KR101745960B1 - Three phase motor protection circuit - Google Patents

Abstract

The present invention relates to a three-phase motor protection circuit comprising: first, second, and third phase power input terminals respectively connected to three phase power input lines; A current transformer connection terminal connected to a current transformer installed for monitoring the current of a motor which is operated by receiving power from the three-phase power input line; And an overload setting variable resistor and a no-load setting variable resistor connected in parallel between the first phase power input terminal and the second phase power input terminal, wherein the overload setting variable resistor and the no- A delay angle setting unit for outputting a signal having a phase delayed by a predetermined angle with respect to a phase of the first phase power source; A transformer connected between the second phase power input terminal and the third phase power input terminal and having a center tap having a phase difference of 180 degrees with respect to the first phase power supply; And a first diode and a second diode which are connected in parallel to each other in a reverse direction between a line commonly connected to one of the center tap of the transformer and the current transformer connection terminal and a line connected to the other of the current transformer connection terminals A square wave converting unit for short-circuiting a voltage equal to or greater than a predetermined value obtained from the current transformer to convert an AC sine wave into a square wave; An amplifying unit amplifying the output of the square wave converting unit; An overload detection flip-flop for maintaining an output according to a parallax between a phase of a load current output from the amplifier and a delay angle set by the overload setting variable resistor for a wavelength; A load detecting flip-flop for holding an output according to a time difference between a phase of a load current outputted from the amplifying unit and a delay angle set by the no-load setting variable resistor for a wavelength; And an abnormality signal detecting unit for detecting and outputting an abnormality signal of the motor from the output of the overload detection flip-flop and the no-load detection flip-flop.
According to the present invention, by detecting the motor abnormality by comparing the delay angle of the current due to the change of the inductance of the motor and the delay angle of the preset voltage, it is possible to precisely set the detection sensitivity regardless of the fluctuation of the amount of current of the load. There is an effect that the abnormality of the motor can be accurately detected even if magnetic saturation occurs.

Description

[0001] THREE PHASE MOTOR PROTECTION CIRCUIT [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a three-phase motor protection circuit, and more particularly, to a three-phase motor protection circuit that detects an abnormality of a motor using a load current phase delay characteristic according to a change in inductance of the motor.

Generally, in a motor which is generally used for three-phase alternating current, three phases of R phase, S phase and T phase are applied to the motor to operate the motor. The three-phase AC power applied in this manner is a three- And the breakdown of the three-phase motor is often caused by an image formation.

In addition, it is necessary to detect the abnormality of the motor rapidly and take appropriate countermeasures against various faults such as overload of the motor, short circuit between coils, overheat, coil disconnection, idling, light load, no load.

Generally, in order to detect an abnormality of the motor, the amount of current of the load is detected from a current transformer installed in the motor, and the abnormality of the motor is diagnosed from the detected amount of current. However, in the method of detecting the change of the amount of current, it is difficult to precisely set the reference value because the current varies according to the supply voltage. For example, when a partial short circuit of the coil occurs, when the coil or the core is overheated, or when a mechanical overload occurs, it is practically impossible to set a precise detection sensitivity because the amount of current changes according to the voltage fluctuation. In addition, in a method of detecting an abnormality of the motor by measuring the amount of current, magnetic saturation occurs more than the standard of the current transformer, among other things. In this case, it is very difficult to accurately measure the amount of current.

Korean Patent Laid-Open No. 10-2010-0080184 discloses a motor protection control apparatus for correcting an error of a current value measured by a current transformer to measure an accurate current value. However, even in the preceding literature, it is still difficult to measure the amount of current when the current transformer has magnetic saturation higher than its own standard. Such a problem is still a problem to be solved in the method of measuring the amount of current from the current transformer.

Korean Patent Publication No. 10-2010-0080184

The present invention detects a motor abnormality by comparing a delay angle of a current due to a change in inductance of a motor and a delay angle of a preset voltage, unlike the conventional method of detecting the amount of current flowing in the motor, And it is an object of the present invention to provide a three-phase motor protection circuit capable of precisely setting sensitivity and accurately detecting an abnormality of a motor even when magnetic saturation of a current transformer occurs.

A three-phase motor protection circuit according to an embodiment of the present invention includes first, second, and third phase power input terminals respectively connected to three phase power input lines; A current transformer connection terminal connected to a current transformer installed for monitoring the current of a motor which is operated by receiving power from the three-phase power input line; And an overload setting variable resistor and a no-load setting variable resistor connected in parallel between the first phase power input terminal and the second phase power input terminal, wherein the overload setting variable resistor and the no- A delay angle setting unit for outputting a signal having a phase delayed by a predetermined angle with respect to a phase of the first phase power source; A transformer connected between the second phase power input terminal and the third phase power input terminal and having a center tap having a phase difference of 180 degrees with respect to the first phase power supply; And a first diode and a second diode which are connected in parallel to each other in a reverse direction between a line commonly connected to one of the center tap of the transformer and the current transformer connection terminal and a line connected to the other of the current transformer connection terminals A square wave converting unit for short-circuiting a voltage equal to or greater than a predetermined value obtained from the current transformer to convert an AC sine wave into a square wave; An amplifying unit amplifying the output of the square wave converting unit; An overload detection flip-flop for maintaining an output according to a parallax between a phase of a load current output from the amplifier and a delay angle set by the overload setting variable resistor for a wavelength; A load detecting flip-flop for holding an output according to a time difference between a phase of a load current outputted from the amplifying unit and a delay angle set by the no-load setting variable resistor for a wavelength; And an abnormality signal detecting unit for detecting and outputting an abnormality signal of the motor from the output of the overload detection flip-flop and the no-load detection flip-flop.

In the above embodiment, the abnormal signal detection section generates a high level output when the output signal of the overload detection flip-flop is generated, and a feedback circuit that feeds back the high level output to the input terminal is formed at the output terminal, A first ripple counter for maintaining a level output; A second ripple counter for generating a high level output when the output signal of the no-load detecting flip-flop is generated, and a feedback circuit for feeding back a high level output to an input terminal at the output terminal and maintaining a high level output until the next reset; A flicker signal output circuit for half-wave rectifying the AC input when no high-level output is generated in the first ripple counter and the second ripple counter and outputting a flicker signal indicating a steady state of the motor; An overload signal output circuit for outputting an overload signal indicating an overload of the motor when a high level signal is output from the first ripple counter; And a no-load signal output circuit for outputting a no-load signal indicating no-load of the motor when a high level signal is output from the second ripple counter.

The photocoupler may further include a photocoupler disposed downstream of the blink signal output circuit, the overload signal output circuit, and the no-load signal output circuit. The light emitting diode of the photocoupler is periodically turned on / off And is turned on by the no-load signal, and an abnormal signal output terminal is connected to the transistor input terminal and the output terminal of the photocoupler.

In the above embodiment, it further includes a bypass circuit portion for bypassing the overload signal output circuit portion from the input terminal of the photocoupler when the no-load signal is generated.

In the above embodiment, the abnormality signal detecting section generates a high level output when the output signal is generated in the overload detecting flip flop or the no load detecting flip flop, and the output terminal has a feedback circuit that feeds back a high level output to the input terminal A third ripple counter configured to maintain a high level output until a next reset; An abnormal signal detection transistor that is turned on when a high level signal is output from the third ripple counter; A relay connected in series to the abnormal-signal detecting transistor and excited when an overload or no-load occurs; And an abnormal signal output terminal connected to both sides of the contact of the relay.

According to another aspect of the present invention, there is provided a three-phase motor protection circuit comprising: first, second, and third phase power input terminals respectively connected to three phase power input lines; A current transformer connection terminal connected to a current transformer installed for monitoring the current of a motor which is operated by receiving power from the three-phase power input line; And an overload setting variable resistor and a no-load setting variable resistor connected in parallel between the first phase power input terminal and the second phase power input terminal, wherein the overload setting variable resistor and the no- A delay angle setting unit for outputting a signal having a phase delayed by a predetermined angle with respect to a phase of the first phase power source; A first diode and a second diode which are connected in parallel to each other in a reverse direction between a line commonly connected to one of the third phase power input terminal and the current transformer connecting terminal and a line connected to another terminal of the current transformer connecting terminal A square wave converting unit short-circuited to a voltage equal to or greater than a predetermined value obtained from the current transformer and converting an AC sine wave into a square wave; An amplifying unit amplifying the output of the square wave converting unit; An overload detection flip-flop for maintaining an output according to a parallax between a phase of a load current output from the amplifier and a delay angle set by the overload setting variable resistor for a wavelength; A load detecting flip-flop for holding an output according to a time difference between a phase of a load current outputted from the amplifying unit and a delay angle set by the no-load setting variable resistor for a wavelength; And an abnormality signal detecting unit for detecting and outputting an abnormality signal of the motor from the output of the overload detection flip-flop and the no-load detection flip-flop.

In the above embodiment, the abnormal signal detection section generates a high level output when the output signal of the overload detection flip-flop is generated, and a feedback circuit that feeds back the high level output to the input terminal is formed at the output terminal, A first ripple counter for maintaining a level output; A second ripple counter for generating a high level output when the output signal of the no-load detecting flip-flop is generated, and a feedback circuit for feeding back a high level output to an input terminal at the output terminal and maintaining a high level output until the next reset; A flicker signal output circuit for half-wave rectifying the AC input when no high-level output is generated in the first ripple counter and the second ripple counter and outputting a flicker signal indicating a steady state of the motor; An overload signal output circuit for outputting an overload signal indicating an overload of the motor when a high level signal is output from the first ripple counter; And a no-load signal output circuit for outputting a no-load signal indicating no-load of the motor when a high level signal is output from the second ripple counter.

The photocoupler may further include a photocoupler disposed downstream of the blink signal output circuit, the overload signal output circuit, and the no-load signal output circuit. The light emitting diode of the photocoupler is periodically turned on / off And is turned on by the no-load signal, and an abnormal signal output terminal is connected to the transistor input terminal and the output terminal of the photocoupler.

In the above embodiment, it further includes a bypass circuit portion for bypassing the overload signal output circuit portion from the input terminal of the photocoupler when the no-load signal is generated.

In the above embodiment, the abnormality signal detecting section generates a high level output when the output signal is generated in the overload detecting flip flop or the no load detecting flip flop, and the output terminal has a feedback circuit that feeds back a high level output to the input terminal A third ripple counter configured to maintain a high level output until a next reset; An abnormal signal detection transistor that is turned on when a high level signal is output from the third ripple counter; A relay connected in series to the abnormal-signal detecting transistor and excited when an overload or no-load occurs; And an abnormal signal output terminal connected to both sides of the contact of the relay.

According to the three-phase motor protection circuit of the present invention, by detecting the motor abnormality by comparing the delay angle of the current due to the change of the inductance of the motor and the delay angle of the preset voltage, the detection sensitivity can be precisely set It is possible to accurately detect the abnormality of the motor even if the magnetic saturation of the current transformer occurs.

1 is a circuit diagram illustrating a basic principle according to a first embodiment of the present invention,
2 is a circuit diagram illustrating a protection circuit according to a first embodiment of the present invention,
3 is a circuit diagram illustrating a modification of the first embodiment of the present invention,
4 is a circuit diagram illustrating a basic principle according to a second embodiment of the present invention,
5 is a circuit diagram illustrating a protection circuit according to a second embodiment of the present invention, and Fig.
6 is a circuit diagram illustrating a modification of the second embodiment of the present invention.

Hereinafter, specific embodiments according to the present invention will be described with reference to the accompanying drawings. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Parts having similar configurations and operations throughout the specification are denoted by the same reference numerals. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

In the following description of the embodiments, redundant descriptions and explanations of techniques obvious to those skilled in the art are omitted. Also, in the following description, when a section is referred to as "comprising " another element, it means that it may further include other elements in addition to the described element unless otherwise specifically stated.

 Also, the terms "to", "to", "to", and "modules" in the specification mean units for processing at least one function or operation, and may be implemented by hardware or software or a combination of hardware and software . In addition, when a part is electrically connected to another part, it includes not only a case directly connected but also a case where the other parts are connected to each other in the middle.

Terms including ordinals, such as first, second, etc., may be used to describe various elements, but the elements are not limited to these terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the second component may be referred to as a first component, and similarly, the first component may also be referred to as a second component.

The three-phase motor protection circuit of the present invention detects the abnormality of the motor using the phase delay characteristic of the load current. The present invention differs from the conventional anomaly detection method in that a method of detecting the amount of current flowing through a motor has been conventionally used. However, the present invention is applicable to a method of comparing a current delay angle due to a change in inductance of a motor and a voltage angle previously delayed by a variable resistor . In the conventional method, if abnormality detection is difficult due to magnetic saturation above the level of the current transformer, the three-phase motor protection circuit of the present invention can prevent the voltage of the current transformer from crossing between plus (+) and minus Of the inductance value is changed by the change of the inductance value regardless of the load.

In the following description, the three-phase motor protection circuit of the present invention will be described by dividing it into a first embodiment using a transformer and a second embodiment using no transformer. Figs. 1 to 3 show a first embodiment using a transformer, and Figs. 4 to 6 show a second embodiment without using a transformer.

1 is a circuit diagram illustrating a basic principle of a first embodiment of a three-phase motor protection circuit according to the present invention. Referring to FIG. 1, the three-phase motor operates by receiving power from a power source of a first phase (R phase), a second phase (S phase), and a third phase (T phase). The first phase (R phase), the second phase (S phase), and the third phase (T phase) are each a power source having a phase difference of 120 degrees. In the following description, R, S, Each of the S and T phases having a phase difference of 120 degrees with respect to the other phase is sufficient, and the order thereof can be changed.

Referring to FIG. 1, a transformer 100 is installed between the power input terminals of two other phases on the basis of an R phase (which may be replaced with an S phase or a T phase), and the center tap of the transformer 100 (CT) monitor installed to monitor the current of the motor from the line drawn from the line (tab). The phase of the power source drawn from the center tap of the transformer 100 has a phase difference of 180 degrees with respect to the R phase.

A variable resistor (VR) is provided between the R phase and the T phase (or between the R phase and the S phase). This variable resistor VR is for setting a delay angle with respect to the R phase, and is used as a reference value for detecting overload or no load in comparison with the load current phase.

2 is a circuit diagram illustrating a first embodiment of a three-phase motor protection circuit according to the present invention. Referring to FIG. 2, the three-phase power input terminals R, T, and S are terminals connected to the input lines of the three-phase power source applied to the motor, And the abnormal signal output terminals P1 and P2 are terminals for outputting a signal indicating a normal or abnormal state of the motor.

As illustrated in FIG. 1, a transformer 100 is disposed between the T phase and the S phase, and the center tap of the transformer 100 has a phase difference of 180 degrees with respect to the R phase. Between the T-phase and the S-phase, a rectifying circuit section 110 composed of half-wave rectifying diodes D1 and D2 and a capacitor C1 is provided. The rectifying circuit 110 is a circuit for rectifying and smoothing the AC input for supplying the IC operation power.

Connected between a line where a terminal (K) of one of a center tap of the transformer (100) and a current transformer connection terminal are connected in common and a line connected to another terminal (L) of a current transformer connection terminal, (D3) and a second diode (D4). The square wave converting unit 120 converts an AC sine wave into a square wave by shorting a voltage equal to or higher than a predetermined value obtained from the current transformer CT, for example, a voltage of 0.6 V or higher.

The output of the square-wave converting unit 120 is amplified by the amplifying unit 130. The amplifying unit 130 includes a combination of resistors R5, R6 and R7 and a transistor TR1. The amplifying unit 130 amplifies a voltage formed at both ends of the first diode D3 and the second diode D4, And supplies it to the flip-flop 200 and the flip-flop 300 for no-load detection.

Referring to FIG. 2, an overload setting unit is constructed by connecting an overload setting variable resistor VR1 and a fixed resistor R1 in series between an R phase and a T phase, a no-load setting variable resistor VR2 and a fixed resistor R2 ) Are connected in series to constitute a delay angle setting unit (140). The overload setting variable resistor VR1 and the no-load setting variable resistor VR2 set the delay angle with respect to the R phase within the range of 0 to 70 degrees.

The two outputs of the delay angle setting unit 140 are securely coupled to the overload detection flip-flop 200 and the no-load detection flip-flop 300 via the resistor circuit unit 150 composed of resistors R3 and R4.

The overload detection flip-flop 200 and the no-load detection flip-flop 300 are both "D" flip-flops, and the output according to the phase difference between the load current and the variable resistors VR1 and VR2 is maintained for one wavelength do. The overload indication LED (LED1) and the no-load indication LED (LED2) are connected to the output terminals of the overload detection flip-flop 200 and the no-load detection flip-flop 300, respectively.

The overload detection flip-flop 200 generates a high-level output and the overload indication LED (LED1) is turned on when an over load including a phenomenon such as short-circuiting between the coil layers of the motor, overheating, . During no light load or no load such as coil disconnection or idling, the no-load detection flip-flop 200 generates a high-level output, and the no-load display LED (LED2) is turned on.

An abnormal signal detector 700 for detecting and outputting an abnormal signal of the motor is connected to the output terminals of the overload detection flip flop 200 and the no load detection flip flop 300 as shown in FIG. The abnormal signal detector 700 includes a first ripple counter 400, a second ripple counter 500, a first ripple counter 400 and a second ripple counter 500, A flicker signal output circuit portion, an overload signal output circuit portion, and a no-load signal output circuit portion that constitute different circuits by the outputs of the counter 400 and the second ripple counter 500. The output of the overload detection flip flop 200 is transmitted to the first ripple counter 400 and the output of the no load detection flip flop 300 is transmitted to the second ripple counter 500. The first ripple counter 400 and the second ripple counter 500 receive the AC pulse for the timer from the resistor R9 and output the low level output of the overload detection flip flop 200 and the no load detection flip flop 300 The output is generated only for the length specified for the timer for the timer.

When the overload detection signal is applied to the first ripple counter 400, the high level output is fed back to the input terminal by the diode D5 to invalidate the clock pulse and maintains the high level output until the next reset. When the no-load signal is detected, the second ripple counter 500 is fed back to the input terminal by the diode D6 to maintain the high level output until the next reset.

When both the first ripple counter 400 and the second ripple counter 500 generate a low level output, the abnormal signal detector 700 functions as a flicker signal output circuit. That is, no output is generated in both the first ripple counter 400 and the second ripple counter 500 in the steady state of the motor. Therefore, the diode D7 connected to the AC input terminal performs half-wave rectification of the AC input, And outputs a flashing signal indicating the state. The flicker signal is connected to the resistor R10 and the photocoupler 180. The light emitting diode of the photocoupler 180 is periodically flickered by the half-wave rectified signal and the flicker signal indicating the steady state of the motor through the abnormal signal output terminals P1 and P2 connected to the input / output terminals of the photocoupler 180 Is output.

When the first ripple counter 400 generates the high level output, the abnormal signal detection unit 700 functions as the overload signal output circuit unit. A high level output is applied to the output terminal of the first ripple counter 400 so that the diode D8 supplies an overload signal, that is, a positive voltage, to the resistor R10. In this case, the light emitting diode of the photocoupler 180 maintains the ON state, and the overload signal is outputted through the abnormal signal connection terminal.

When the second ripple counter 500 generates a high level output, the abnormal signal detector 700 functions as a no-load signal output circuit. A high level output is applied to the output terminal of the second ripple counter 500 so that the bypass circuit portion 170 composed of the resistor R11 and the bypass transistor TR2 operates. The bypass transistor TR2 is turned on by the high level output generated by the second ripple counter 500 and the flickering signal or the overload signal applied to the resistor R10 regardless of the output of the first ripple counter 400 The signal (positive voltage) is bypassed through the bypass circuit unit 170 and the light emitting diode of the photocoupler 180 is turned off. At this time, no signal is output through the abnormal signal connection terminal, and the external state recognizes this state as no-load state.

On the other hand, FIG. 3 shows a modification of the first embodiment described above. In the example of FIG. 2, the photocoupler 180 is turned off to drive the photocoupler 180 in a non-loaded state, that is, when the photocoupler 180 is turned off, 3, the example of FIG. 3 shows an example in which the normal / abnormal state of the motor is classified into two stages according to the on / off drive of the relay.

Referring to FIG. 3, the circuit configuration up to the flip-flop 200 for overload detection and the flip-flop 300 for no-load detection is the same as that of FIG. Here, the embodiment of FIG. 3 uses only one ripple counter. As shown in the figure, the outputs of the overload detection flip-flop 200 and the no-load detection flip-flop 300 are commonly connected to the clock pulse input terminal of the third ripple counter 600.

When the overload detection signal or the no-load detection signal is applied from any one of the D flip-flops of the previous stage, the third ripple counter 600 is fed back to the input terminal of the high-level output by the diode D8 to invalidate the clock pulse, Level output.

The base terminal of the abnormality signal detection transistor TR3 is connected to the output terminal of the third ripple counter 600 and the abnormality signal detection transistor TR3 is turned on by the high level output of the third ripple counter 600 . At this time, the relay 190 is energized to turn off the relay contact 192, and an abnormal signal indicating overload or no load is outputted through the abnormal signal output terminals P1 and P2.

4 is a circuit diagram illustrating the basic principle of the second embodiment of the three-phase motor protection circuit according to the present invention. The second embodiment shown in Figs. 4 to 6 is a method in which a transformer is not used unlike the first embodiment, and other circuit configurations using the D flip-flop and the ripple counter are substantially the same as those in the first embodiment.

Referring to FIG. 4, a fixed resistor R0, a current transformer CT, and a variable resistor VR are provided between the S phase and the T phase. When the resistances of the fixed resistor R0 and the variable resistor VR are the same, the current transformer CT has a phase difference of 180 degrees with respect to the R phase. In this case, the three-phase motor protection circuit of the present invention Can be configured. As in the first embodiment, the variable resistor VR is for setting the delay angle with respect to the R phase, and the delay angle set by the variable resistor VR is a reference value for detecting overload or no load in comparison with the load current phase .

Fig. 5 is a circuit diagram illustrating a second embodiment of a three-phase motor protection circuit according to the present invention, and Fig. 6 is a circuit diagram showing a modification of the second embodiment. In the following description of the second embodiment with reference to FIGS. 5 and 6, the description of the circuit configuration which is the same as the first embodiment described above will be omitted.

5, a protection circuit portion 105 including a current limiting PTC (Th) and a capacitor C1 is provided between the T and R phases, and a zener diode D1, a diode (D2), and a smoothing capacitor (C2). The rectifying circuit portion 115 is a circuit for rectifying and smoothing the AC input for supplying the IC operation power.

A first diode D3 connected in parallel to each other in the reverse direction between a line to which one terminal K of the R phase input terminal and the current transformer connection terminal is commonly connected and a line connected to the other terminal L of the current transformer connection terminal, And a second diode (D4). The square wave converting unit 120 converts an AC sine wave into a square wave by shorting a voltage equal to or higher than a predetermined value obtained from the current transformer CT, for example, a voltage of 0.6 V or higher.

The output of the square-wave converting unit 120 is amplified by the amplifier 130 and is coupled to the overload detection flip-flop 200 and the no-load detection flip-flop 300, and the following circuit configuration is the same as that shown in FIG. 1 embodiment.

5, both of the first ripple counter 400 and the second ripple counter 500 generate a low level output and the abnormal signal output terminal P1, and P2, respectively. When the motor is in an overloaded state, a high level output is generated in the first ripple counter 400 and the photocoupler 180 is maintained in the on state. When the motor is in a no-load state, a high-level output is generated in the second ripple counter 500, and a signal applied to the resistor R10 is bypassed through the bypass circuit unit 170 to turn off the photocoupler 180 .

6 is a modification of the second embodiment. Circuit configurations up to the overload detection flip-flop 200 and the no-load detection flip-flop 300 are the same as those in the embodiment of FIG. 5, and after the third ripple counter 600 Is the same as the embodiment of Fig.

6, when an output is generated from any one of the overload detection flip-flop 200 and the no-load detection flip-flop 300, the third ripple counter 600 generates a high level output and is reset . As a result, the abnormal signal detection transistor TR3 is turned on and the relay 190 is excited, and an abnormal signal indicating an overload or no load is outputted through the abnormal signal output terminals P1 and P2.

The invention described above is susceptible to various modifications within the scope not impairing the basic idea. In other words, all of the above embodiments should be interpreted by way of example and not by way of limitation. Therefore, the scope of protection of the present invention should be determined in accordance with the appended claims rather than the above-described embodiments, and should be construed as falling within the scope of the present invention when the constituent elements defined in the appended claims are replaced by equivalents.

100: Transformer 105: Protection circuit
110: rectification circuit part 115: rectification circuit part
120: square wave converting unit 130: amplifying unit
140: Delay angle setting unit 150:
160: abnormal state display circuit unit 170: bypass circuit unit
180: Photo coupler 190: Relay
192: Relay contact point 200: Overload detection flip-flop
300: No-load detection flip-flop 400: First ripple counter
500: second ripple counter 600: third ripple counter
700: abnormal signal detection unit

Claims (10)

A first phase, a second phase, and a third phase power input terminal respectively connected to the three phase power input line;
A current transformer connection terminal connected to a current transformer installed for monitoring the current of a motor which is operated by receiving power from the three-phase power input line;
And an overload setting variable resistor and a no-load setting variable resistor connected in parallel between the first phase power input terminal and the second phase power input terminal, wherein the overload setting variable resistor and the no- A delay angle setting unit for outputting a signal having a phase delayed by a predetermined angle with respect to a phase of the first phase power source;
A transformer connected between the second phase power input terminal and the third phase power input terminal and having a center tap having a phase difference of 180 degrees with respect to the first phase power supply;
And a first diode and a second diode which are connected in parallel to each other in a reverse direction between a line commonly connected to one of the center tap of the transformer and the current transformer connection terminal and a line connected to the other of the current transformer connection terminals A square wave converting unit for short-circuiting a voltage equal to or greater than a predetermined value obtained from the current transformer to convert an AC sine wave into a square wave;
An amplifying unit amplifying the output of the square wave converting unit;
An overload detection flip-flop for maintaining an output according to a parallax between a phase of a load current output from the amplifier and a delay angle set by the overload setting variable resistor for a wavelength;
A load detecting flip-flop for holding an output according to a time difference between a phase of a load current outputted from the amplifying unit and a delay angle set by the no-load setting variable resistor for a wavelength; And
An abnormality detection unit for detecting and outputting an abnormality signal of the motor from the output of the overload detection flip-flop and the no-
Phase motor protection circuit.
The method according to claim 1,
Wherein the abnormality signal detecting unit comprises:
A first ripple counter for generating a high level output when an output signal of the overload detection flip flop is generated and a feedback circuit for feeding a high level output to an input terminal at an output terminal to maintain a high level output until the next reset;
A second ripple counter for generating a high level output when the output signal of the no-load detecting flip-flop is generated, and a feedback circuit for feeding back a high level output to an input terminal at the output terminal and maintaining a high level output until the next reset;
A flicker signal output circuit for half-wave rectifying the AC input when no high-level output is generated in the first ripple counter and the second ripple counter and outputting a flicker signal indicating a steady state of the motor;
An overload signal output circuit for outputting an overload signal indicating an overload of the motor when a high level signal is output from the first ripple counter; And
And a no-load signal output circuit for outputting a no-load signal indicating no-load of the motor when a high level signal is output from the second ripple counter,
Phase motor protection circuit.
3. The method of claim 2,
Further comprising an optocoupler disposed at a rear end of the flickering signal output circuit part, the overload signal output circuit part, and the no-load signal output circuit part,
The light emitting diode of the photocoupler is periodically turned on / off by the flickering signal, is turned on by the overload signal, is turned off by the no-load signal,
And an abnormal signal output terminal is connected to a transistor input terminal and an output terminal of the photocoupler.
The method of claim 3,
Further comprising a bypass circuit portion for bypassing the overload signal output circuit portion from an input terminal of the photocoupler when the no-load signal is generated.
The method according to claim 1,
Wherein the abnormality signal detecting unit comprises:
A feedback circuit for generating a high level output when the output signal is generated in the flip-flop for overload detection or the flip-flop for detecting no-load and a feedback circuit for feeding back a high level output to the input terminal is formed at the output terminal, A third ripple counter;
An abnormal signal detection transistor that is turned on when a high level signal is output from the third ripple counter;
A relay connected in series to the abnormal-signal detecting transistor and excited when an overload or no-load occurs; And
An abnormal signal output terminal connected to both the contacts of the relay
Phase motor protection circuit.
A first phase, a second phase, and a third phase power input terminal respectively connected to the three phase power input line;
A current transformer connection terminal connected to a current transformer installed for monitoring the current of a motor which is operated by receiving power from the three-phase power input line;
And an overload setting variable resistor and a no-load setting variable resistor connected in parallel between the first phase power input terminal and the second phase power input terminal, wherein the overload setting variable resistor and the no- A delay angle setting unit for outputting a signal having a phase delayed by a predetermined angle with respect to a phase of the first phase power source;
A first diode and a second diode which are connected in parallel to each other in a reverse direction between a line commonly connected to one of the third phase power input terminal and the current transformer connecting terminal and a line connected to another terminal of the current transformer connecting terminal A square wave converting unit short-circuited to a voltage equal to or greater than a predetermined value obtained from the current transformer and converting an AC sine wave into a square wave;
An amplifying unit amplifying the output of the square wave converting unit;
An overload detection flip-flop for maintaining an output according to a parallax between a phase of a load current output from the amplifier and a delay angle set by the overload setting variable resistor for a wavelength;
A load detecting flip-flop for holding an output according to a time difference between a phase of a load current outputted from the amplifying unit and a delay angle set by the no-load setting variable resistor for a wavelength; And
An abnormality detection unit for detecting and outputting an abnormality signal of the motor from the output of the overload detection flip-flop and the no-
Phase motor protection circuit.
The method according to claim 6,
Wherein the abnormality signal detecting unit comprises:
A first ripple counter for generating a high level output when an output signal of the overload detection flip flop is generated and a feedback circuit for feeding a high level output to an input terminal at an output terminal to maintain a high level output until the next reset;
A second ripple counter for generating a high level output when the output signal of the no-load detecting flip-flop is generated, and a feedback circuit for feeding back a high level output to an input terminal at the output terminal and maintaining a high level output until the next reset;
A flicker signal output circuit for half-wave rectifying the AC input when no high-level output is generated in the first ripple counter and the second ripple counter and outputting a flicker signal indicating a steady state of the motor;
An overload signal output circuit for outputting an overload signal indicating an overload of the motor when a high level signal is output from the first ripple counter; And
And a no-load signal output circuit for outputting a no-load signal indicating no-load of the motor when a high level signal is output from the second ripple counter,
Phase motor protection circuit.
8. The method of claim 7,
Further comprising an optocoupler disposed at a rear end of the flickering signal output circuit part, the overload signal output circuit part, and the no-load signal output circuit part,
The light emitting diode of the photocoupler is periodically turned on / off by the flickering signal, is turned on by the overload signal, is turned off by the no-load signal,
And an abnormal signal output terminal is connected to a transistor input terminal and an output terminal of the photocoupler.
9. The method of claim 8,
Further comprising a bypass circuit portion for bypassing the overload signal output circuit portion from an input terminal of the photocoupler when the no-load signal is generated.
The method according to claim 6,
Wherein the abnormality signal detecting unit comprises:
A feedback circuit for generating a high level output when the output signal is generated in the flip-flop for overload detection or the flip-flop for detecting no-load and a feedback circuit for feeding back a high level output to the input terminal is formed at the output terminal, A third ripple counter;
An abnormal signal detection transistor that is turned on when a high level signal is output from the third ripple counter;
A relay connected in series to the abnormal-signal detecting transistor and excited when an overload or no-load occurs; And
An abnormal signal output terminal connected to both the contacts of the relay
Phase motor protection circuit.

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