KR101547597B1 - Apparatus for detecting electrical degradation current of surge protecting device - Google Patents

Abstract

The present invention relates to an apparatus for diagnosing degradation of a surge protection apparatus. The apparatus for diagnosing degradation of the surge protection apparatus according to the present invention comprises: a surge protecting device which is electrically connected between a ground port and a supply port supplied with electricity or an external signal; and a fuse which is formed using a bi-metal or a shape-memory alloy transformed by heat, and maintains on-state of an electrical connection state between the surge protection device and the supply port in case a leakage current through the surge protection device does not occur, and maintains off-state of the electrical connection state between the surge protection device and the supply port by responding to the heat generated by a leakage current in case the leakage current occurs through the surge protection device. In case the fuse repeats on-state and off-state, it is judged as an initial fault state of the surge protection device.

Description

TECHNICAL FIELD [0001] The present invention relates to a surge protection device deterioration diagnosis apparatus,

More particularly, the present invention relates to a surge protection element deterioration diagnosis apparatus capable of knowing in advance a failure of a surge protection element and preventing damage due to a surge even in the event of a failure .

Electromagnetic Pulse (EMP) refers to a large energy that occurs naturally or artificially. A natural EMP can be a lightning stroke, and an artificial EMP can pulse a strong energy generated when a nuclear bomb or an electronic bomb explodes. .

As described above, the electronic devices exposed to the EMP can be seriously damaged due to the influence of a large energy pulse, so that the electronic equipment functioning as an important task can be protected from external electromagnetic waves It is in urgent need to take measures for

At present, it is urgent to take measures to protect important national facilities and weapon system equipment from electromagnetic pulse bombs, which are estimated to have completed EMP bomb development in North Korea.

However, EMP protection (anti-wavelength) equipment has a problem that it requires a huge budget and a lot of preparation time.

In order to solve this problem, an EMP filter for blocking an electromagnetic pulse (EMP) is manufactured and used.

Such an EMP filter shields electromagnetic pulses, but surges are also required to be blocked, so a surge protector is additionally provided. An example of such a surge protection device is MOV (Metal Oxide Varistor).

The MOV is typically connected between a power supply terminal or an external signal input terminal and a ground terminal. When a voltage higher than a certain voltage is applied by using the asymmetric effect of the current, the current flows to the ground terminal I will go.

That is, the MOV maintains the electrically open state at normal times, and when a high voltage such as a surge voltage is input, the MOV becomes electrically short, and the incoming surge flows to the ground terminal. This protects the EMP filter (or internal circuit) from a high voltage such as a surge.

This MOV should be kept open electrically when the surge does not flow. However, if there is an abnormality due to the deterioration of the MOV device, the leakage current is generated at the initial stage of the fault and then stopped. Repeatedly occurs, and in a completely failed state, the leakage current is excessively generated, so that a short state is maintained.

When the MOV is short-circuited and the short-circuit state is maintained, the EMP filter connected to the MOV fails to exhibit its function, thereby damaging the electronic devices to be protected. However, There is no known method to date.

In the conventional case, the inspector has a separate leakage current measuring device, and the inspector manually measures the leakage current of the MOV to determine whether or not the fault has occurred. However, this method is not efficient and takes a long time and cost.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a surge protection element deterioration diagnosing apparatus capable of overcoming the above-described conventional problems.

It is another object of the present invention to provide a surge protection element deterioration diagnosis apparatus capable of realizing an initial deterioration and a failure state of a surge protection element in real time.

It is still another object of the present invention to provide a surge protection element deterioration diagnosis apparatus capable of protecting an EMP filter (or an internal circuit) from a high voltage such as a surge.

According to an embodiment of the present invention, there is provided a surge protection element deterioration diagnosis apparatus comprising: a surge protection element that is electrically connected between a supply terminal to which power is supplied or an external signal is supplied, A protection element; And when the leakage current is not generated through the surge protection element, the electrical connection state between the surge protection element and the supply terminal is maintained in an ON state And a fuse for maintaining an electrical connection state between the surge protection element and the supply terminal in an OFF state in response to heat generated by a leakage current when a leakage current is generated through the surge protection element And determines that the surge protection element is in an initial failure state when the fuse repeats the ON state and the OFF state.

The surge protector may be a metal oxide varistor (MOV).

Wherein the fuse includes a spindle connected between a first terminal of the surge protection element to which the second terminal is connected to the ground terminal and the supply terminal, and a shape memory alloy spring into which the spindle is inserted, The tension of the spring varies according to the heat generated by the leakage current, so that the spindle is moved to maintain the electrical connection between the surge protection element and the supply terminal in an on state or an off state.

The surge protection element deterioration diagnosing apparatus diagnoses the deterioration due to deterioration of the surge protection element when the on state and the off state are repeated for a predetermined time by the fuse or when the off state is continued for a predetermined time by the fuse And a warning unit for notifying the failure of the surge protection element.

The warning unit may include an LED that is turned on when the fuse is in an open state or an alarm signal generator that is transmitted to a remote location through a wired / wireless communication network when the fuse is open.

The surge protection element deterioration diagnosis apparatus includes: a supplementary surge protection element; Further comprising at least one switch operable in response to an open state signal of the fuse when the fuse is in an open state, wherein when the fuse is in an open state, So that the protection terminal has an electrically connected state between the supply terminal and the ground terminal.

According to the present invention, it is possible to detect and confirm, in real time, a failure state such as an initial deteriorated state and a completely deteriorated state in which a leakage current of a surge protection element such as MOV repeats occurrence or non-occurrence of leakage, The surge can be blocked through the protection element.

1 is a circuit diagram of a surge protection element deterioration diagnosis apparatus according to a first embodiment of the present invention,
Fig. 2 shows a schematic diagram and operational state diagram of the fuse F of Fig. 1,
3 is a circuit diagram of a surge protection element deterioration diagnosis apparatus according to a second embodiment of the present invention,
Figs. 4 to 7 are schematic external views of the surge protection element degradation diagnostic apparatus of Fig. 1. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings without intending to intend to provide a thorough understanding of the present invention to a person having ordinary skill in the art to which the present invention belongs.

1 is a circuit diagram of a surge protection element deterioration diagnosis apparatus 100 according to a first embodiment of the present invention.

1, the surge protection element deterioration diagnosis apparatus 100 according to the first embodiment of the present invention includes a surge protection element S1, a fuse F, and a warning unit 150. [ The warning unit 150 includes a photocoupler PC, an LED lamp LD1 and an LD2 and various protection devices D1, D2, D3, D4, R1, R2 and R3.

The surge protection element S1 is an element for surge protection and is electrically connected between a supply terminal H and a ground terminal L to which power is supplied from an EMP filter or the like or an external signal is supplied.

The surge protection element S1 may be a metal oxide varistor (MOV), but it may be formed of at least one element selected from a Transient Voltage Suppression (TVS) diode, a discharge gap arrestor, a SIC varistor and a zener diode Can be selected.

The surge protection element S1 maintains an open state when a surge does not flow and shorts when a surge is introduced so that a surge flowing into the supply terminal H is connected to a ground terminal (L), thereby protecting an internal circuit (not shown) such as an EMP filter.

The fuse F may be formed using a shape memory alloy or bimetal which is deformed by heat. The fuse F maintains the electrical connection between the surge protection element S1 and the supply terminal H in an ON state when no leakage current is generated through the surge protection element S1, When a leakage current is generated through the surge protection element S1, the electrical connection state between the surge protection element S1 and the supply terminal H is turned off in response to heat generated by the leakage current .

Fig. 2 is a schematic view of the fuse F shown in Fig. 1, which uses a shape memory alloy spring (Shape Memory Alloy Spring).

The shape memory alloy has a transformation force that returns to its original shape at an arbitrary temperature even if its shape is changed by physical impact with an alloy of titanium and nickel. This transformation force is different from that of titanium and nickel depending on the content of titanium and nickel. It has properties.

Therefore, the tensile force is maintained at a constant temperature range (room temperature), so that the tensile force is increased at a constant temperature range (for example, a temperature range elevated by heat generated by the leakage current) It is possible to construct the fuse by using the shape memory alloy spring thus constructed.

2, the fuse F includes a conductive housing 30 having an internal space and an insulator 25 interposed between the housing 30 and the inside of the housing 30, A first lead terminal 10 inserted into one side of the space, a second lead terminal 20 electrically connected to the housing, a second lead terminal 20 disposed in an inner space of the housing 30, A shape memory alloy spring 50 which is disposed between the spindle 60 and the first lead terminal 10 inserted in the inner space while covering one side of the spindle 60; And a bias spring 40 electrically connected to the other side of the spindle 60 and the housing 30 and disposed between the other side of the spindle 60 and the other side of the inner space.

The spindle 60 has a structure in which the shape memory alloy spring 50 is disposed on one side and the bias spring 40 is disposed on the other side.

The first lead terminal 10 is electrically connected to the supply terminal H and the second lead terminal 20 is connected to the other end of the surge protection element S1, And have an electrically connected structure.

2 (a), the fuse F is electrically short-circuited with the first lead terminal 10 when the spindle 60 is normally in a temperature range below the transition temperature in the normal temperature range the shape memory alloy spring 50 maintains a state where the tensile force of the shape memory alloy spring 50 is smaller than the tensile force of the bias spring 40 so as to maintain the short state.

However, when a leakage current is generated and a leakage current is applied to the bias spring 40, as shown in FIG. 2 (b), the bias spring 40 generates heat due to its own resistance value, So that the internal temperature of the housing 30 is increased. When the internal temperature of the housing 30 rises, the shape memory alloy spring 50 is stretched according to the increased temperature. As a result, the tensile force of the shape memory alloy spring 50 becomes larger than the tensile force of the bias spring 40. As the tensile force of the shape memory alloy spring 50 increases, the shape memory alloy spring 50 The spindle 60 is moved in the other direction within the inner space of the housing 30 by pushing the spindle 60 so that the first lead terminal 10 and the spindle 60 are electrically opened ) State.

When the temperature of the housing 30 is lowered due to the disappearance of the leakage current, the tensile force of the shape memory alloy spring 50 is small and it is restored to a normal state.

Since the surge protection element S1 repeatedly generates a state in which a leakage current is generated and a state in which no leakage current occurs during an initial failure, the surge protection element S1 is repeatedly turned on and off, S1) can be known.

For this state, the tension spring of the shape memory alloy spring 50 at the transition temperature or less (when no leakage current is generated) is smaller than the tensile force of the bias spring 40, and when the transition temperature is higher than the transition temperature , The tensile force of the shape memory alloy spring 50 should be designed to be larger than the tensile force of the bias spring 40. [

If the surge protection element S1 is completely broken or short-circuited, the leakage current exceeds the allowable range. Therefore, the biasing spring 40 is designed to be cut off so that it has a general fuse function.

The warning unit 150 turns on the green LED lamp LD1 indicating that the fuse F is in the on state and informs the surge protection device S1 that the green LED lamp LD1 is in the steady state, To inform the user of an initial failure state or a complete failure state due to the deterioration of the surge protection element S1 by turning on a red LED lamp LD2 indicating a failure of the surge protection element S1.

The configuration of the warning unit 150 will be described below.

The photocoupler PC is electrically connected to the first lead terminal 10 of the fuse F or to the first input terminal (anode) 1 of the other terminal of the surge protection element S1, The terminal (cathode) 2 may have a structure electrically connected to the ground terminal L.

A photocoupler (PC) is an optical composite device that optically couples (couples) a light-emitting element and a light-receiving element and combines them into one package, which is advantageous in that signals can be transmitted in a state in which a circuit and a circuit are electrically insulated.

A diode D1 is connected between the first lead terminal 10 of the fuse F or the other terminal of the surge protection element S1 and the first input terminal 1 for protection and operation of the photocoupler PC, And a resistor R1 may have a serial connection structure and a Zener diode D4 may be connected between the first input terminal 1 and the second input terminal 2 of the photocoupler PC.

A first output terminal (collector) 3 of the photocoupler PC is connected to a first node n1 and a second output terminal (emitter) 4 of the photocoupler PC is connected to the green LED And may be connected to one end of the lamp LD1. The other end of the green LED lamp (LD1) is electrically connected to the ground terminal (L).

A diode D2 and a resistor R2 are connected in series between the supply terminal H and the first node n1 and a reverse current prevention is provided between the first node n1 and the ground terminal L The diode D3, the resistor R3, and the red LED lamp LD2 have a series connection structure.

The warning unit 150 operates as follows.

The voltage supplied through the supply terminal H is half-wave rectified by the diode D1 so that the voltage is lowered to the photocoupler PC via the first input terminal 1 An input signal is supplied. Since the photocoupler PC operates in response to the input signal, the supply voltage of the supply terminal H passes through the diode D2 and the resistor R3, 1 output terminal 3 and a voltage applied to the first output terminal 3 is applied to the green LED lamp LD1 through the second output terminal 4 so that the green LED lamp LD1, . At this time, no signal or voltage is applied to the red LED lamp LD2.

In the off state of the fuse F, the fuse F is turned off and no signal is input to the photocoupler PC, so that the photocoupler PC does not operate. Accordingly, the voltage or the signal of the supply terminal H is applied to the red LED lamp LD2 through the first node n1 to light the red LED lamp LD2.

Thus, it is possible to know whether the surge protection element S1 is faulty or not.

The green LED lamp LD1 and the red LED lamp LD2 correspond to the on state and the off state of the fuse F during the initial failure or the initial deterioration of the surge protection element S1, And turns on alternately. Then, when the surge protection element S1 is completely broken and the bias spring 40 of the fuse F is completely cut off, the red LED lamp LD2 is kept on.

Accordingly, when the LED lamps LD1 and LD2 are alternately turned on, the surge protection element S1 is in an initial failure state, and when the red LED lamp LD2 is continuously lit, It is possible to know that it is in a completely failed state.

According to another embodiment, a warning signal generator (not shown) may be provided in place of the LED lamps LD1 and LD2. The warning signal generator may transmit a signal to the remote location through the wired / wireless communication network so that the surge protection element S1 may be informed of the failure of the fuse F when the fuse F is open. In this case, it is possible to transmit the signal only when the fuse F is in the open state, or to transmit the signal even when the fuse F is in the on state.

The warning signal generator may be provided separately from the LED lamps LD1 and LD2.

In the case of the above-described surge protection element deterioration diagnosis apparatus 100, the surge protection element can be recognized early, and can be effectively countered. However, after the surge protector fails, quick replacement work is required. When a surge is introduced, internal circuits such as an EMP filter may be damaged. Therefore, even in the case of a failure of the surge protection device, a method of protecting the internal circuit and the like is required.

3 is a circuit diagram of a surge protection element deterioration diagnosis apparatus 200 according to a second embodiment of the present invention.

3, the surge protection element deterioration diagnosis apparatus 200 according to the second embodiment of the present invention includes a surge protection element S1, a fuse F, a warning unit 150, (S2) and a complementary unit (180). In the case of the surge protection element S1, the fuse F and the warning unit 150, the configuration, the connection structure and the operation are the same as those of the first embodiment of the present invention.

The complementary unit 180 includes a first switch SW, a second switch Q1, and protection elements D5, R4, and R5.

When the first switch SW is composed of a relay switch, one end of the coil is connected to the supply terminal H via the diode D5 and the resistor R4, and the other end of the coil is connected to the third node n3 . That is, a diode D5 is connected between the supply terminal H and the resistor R4, and a coil is connected between the resistor R4 and the third node n3. The first contact A of the first switch SW is connected to one end of the complementary surge protection element S2 and the second contact B of the first switch SW is connected to the supply terminal (H).

Therefore, when a current flows through the coil of the first switch SW, the first contact A and the second contact B are electrically connected to each other so that the complementary surge protective element S2 is electrically connected to the supply terminal The first contact A and the second contact B are electrically disconnected from each other and thus the complementary surge protective element S2 is electrically connected to the first contact A and the second contact B. Therefore, And is not electrically connected to the supply terminal H.

The second switch Q1 may be an n-channel transistor and is connected to a second node n2, which is a node between the resistor R3 and the red LED lamp LD2, via a resistor R5. (Or a gate) is connected to the third node n3, and an emitter (or a source) is connected to the ground terminal L and a collector (or drain) is connected to the third node n3. That is, the resistor R5 is connected between the second node n2 and the base (or gate) of the second switch Q1.

The second switch Q1 is turned on when the red LED lamp LD2 is lit, that is, when the fuse F is off, and when the green LED lamp LD1 is lit, that is, when the fuse F F is in the ON state, it is in the OFF state to interrupt the current.

The complementary surge protection element S2 has one end connected to the first contact A of the first switch SW and the other end connected to the ground terminal L. [

The complementary unit 180 operates as follows.

In the on state of the fuse F, no signal or voltage is applied to the red LED lamp LD2, so that the second switch Q1 is shut off, so that the first switch SW does not operate The supply terminal H and the supplementary surge protection element S2 are not electrically connected because the first contact A and the second contact B are separated from each other.

In this case, since the surge protection element S1 operates normally, the supplementary surge protection element S2 is not required.

The voltage or the signal of the supply terminal H is applied to the red LED lamp LD2 through the first node n1 and the second node n2 in the off state of the fuse F, The LED lamp (LD2) is turned on. In this case, since a voltage or a signal is applied to the base (or gate) of the second switch Q1 through the second node n2, the second switch Q1 operates to turn on the third node n3, And the ground terminal (L). As a result, a current flows through the coil of the first switch SW, so that the first contact A and the second contact B are electrically connected to each other, The surge protection element S2 is electrically connected.

Since the surge protection element S1 is in a completely failed state or an initial failure state, the surge protection element S2 can cope with the surge protection element S2 when a surge is introduced.

Figs. 4 to 7 are schematic views of the external appearance of the surge protection element degradation diagnosis apparatus 100 of Fig. 6 and 7 illustrate the case where the deterioration diagnosis apparatus 100b (the surge protection element S1) is connected to the surge protection element S1 which is installed in advance, ) Are connected to each other.

4 and 5, the surge protection element deterioration diagnosis apparatus 100a includes a surge protection element S1, a fuse F, and other elements corresponding to the circuit shown in Fig. 1 in a rectangular case C1 (PCB) equipped with elements to be mounted, and the input terminal, the output terminal, and the detection terminal are exposed to the outside. And the LED lamp LD2 is exposed to the outside. Here, the LED lamp LD1 is not installed.

6 and 7, the surge protection element deterioration diagnosis apparatus 100b is configured in such a manner that the surge protection element S1 can be connected to the outside, so that the surge protection element S1 can be connected to the fuse F and a circuit board PCB on which elements corresponding to the circuit shown in FIG. 1 are mounted are housed in a case C2 so that the input terminal L1, the output terminal L2 and the detection terminal L3 are exposed to the outside Structure. And the LED lamp LD2 is exposed to the outside. Here, the LED lamp LD1 is not installed.

The surge protection element deterioration diagnosis apparatus 100b is mounted on a surge protection element S1 that is already provided for diagnosis of a failure.

As described above, according to the present invention, it is possible to detect and confirm, in real time, a failure state such as an initial deteriorated state or a completely deteriorated state in which a leakage current of a surge protective element such as MOV is repeatedly generated or not, It has the advantage of being able to block the surge through a surge protection device for complementary purposes.

The foregoing description of the embodiments is merely illustrative of the present invention with reference to the drawings for a more thorough understanding of the present invention, and thus should not be construed as limiting the present invention. It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the basic principles of the present invention.

S1: Surge protection element F: Fuse
150: warning unit 180: complementary unit

Claims (6)

A surge protection element deterioration diagnosis apparatus comprising:
A surge protection element electrically connected between a ground terminal and a supply terminal to which power is supplied or an external signal is supplied;
And when the leakage current is not generated through the surge protection element, the electrical connection state between the surge protection element and the supply terminal is maintained in an ON state And a fuse for maintaining an electrical connection state between the surge protection element and the supply terminal in an OFF state in response to heat generated by a leakage current when a leakage current is generated through the surge protection element So,
Wherein when the fuse repeats the ON state and the OFF state, it is determined that the surge protection element is in an initial failure state,
The fuse,
A spindle connected between the supply terminal and the first terminal of the surge protection element to which the second terminal is connected to the ground terminal;
A shape memory alloy spring into which the spindle is inserted and which is made of a shape memory alloy,
Wherein a position of the spindle is shifted due to a change in a tensile force of the spring corresponding to a heat generated by a leakage current so that an electrical connection state between the surge protection element and the supply terminal is maintained in an on state or an off state. Device degradation diagnosis device. The method according to claim 1,
Wherein the surge protection device is a metal oxide varistor (MOV). delete The surge protection device according to claim 1,
When the on state and the off state are repeated for a predetermined time by the fuse or when the off state is continued for a predetermined time by the fuse, it is determined to diagnose the deterioration of the surge protection element, Further comprising a warning unit for informing the surge protection element. The method of claim 4,
Wherein the warning unit comprises an LED that is lit when the fuse is in an open state or an alarm signal generator that is transmitted to a remote location via a wired / wireless communication network when the fuse is open. The surge protection device according to claim 1 or 4,
A complementary surge protection element;
Further comprising at least one switch operative in response to an open state signal of the fuse when the fuse is open,
Wherein the complementary surge suppressor has an electrically connected state between the supply terminal and the ground terminal through operation of the at least one switch when the fuse is in an open state.

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