a) is input to an F/V converter 4, the converter 4 outputs a voltage signal proportional to the frequency of the pulse. This output voltage is amplified by an amplifier 6, and supplied to a drive circuit 8. On the other hand, the drive pulse is supplied to a pulse distributor 2, which outputs a rotary command pulse. This command pulse is supplied to the driven circuit 8. The circuit 8 applies an electric pulse to the phases of the exciting windings of the stator of a pulse motor 10 on the basis of the command pulse and the output exciting voltage of a power amplifier 6 to thereby rotate the motor 10.

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention relates to a pulse motor drive device equipped with an F-V (frequency-voltage) conversion circuit that controls a drive voltage according to the frequency of drive pulses to a pulse motor. Regarding.

[Conventional technology]

The types of pulse motor drive devices are roughly divided into two types: a constant current drive method in which a pulse motor is driven by applying a constant current, and a constant voltage drive method in which a pulse motor is driven by applying a constant voltage.

[Problem that the invention seeks to solve]

In a constant voltage drive system, the motor rotor undergoes damped vibration as shown by the solid line in Figure 4 between the input of the input electric pulse signal and the next step, and this causes the rotation of the motor's output shaft to slow down. There was a flaw in that it did not run smoothly.

In the constant current drive method, the rise torque characteristics of the pulse motor at high speeds are improved, but a problem arises in that vibration chopper noise is produced at low speeds.

None of the above two methods can solve the problem of vibration of the output shaft of the motor. Therefore, an object of the present invention is to provide a pulse motor drive device that eliminates the above-mentioned defects.

[Means to solve problems]

In order to achieve the above object, the present invention provides a device for driving a pulse motor by supplying electric pulses to each phase of a stator excitation winding of a pulse motor. A means is provided for changing the excitation voltage applied to each phase of the line.

[Effect]

Therefore, when the frequency of the electric pulses supplied to the pulse motor increases, the stator excitation voltage increases accordingly, shortening the rotor rise time, and when the frequency of the electric pulses decreases, the rotor excitation voltage increases accordingly. The rise time becomes longer. As a result, the first stationary point of the rotor for each pulse coincides with the application timing of the electric pulse, and the rotor rotates smoothly without vibration.

〔Example〕

The configuration of the present invention will be explained below with reference to the accompanying drawings.

In FIG. 1, 2 is a pulse distribution circuit.

The input end of this is connected to the output end of a pulse motor drive pulse generation circuit (not shown). Reference numeral 4 denotes an F-V conversion circuit configured so that the output voltage signal changes according to the frequency of the input pulse, and the input terminal of this circuit is connected to the output terminal of the drive pulse generation circuit. 6 is a power amplifier circuit, which is connected to the power supply and the output end of the F-V conversion circuit. The power amplification circuit 6 amplifies the output voltage signal of the F-V conversion circuit 4 and supplies this amplified voltage to the pulse motor drive circuit 8. The drive circuit 8 supplies drive electric pulses to each phase of the stator winding of the pulse motor 10 based on the output voltage of the power amplifier circuit 6' and the output command pulse signal of the pulse distribution circuit 2, thereby driving the pulse motor 10. to drive.

Next, the operation of this embodiment will be explained.

When the output pulse of the drive pulse generation circuit is input to the F-V conversion circuit 4, a voltage signal proportional to the frequency of the output pulse is output from the F-V conversion circuit 4, as shown in FIG. This output voltage is amplified by the power amplifier circuit 6 and supplied to the drive circuit 8. On the other hand, the output pulses of the drive pulse generation circuit are supplied to the pulse distribution circuit 2, which outputs rotation command pulses. This command pulse is supplied to the drive circuit 8. The drive circuit 8 applies electric pulses to each phase of the excitation winding of the stator of the pulse motor 10 based on the command pulse and the output excitation voltage of the power amplification circuit 6, thereby causing the pulse motor 1o to rotate. Starting, stopping, and steady rotation of the pulse motor 10 are defined by the frequency of the electric pulses applied to the stator. The rise time of the rotor of the pulse motor 10 is inversely proportional to the magnitude of the voltage of the electric pulse applied to the stator of the pulse motor. That is, in FIG. 4, if the predetermined rotation angle of the rotor of the pulse motor corresponding to one electric pulse is eO, the time t1 for the rotor to reach the angle θO by one electric pulse is
If you want to shorten the time t1, you can increase the excitation voltage to the pulse motor, and if you want to lengthen the time t1, you can decrease the excitation voltage.

One electric pulse is applied to the pulse motor 10, and the rotor is supplied to the pulse motor in such a way that the rotor rises to an angle θ0, and when the inertia force reaches the first rest point angle θ1, the next electric pulse is applied. If the excitation voltage is set to the frequency of the electric pulse, the rotor of the pulse motor will rotate smoothly without vibration. The invention is based on this principle. For example, No. 2, as shown in FIG.
When an electric pulse having a frequency indicated by
The signal is amplified by and supplied to the drive circuit 8. The height of this voltage is such that j electric pulses are applied to the pulse motor 10 at t1.
When the first stationary point of the rotor is exactly θ1
It is set so that Therefore, the next electric pulse is supplied to the pulse motor at time t2 when the rotor is stationary, and the vibration of the rotor of the pulse motor is eliminated.

In FIG. 3, No, No for drive pulses 1 to 4,
The rotation characteristic diagrams of rotors 1 to 4 correspond. As is clear from the above description, the configurations of the F-V conversion circuit 4 and the power amplifier circuit 6 constitute means for changing the excitation voltage to each phase of the stator excitation winding according to the frequency of the electric pulse. are doing.

〔effect〕

As described above, the present invention is configured to change the excitation voltage according to the frequency of the drive pulse, and therefore has the effect of being able to smoothly drive the pulse motor.

[Brief explanation of drawings]

The figures show preferred embodiments of the present invention, in which Figure 1 is a block circuit diagram, Figure 2 is an output characteristic diagram of the F-V conversion circuit, Figure 3 is an operational diagram, and Figure 4 is a transient diagram of the pulse motor. It is a response characteristic diagram. 2... Pulse distribution circuit, 4... F-V conversion circuit. 6...Power amplification circuit, 8...Pulse motor drive circuit, 10...Pulse motor patent applicant Patent attorney Muto Kogyo Co., Ltd. Akio Nishijima ・Figure 1 Figure 2 Figure 3 Figure 4

Claims (1)

[Claims] (1) In a device that drives a pulse motor by supplying electric pulses to each phase of a stator excitation winding of a pulse motor, the excitation voltage to each phase of the stator excitation winding is determined according to the frequency of the electric pulse. 1. A pulse motor drive device characterized by comprising means for changing.