KR960012413B1 - R.p.m. control device - Google Patents

Abstract

The apparatus regulates the rpm of a rotational means by using the computer control when testing a safety loader of a fuse so as to reduce the test time. The apparatus comprises: the rotational means(200) generating pulses according to the rpm of an attachment(100); a counter(300) counting the pulses while dividing the pulses by 1/10, 1/100, 1/1000 and 1/10000 via an inverter(IN1); a rpm detector(400) including an oscillator(410), a counter(420) and an AND gate(430) for generating a reference clock(CLK); a rotary speed converter(500) including a counter(510), an AND gate(520) and a single stability multi-vibrator(530) for converting the pulses from the rotational means(200) into a computer readable rotary speed ; a computer interface(600) connected to the counter(300).

Description

Rotation speed adjusting device by computer control

1 is a block diagram of a device for adjusting a rotational speed (rpm) of a rotating unit by computer control according to the present invention.

* Explanation of symbols for main parts of the drawings

100: jig 200: rotating part

300: counter unit 400: rotational speed reading unit

410: oscillator 500: rotation speed conversion unit

600: COMPUTER INTERFACE

310, 320, 330, 340, 420, 510: counter

430, 520: AND gate 530: monostable multivibrator

IN _{1 to} IN ₃ : Inverter

The present invention relates to a safety loading device of a fuse, and more particularly, to a rotation speed (rpm) adjusting device of a rotating part by computer control adjustable to maintain a constant rotation speed of a rotating part when performing a loading test of a safety loading device. .

Conventionally, when the load test of the safety loading device of the fuse is made, a circuit using an inverter or the like is configured, and the user adjusts the rotational speed of the rotating part by an analog method, so that the deviation of the adjustment according to the user's skill is different. A serious problem has arisen, and also a problem of not being able to accurately adjust the rotational speed of the safety loader.

Accordingly, the present invention is to provide an apparatus for adjusting the rotational speed (rpm) of a rotating unit by computer control, which can solve all the problems caused in the analog loading test of the conventional safety loading device.

The present invention provides a device for adjusting the rotational speed (rpm) of a rotating unit by computer control, which is configured to be able to maintain a precise rotational speed due to an interface with a computer that sets a rotational speed by configuring a relatively simple circuit. There is this.

In addition, the present invention is to be able to automatically maintain the rotational speed of the rotating part, it is possible to exclude the adjustment of the rotational speed by manual operation can shorten the time required to adjust the rotational speed of the rotating portion, the number of work required to work Another object of the present invention is to provide an apparatus for adjusting the rotational speed (rpm) of a rotating part by computer control, which can reduce the number of parts.

The present invention, in order to achieve the above object, in the loading test of the safety loading device of the fuse, converting the DC signal into an AC signal of the rotating unit 200 for generating a pulse according to the rotation speed (rpm) of the jig 100 Through the inverter IN _{1 is} connected to the counter unit 300 for counting the pulse signal generated from the rotating unit 200 divided into 1/10, 1/100, 1/1000, 1/10000, and the reference clock ( The rotational speed conversion unit 500 and the inverters IN _{2 to} IN for converting the rotational speed reading unit 400 for generating a CLK into a rotational speed that can be read by a computer according to the number of pulses generated from the rotating unit 200. _It is achieved by the rotation speed (rpm) adjusting device of the rotating part by the computer control, characterized in that connected to the counter unit 300 through ₂ ), the counter unit 300 is connected to the computer interface 600 .

The above and other objects, features, and effects of the present invention will be more clearly understood by the embodiments described in detail with reference to the accompanying drawings.

1 is a block diagram of a device for adjusting a rotational speed (rpm) of a rotating unit by computer control according to the present invention.

The rotary unit 200 is a conventional rotary encoder in which a pulse signal is generated at the same decomposition rate according to the rotational speed at which the jig 100 rotates, and an output end of the rotary unit 200 connected to the jig 100. The counter 310 of the counter unit 300 that counts pulses by dividing the pulse into 1/10, 1/100, 1/1000, and 1/10000 through an inverter IN ₁ that converts a DC signal into an AC signal. Is connected to.

The counter unit 300 is to count the pulse signal generated by the rotating unit 200 by dividing it into 1/10, 1/100, 1/1000, and 1/10000, and counts it as 1/10. ) And the counter unit 300, which comprises a counter 320 that counts to 1/100, a counter 330 that counts to 1/1000, and a counter 340 that counts to 1/10000, is generated from the rotating unit 200. connected to the inverter (iN ₂ ~IN ₂₎ the computer is connected to the output terminal of the monostable multivibrator 530 of the speed conversion unit 500 to the data to convert the data of the rotational speed that can be read according to the number of pulses Is connected to the output terminal of the rotary unit 200 is connected to the jig 100 through an inverter (IN ₁ ), the output terminal of the counter unit 300 is connected to a computer interface (COMPUTER INTERFACE) 600 It is.

The rotational speed reading unit 400 is capable of generating an arbitrary reference clock signal, and counts the oscillator 410 and the oscillation signal output from the oscillator 410. A counter 420 and an AND gate 430 for ANDing a signal counted from the counter 420 and outputting the signal are generated as a clock signal.

The rotation speed converter 500 may convert the rotation speed into a rotation speed that can be read by a computer according to the number of pulses generated from the rotation part 200, and the AND gate 430 of the rotation speed readout 400 A counter 510 for counting a clock signal outputted from the counter), an AND gate 520 for ANDing a value of the signal counted from the counter 510, and a counter part by an AND signal from the AND gate 520. A monostable multivibrator 530 that controls each of the counters 310 to 340 of the 300 is configured.

Hereinafter, the operation relations and effects of the rotation speed (rpm) adjusting device of the rotating unit by the computer control according to the present invention.

The apparatus of the present invention is configured with the operator setting the oscillator 410 of the rotational speed reading unit 400 to oscillate for an arbitrary reference time (eg, '100' ms).

If the jig 100 is rotated according to the rotational speed of the rotary encoder 200 is rotated, the rotary encoder of the rotary part 200 is rotated by the decomposition ratio of the encoder (for example, '600') Generates a pulse signal such as a rotational speed of the jig 100 (for example, '20' rpm), the pulse signal generated from the rotary encoder of the rotary unit 200 is an inverter (IN ₁ to convert a DC signal into an AC signal) Is sent).

The pulse signal transmitted to the inverter (IN ₁₎ is converted into an AC signal by the inverter (IN ₁₎ is sent to the counter 310 of the counter 300. The

On the other hand, the oscillation signal generated from the oscillator 410 of the rotational speed reading unit 400 which is set to oscillate for any reference time set by the operator (eg, '100'ms) is the rotational speed reading unit 400. Is transmitted to the counter 420 of the counter) and the signal counted from the counter 420 of the rotational speed reading unit 400 is transmitted to the end gate 430, and the AND gate of the rotational speed reading unit 400. The signal transmitted to 430 is ANDed by the AND gate 430 to be converted into a clock signal.

The clock signal generated through the AND gate 430 of the rotational speed reading unit 400 is transmitted to and counted by the counter 510 of the rotational speed conversion unit 500, and the counter of the rotational speed conversion unit 500 is counted. The signal counted at 510 is transmitted to the AND gate 520, and the signal transmitted to the AND gate 520 of the rotational speed converter 500 is ANDed by the AND gate 520 to provide the monostable multivibrator 530. Is sent).

The monostable multivibrator 530 of the rotation speed converter 500 may calculate the number of pulse signals generated by the rotation unit 200 (that is, the rotation speed of the jig 100) by the transmitted signal. The control signal is transmitted to the counter 310 of the counter unit 300 through the inverter IN _{2 in} order to convert to a rotation speed that can be read from.

Accordingly, the counter 310 of the counter unit 300 is generated and input from the rotary encoder of the rotating unit 200 by a control signal output from the monostable multivibrator 530 of the rotational speed converter 500. The number of pulses is counted by 1/10 for a predetermined time (for example, '100' ms), and the value counted from the counter 310 of the counter unit 300 is transferred to the computer through the computer interface 600. The computer transmits the number of pulses counted from the counter 310 of the counter unit 300 and the rotational speed reading unit 400 by a software program of its own for an arbitrary reference setting time (eg, '100'ms). Multiply any reference time (e.g., '100'ms) set in the oscillator 410, multiply that value by' 1 'minutes (i.e.,' 60 'SEC), and then decode the encoder (e.g., Dividing by 600'ms to calculate the final value (ie the rotational speed of the jig).

The computer controls the speed control circuit of the jig 100 to rotate constantly by the calculated value (that is, the rotational speed of the jig).

In addition, when the jig 100 rotates at a speed of '1000', the rotary part 200 made of a rotary encoder rotates according to the rotational speed at which the jig 100 rotates, and the rotating part ( The rotary encoder of 200 generates a pulse signal such as a rotation speed (eg, '1000' rpm) of the jig 100 at an decomposition ratio of the encoder (eg, '600'), and the rotary part of the rotary part 200. The pulse signal generated from the encoder is transmitted to an inverter IN ₁ that converts a DC signal into an AC signal.

The pulse signal transmitted to the inverter (IN ₁₎ is converted into an AC signal via an inverter (IN ₁₎ is sent to the counter 330 via the counter 310, the counter 300.

On the other hand, the oscillation signal generated from the oscillator 410 of the rotational speed reading unit 400, which is set to oscillate for any reference time set by the operator (for example, '100'ms), is generated by the rotational speed reading unit 400. Transmitted and counted to the counter 420, the counted signal from the counter 420 of the rotational speed reading unit 400 is transmitted to the end gate 430, and the AND gate 430 of the rotational speed reading unit 400 The signal transmitted at) is ANDed and converted into a clock signal.

The clock signal generated through the AND gate 430 of the rotation speed reading unit 400 is transmitted to the counter 510 of the rotation speed converting unit 500, and the counter 510 of the rotation speed converting unit 500. The counted signal from is sent to the endgate 520.

The signal transmitted to the AND gate 520 of the rotational speed converter 500 is ANDed by the AND gate 520, and the signal from the AND gate 520 of the ROT converter 500 is short. Stable multivibrator 530 is transmitted.

The monostable multivibrator 530 of the rotational speed converting unit 500 is the number of pulse signals generated by the rotary encoder of the rotating unit 200 by the signal transmitted from the end gate 520 (that is, jig 100). The control signal is transmitted to the counter 330 of the counter unit 300 through the inverters IN ₂ to IN _{3 in} order to convert the rotation speed) into a rotation speed that can be read by a computer.

Therefore, the counter 330 of the counter unit 300 is generated by the rotary encoder of the rotary unit 200 by the control signal output from the mono-stable precision vibrator 530 of the rotational speed converter 500 and inputted therein. The number of times is counted as 1/1000 for a predetermined time (for example, '100'ms), and the value counted as 1/1000 from the counter 330 of the counter unit 300 is determined by the computer interface 600. Is transferred to the computer.

The computer generates the number of pulses counted from the counter 330 of the counter unit 300 and the oscillator 410 of the rotational speed reading unit 400 for a predetermined period of time set by its own program (eg, '100' ms). Multiply any number of times (e.g., '100'ms) set at, multiply that value by' 1 minute (ie, '60' SEC), and then set the encoder's decomposition rate (eg, '600'ms). The final value is calculated by dividing.

The computer controls the speed control circuit to maintain the rotation speed of the jig 100 by the calculated value (that is, the rotation speed of the jig).

As described above, the present invention allows the computer to automatically and accurately rotate the rotational speed of the rotating part with the computer when the loading test of the safety loading device of the fuse, thereby improving the reliability of the rotating part and reducing the time required for the work. It is possible to improve the productivity by reducing the number of personnel.

Claims (4)

In the loading test of the safety loading device of the fuse, the rotation unit (200) for generating a pulse according to the rotation speed (rpm) of the jig 100 through the inverter IN ₁ for converting a DC signal into an AC signal (the rotating unit ( Rotational speed reading unit 400 is connected to the counter unit 300 for dividing the pulse signal generated from the 200 into 1/10, 1/100, 1/1000, 1/10000 and generates a reference clock CLK. ) to the speed conversion section 500 and the inverter (the counter 300 through the iN ₂ ~IN ₂₎ for converting a rotation speed that can be computer is read in accordance with the number of pulses generated from said rotary part (200) And a counter speed (300) connected to a computer interface (600). The oscillator 410 of claim 1, wherein the rotational speed reading unit 400 generates an oscillation signal so as to generate a reference clock signal, a counter 420 that counts the oscillator signal, and an AND gate 430 that ANDs the counted signal. Rotation speed (rpm) adjusting device of the rotating unit by a computer control, characterized in that consisting of. The monolithic multivibrator of claim 1, wherein the rotational speed converter 500 changes the computer-readable rotational speed according to the number of pulses generated by the rotational unit 200. A rotation speed (rpm) adjusting device of the rotating unit by computer control, characterized in that consisting of (530). The method of claim 1, wherein the counter unit 300 is characterized in that it comprises a counter (310-340) for counting the pulse generated in the rotating unit 200 to 1/10, 1/100, 1/1000, 1/10000 Rotation speed (rpm) adjustment device by the computer control.