JPH0342325Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a position sensor that uses a stepping motor as a position signal generation source.

[Prior Art] Photo encoders and the like have been known as position sensors, and are widely used in various position detection fields.

[Problems to be Solved by the Invention] However, photo encoders are generally expensive, and since they are made of glass, they have the disadvantage of being weak in strength.

An object of the present invention is to provide a position sensor using a stepping motor that is inexpensive and mechanically robust.

[Means for Solving the Problems] In order to achieve the above object, the present invention provides a multi-phase permanent magnet type stepping motor in which a rotor is connected to a detected part whose position is to be detected; an adding circuit that vectorially adds sine wave signals output from each stator coil of adjacent phases of the stepping motor as the stepping motor rotates, and outputs a sine wave signal having a phase intermediate between the adjacent phases; and,
It is characterized by comprising a plurality of waveform conversion circuits that convert each sine wave signal from each stator coil and addition circuit of the adjacent phases into a pulse signal and output it as a position signal of the detected part. .

[Operation of the invention] The position sensor of the invention detects with high precision the position of a moving detection target connected to the rotor of a stepping motor based on a position signal consisting of a pulse signal obtained by the above-mentioned means. be able to. Further, since the above-mentioned means only requires adding additional circuits such as an adding circuit and a waveform converting circuit to the stepping motor, a relatively inexpensive and mechanically strong position sensor can be obtained.

[Example] The conventional photo encoder described above can detect the position even when the detected part is stationary, but the present invention mainly detects the position when the detected part is moving, so the rotor is not covered. It uses a multi-phase permanent magnet stepping motor connected to the detector.

Embodiments of the present invention will be described below based on the drawings.

The drawings show an embodiment of a position sensor using a stepping motor according to the present invention. In the same figure, the rotor of a four-phase permanent magnet type stepping motor is connected to a detected part (not shown), and as the rotor rotates, there is a phase difference of 90° from stator coil A and stator coil B. The sine wave signals a, b are output, and each sine wave signal a, b
is amplified by amplifiers 1 and 2. These amplified sine wave signals a and b are added vectorially by an adder circuit 3, and a new sine wave signal c having a phase intermediate between both signals a and b is output. Next, the amplified sine wave signals a, b and the new sine wave signal c are converted into pulse signals P ₁ to P ₃ by waveform conversion circuits 4 to 6, respectively, and the pulse signals are converted into position signals of the detected part. is output as The above amplifiers 1 and 2, addition circuit 3, and waveform conversion circuits 4 to 6 constitute a position signal generation circuit 7. Note that although only the position signal generation circuit 7 provided on the output side of stator coil A and stator coil B is shown in the drawing, the above-mentioned circuit is also provided on each output side of stator coil B, A and B, and B and A. Position signal generation circuit 8 similar to
10 is provided, and as a result, pulse signals based on eight kinds of sine wave signals whose phases differ by 45 degrees from each other are output from the eight output terminals 11 to 18 of the position signal generation circuits 7 to 10. Become. This results in
For example, if a pulse signal of 50 pulses is output per one rotation of the rotor from each of the eight output terminals 11 to 18, the total number of pulse signals per one rotation of the rotor is
A pulse signal of 400 pulses is obtained, and based on these pulse signals, the position of the detected part connected to the rotor can be detected with high accuracy.

In addition, in the above embodiment, four sets of stepping
Although a motor is used, the present invention is not limited to this. For example, it is also possible to use a 5-phase stepping motor, and in this case, it is possible to obtain, for example, 1000 pulse signals per rotation of the rotor. , more accurate position detection can be performed.

[Effects of the invention] As explained above, the present invention uses a multi-phase permanent magnet type stepping device for the part to be detected whose position is to be detected.
The rotors of the motors are connected, and as the rotors rotate, the sine wave signals output from the stator coils of the adjacent phases of the stepping motor are added to an adder circuit to generate a sine wave signal having a phase intermediate between the adjacent phases. The wave signal is obtained, and each sine wave signal from each of the stator coils and the adder circuit is applied to a waveform conversion circuit to be converted into a pulse signal, and the pulse signal is output as a position signal of the detected part. , the position of the moving detected part can be detected with high precision.

Further, since the present invention only requires adding additional circuits such as an adding circuit and a waveform converting circuit to the above-mentioned stepping motor, it can be widely used as a relatively inexpensive and mechanically robust position sensor.

[Brief explanation of the drawing]

The drawing is a circuit diagram showing a main part of an embodiment of the present invention. A, B, . . . stator coil of stepping motor, 3 . . . addition circuit, 4 to 6 . . . waveform conversion circuit, 7 to 10 .

Claims (1)

[Scope of utility model registration request] a multi-phase permanent magnet stepping motor with a rotor connected to a detected part whose position is to be detected;
As the rotor rotates, sine wave signals output from stator coils of adjacent phases of the stepping motor are added vectorially to output a sine wave signal having a phase intermediate between the adjacent phases. comprising an adder circuit and a plurality of waveform conversion circuits that convert each sine wave signal from each stator coil of the adjacent phase and the adder circuit into a pulse signal and output the pulse signal as a position signal of the detected part. A position sensor using a stepping motor featuring: