KR101691399B1 - Limiter device capable of contact failure detection having delay circuit - Google Patents

Abstract

According to the present invention, it is possible to provide a current limiting device capable of detecting contact failure with a delay circuit capable of precisely detecting a contact failure by counting the number of pulses in a predetermined phase range in which noises due to load characteristics are weak.
A current limiting apparatus capable of detecting a contact failure with a delay circuit according to the present invention includes: a high pass filter unit (110) for passing a noise pulse at a predetermined voltage level or more included in an AC power supply voltage; An amplifying part (115) arranged on an output side of the high pass filter part and amplifying the noise pulse passing through the high pass filter part; A pulse passing portion 125 configured to pass through only a pulse included in the phase of the AC power supply voltage from a zero potential point to a predetermined phase; A counter part (130) arranged at an output side of the pulse passing part, counting the number of fundamental waves of the AC power source, counting pulses included in the AC power source voltage and outputting a contact failure detection signal; A relay operation unit (140) for operating the relay in response to the contact failure detection signal; A shutoff switch (147) which is closed when the relay is not operating; A main circuit switch 145 connected in series with the isolation switch to form a main current path; When the relay is operated, a closing operation switch 149; A bypass circuit switch 150 connected in series with the operation switch to form a main current path; And a first counter 155 connected in series with the bypass circuit switch, wherein a reset terminal of the first counter in the counter unit is connected to a reset terminal of the first counter in a spark or an arc And a delay circuit configured not to count for the count value.

Description

TECHNICAL FIELD [0001] The present invention relates to a limiter device capable of detecting contact failure with a delay circuit,

The present invention relates to a current limiting device capable of detecting a contact failure, and more particularly to a current limiting device capable of detecting an arc or a spark due to a contact failure in an electric circuit and reducing a malfunction due to on / The present invention relates to a current limiting device capable of detecting contact failure.

About 30% of all fires are electric fires, more than 60% of them are caused by fault of wiring system. Most of fires due to fault of wiring system are caused by overheating due to contact failure, faulty arc or line insulation It is a tracking / arc accident.

Such wiring system accidents generally have a problem that preventive inspection can not be performed. In particular, insulation failure caused by contamination or carbonization of the line insulation is a type of load current, and thus can not be measured by a conventional grounding- .

In the case of such a line-to-line fault, that is, a line-to-line short-circuit, the arc discharge of a minute thread is continued only in a dark state because of a slight current arc discharge. It changes.

Also, due to the nature of the arc discharge, a discharge is caused along a trajectory in which a current can flow well. In other words, the shape of the lightning arc is similar to the twisted shape of a twig. In the case of such a tracking arc, the arc current is so small that it can not be detected by conventional arc detection technology. In general arc breakers, the shape of the current waveform flowing to the load, the magnitude of the distortion current It is impossible to detect the tracking current, which is a microscopic current, because it is indistinguishable from the noise included in the power when the arc current is small.

Currently, the certification of the arc breaker or arc alarm is also based on the load current of 5 amperes [A]. However, 5 amps [A] is a very large current value, so it can not be regarded as a current value that prevents electric fire in a state where the carbonization of the insulator proceeds considerably due to poor contact.

On the other hand, Korean Patent No. 0914999, an arc detecting circuit breaker of a low-voltage indoor arc furnace maintains a linear characteristic in a low frequency and high frequency range, prevents damage including a fire due to a parallel arc current, A current transformer CT for detecting a parallel arc current using a current as a detection parameter; An integrating unit for integrating a signal detected by the current sensor; A filter unit for removing high frequency noise from the signal integrated by the stochastic integration unit and limiting the current; A rectifying section for full-wave rectifying a signal passing through the upper filter section; An amplifying unit for amplifying a signal rectified by the rectifying unit; A converter for converting a current amplified by the amplifying unit into a voltage; An SCR in which a current signal is directly applied to a gate, And a trip coil connected to the anode side of the upper SCR and operating the circuit breaker to shut off the circuit.

Also, the arc detection apparatus of a low-voltage indoor converter disclosed in Korean Patent Laid-Open Publication No. 2013-0095947 includes a CT installed between an external voltage input line and a lower end; An arc detector for detecting a current due to an arc defect from the CT; A voltage phase detector for detecting a phase of a voltage currently input to the power supply line; And comparing the detected voltage phase with a current to determine an arc characteristic when an arc is generated in a current in a voltage phase of the arc recognition interval and determines the arc characteristic as a load characteristic when an arc is generated in a current phase in a voltage phase of the other section .

However, since an apparatus for detecting an arc by detecting an electric current as described above uses a current transformer (CT), if a magnetic saturation phenomenon occurs in a core in a current transformer, the inductance value varies depending on the size of the load, . It is also included in a current input by a capacitor (for example, a capacitor coupled to a power supply device, a capacitor required for an EMI filter, a capacitor coupled with a constant temperature heating wire, or a capacitor used for power factor correction and noise removal) The total harmonic current is limited and it is limited to detection with high sensitivity. In addition, if a current transformer is used, it may be inconvenient to install, move, or the like because it passes power.

Korean Patent Registration No. 10-0914999 Arc detection circuit breaker for low-voltage indoor arc furnace Korean Unexamined Patent Application Publication No. 10-2013-0095947 Arc detection apparatus and method Korean Patent No. 10-1036665 Korean Patent No. 10-0981824 A breakdown current-driven breaker

SUMMARY OF THE INVENTION An object of the present invention is to provide an apparatus and a method for accurately detecting a contact failure by counting the number of pulses in a predetermined phase range in which noises due to load characteristics are weak, A current-limiting device capable of detection is provided.

A current limiting apparatus capable of detecting a contact failure with a delay circuit according to the present invention includes: a high pass filter unit (110) for passing a noise pulse at a predetermined voltage level or more included in an AC power supply voltage; An amplifying part (115) arranged on an output side of the high pass filter part and amplifying the noise pulse passing through the high pass filter part; A pulse passing portion 125 configured to pass through only a pulse included in the phase of the AC power supply voltage from a zero potential point to a predetermined phase; A counter part (130) arranged at an output side of the pulse passing part, counting the number of fundamental waves of the AC power source, counting pulses included in the AC power source voltage and outputting a contact failure detection signal; A relay operation unit (140) for operating the relay in response to the contact failure detection signal; A shutoff switch (147) which is closed when the relay is not operating; A main circuit switch 145 connected in series with the isolation switch to form a main current path; When the relay is operated, a closing operation switch 149; A bypass circuit switch 150 connected in series with the operation switch to form a main current path; And a first counter 155 connected in series with the bypass circuit switch, wherein a reset terminal of the first counter in the counter unit is connected to a reset terminal of the first counter in a spark or an arc And a delay circuit configured not to count for the count value.

The predetermined phase may be 20 to 30 degrees or 200 to 210 degrees based on the applied potential of the AC power source.

The counter may further include: a second counter that outputs a first state signal when the fundamental wave of the AC power source reaches the second number; And a second reset circuit which is reset at the output of the second counter and counts a first number or more of pulses included in the AC power supply while the fundamental wave of the AC power supply reaches the second number, And a counter.

In addition, the first and second counters are reset in response to the first status signal output from the second counter.

Further, the cutoff switch and the operation switch operate alternately.

Further, the current-flow portion is a superconductor.

According to the current limiting device of the present invention, since no current transformer is used, it is not restricted by the installation position of the circuit because it is independent of the load current, and does not detect instantaneous spark / arc, and operates in continuous or repetitive case.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a circuit diagram of a current-limiting device capable of detecting contact failure with a delay circuit according to an embodiment of the present invention; and Fig.
2 is a main part timing diagram of a fault current detectable current limiting device with a delay circuit according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

All measurable electrical loads are subject to harmonic component noise at a point exceeding 25 degrees of phase of the AC sine wave voltage waveform. This is considered to be because the source of noise generation is weak when the instantaneous voltage is near 0 volt.

However, if there is a contact failure, noises of the harmonic components are generated irrespective of the magnitude of the instantaneous voltage even in the phase 0 to 25.

For example, in an EMI filter in which a capacitor of 0.1 microfarads is built in line, noises of harmonic components are generated irrespective of the phase angle of the power supply voltage at the time of poor contact.

As another example, in a case of a constant temperature hot wire of a polymer material having a line capacitance of 0.1 microfarads per meter, a noise of a very large harmonic component of 15 volts or more at the time of poor contact occurs regardless of the phase angle of the power supply voltage.

As another example, in a small fan motor having a 10-watt (W) class inductive load, a very large harmonic component noise of 15 volts or more occurs regardless of the phase angle of the power supply voltage due to counter-electromotive force at the time of poor contact.

Fig. 1 is a circuit diagram of a current-limiting device capable of detecting a contact failure with a delay circuit according to an embodiment of the present invention. Fig. 2 is a timing chart showing the main part timing of a fault current detectable fault device having a delay circuit according to an embodiment of the present invention .

The contact failure detecting apparatus having the delay circuit according to an embodiment of the present invention includes a surge protection unit 105, a high pass filter unit 110, an amplification protection unit 113, an amplification unit 115, A relay unit 140, a main circuit switch 145, a bypass circuit switch 150, and a current limiting unit 155, a pulse passing unit 125, a counter unit 130, a reset unit 135, ).

The surge protection section 105 is disposed between the input power supply line L and the ground line G and may be a metal oxide varistor.

The high-pass filter unit 110 passes a noise pulse of a predetermined voltage level or lower included in the power source.

The amplification protection unit 113 is disposed between the output side of the high pass filter unit 110 and the ground and outputs a noise pulse of a predetermined voltage level (for example, 12V) or more, which passes through the high pass filter unit 110, (105) to protect the amplifying inverter (U1).

The amplifying unit 115 is disposed on the output side of the high pass filter unit 110 and amplifies the noise pulse passing through the high pass filter unit 110 at a predetermined voltage level or higher.

The operating power generating unit 120 is connected in parallel between the input power line L and the ground line G to generate operating power.

The pulse passing portion 125 is configured to pass a pulse included in the phase range of 0 to 25 degrees. 2, the inverter U3 outputs "Low (0)" in the second half cycle (phase 0 to 180 degrees) of the power supply voltage or " High (1) "is output (N2). Assuming that the noise included in the power supply is uniformly distributed regardless of the phase (N3), the No Gate (U4) sets "High (1)" when the input is "Low" (N4). Using the time constant of the resistor R10 and the capacitor C8, the inverter U5 outputs a square wave delayed by a predetermined time from the output of the inverter U3 (N5). At this time, the time constant of the resistor R10 and the capacitor C8 may correspond to a phase angle of about 25 degrees. The NAND gate U6 receiving the outputs of the inverters U5 and U4 outputs "Low (0)" when there is noise of harmonic components occurring within the phase angle of 0 to 25 degrees.

The first ripple counter IC1 counts the number of noise pulses. If the number of the noise pulses is equal to or greater than a predetermined number, the counter unit 130 outputs a "H" And the second ripple counter IC2 counts the frequency of the power supply voltage to determine the counting time of the first ripple counter IC1. That is, since the frequency of the power supply voltage is 60 Hz, the second ripple counter IC2 outputs a "H" state signal to reset itself and the first ripple counter IC1 at the 32nd cycle when 0.53 seconds have elapsed, The ripple counter (IC1) outputs the "H" status signal when more than 64 noise pulses are counted within 0.53 seconds.

Reset section 135 includes a programmable single junction transistor (PUT) disposed between the output of the second ripple counter IC2 and the reset terminal.

That is, when the pulse output of the NAND gate U6 in the pulse passing portion 125 transits to the "L" state signal, the PUT is turned on to switch the first and second ripple counters from the reset state to the set state, When the 2 ripple counter IC2 outputs the "H" state signal, the PUT is turned off by the reverse voltage and is switched to the reset state.

The relay operation unit 140 includes a relay coil connected to the output of the first ripple counter IC1.

The start of operation of the first ripple counter IC1 is delayed by connecting the resistor R12 and the capacitor C9 to the reset terminal of the first ripple counter IC1.

In other words, when the pulse output of the NAND gate U6 in the pulse passing portion 125 transits to the "L" state signal, PUT is turned on and the second ripple counter IC2 is switched from the reset state to the set state , The first ripple counter IC1 is switched from the reset state to the set state after a predetermined time (the time constant by the resistor R12 and the capacitor C9) has elapsed, and the second ripple counter IC2 is switched to the "H" At the moment of outputting the status signal, PUT is turned off by the reverse voltage and waits in the reset state.

As a result, the spark or the arc which occurs when the first Rip Counter IC1 is reset by the time delay of the resistor R12 and the capacitor C9 on and off is not counted. Specifically, by not counting pulses for 1 Hz (16 ms), malfunction due to on-off switching can be prevented.

The following explains whether or not the contact is bad.

Since the relay coil RL does not operate during a normal state without a contact failure, the cutoff switch 147 is closed and the main current flows via the main circuit switch 145 and the cutoff switch 147. [

The operation switch 149 is closed while the cutoff switch 147 is opened and the main current is supplied to the operation switch 149 and the bypass circuit switch 150 ), And the current-limiting part 155, as shown in Fig.

Meanwhile, the current limiting device having the delay circuit according to an embodiment of the present invention operates the main circuit switch 145 and the bypass circuit switch 150 so that the superconductor of the current limiting part 155 is turned off before the phase transition to the resistor 147), and completes the line change. Thereafter, the current flows through the phase transition of the superconductor provided in the current limiting section 155 in the current limiting device, and a high-speed current is performed within a half period.

In the current limiting device according to the present invention, when a contact failure is detected, the current limiting section 155 is disposed only in the bypass circuit through which a faulty contact current flows, so that the current can be started before the fault current improves sufficiently.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood that various modifications and changes may be made without departing from the scope of the appended claims.

105: surge protection unit 110: high pass filter unit
113 amplification protection unit 115 amplification unit
120: operating power generating unit 125: pulse passing unit
130: Counter unit 135:
140: Relay operation part 145: Main circuit switch
150: bypass circuit switch 155:

Claims (6)

A high-pass filter unit (110) for passing a noise pulse at a predetermined voltage level or more included in the AC power supply voltage;
An amplifying part (115) arranged on an output side of the high pass filter part and amplifying the noise pulse passing through the high pass filter part;
A pulse passing portion 125 configured to pass through only a pulse included in the phase of the AC power supply voltage from a zero potential point to a predetermined phase;
A counter part (130) arranged at an output side of the pulse passing part, counting the number of fundamental waves of the AC power source, counting pulses included in the AC power source voltage and outputting a contact failure detection signal;
A relay operation unit (140) for operating the relay in response to the contact failure detection signal;
A shutoff switch (147) which is closed when the relay is not operating;
A main circuit switch 145 connected in series with the isolation switch to form a main current path;
When the relay is operated, a closing operation switch 149;
A bypass circuit switch 150 connected in series with the operation switch to form a main current path; And
(155) of the superconductor in series with the bypass circuit switch,
Wherein the reset terminal of the first counter in the counter unit includes a delay circuit configured not to count a spark or an arc included in a first period starting from the power-up of the fundamental wave of the power source voltage,
The shutoff switch and the operating switch alternately operate
Current limiting device capable of detecting contact failure.
The method according to claim 1,
Wherein the predetermined phase is 20 to 30 degrees or 200 to 210 degrees with respect to the electric potential of the AC power source.
The apparatus according to claim 1,
A second counter for outputting a first state signal when the fundamental wave of the AC power source reaches a second number; And
A first counter for resetting the output of the second counter and outputting a contact failure detection signal when the first number of pulses included in the AC power supply is counted while the fundamental wave of the AC power supply reaches the second number,
And a delay circuit including the delay circuit.
The method of claim 3,
Wherein the first and second counters are reset in response to the first status signal output from the second counter.
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