KR101244756B1 - Surge protector having preventing thermal runway function - Google Patents

Abstract

PURPOSE: A surge protector having a thermal runaway protection function is provided to protect a varistor from high temperature by blocking a power line if abnormal current is input. CONSTITUTION: A varistor(10) conducts to a ground after absorbing if power greater than a specific level is applied. A thermal deformation unit(30) is thermally deformed by heat generated in the varistor. A shut-off signal transmission unit(50) transmits a shut-off signal by operating due to thermal deformation of the thermal deformation unit. A switch(70) is operated by the shut-off signal transmitted by the shut-off signal transmission unit. The switch disconnects a power line through the switching operation. [Reference numerals] (10) Varistor; (100) Load; (50) Shut-off transmission unit; (70) Switch

Description

Surge protector with thermal runaway protection {SURGE PROTECTOR HAVING PREVENTING THERMAL RUNWAY FUNCTION}

The present invention relates to a surge protector having a thermal runaway protection function that can protect the varistor from the high temperature generated in the process of conducting the incoming brain current to the ground.

As is well known, surge protection devices are applications for the protection of surge devices from surge voltages, in which abnormal voltages beyond the safe range supplied to electrical devices are cut off or connected to ground.

Such a surge protection device is classified into three types of voltage switching type, voltage limiting type, and combination type according to its function. The voltage switching type is a surge protection device having a high impedance state when no surge is applied, and a sudden impedance drop when there is a voltage surge. Examples of devices used therein include air gaps, gas discharge tubes, thyristors, triacs, and the like.

The voltage limiting type is a surge protection device that has a high impedance state when no surge is applied and continuously decreases the impedance when the surge current and the voltage increase. Examples of devices used in voltage limited surge protection devices include varistors and suppression diodes. The combination type is a surge protection device having a voltage switching element and a voltage limiting element.

There is a surge protection device that combines a gas discharge tube and a varistor to perform two operations, voltage switching, voltage limiting, or voltage switching and voltage limiting, depending on the characteristics of the applied voltage.

Surge protection as a device for limiting the transient overvoltage caused by thunder and classifying the surge current in the single-phase or three-phase alternating current or direct current converter in order to prevent a surge among the surge protection devices. The device is installed. As an element for this surge protection device, a zinc oxide type varistor is generally used.

When a zinc oxide type varistor is repeatedly inputted by a lightning strike or the like, the voltage decreases sequentially according to its input level. When the input voltage of the zinc oxide varistor decreases, the leakage current increases to increase the amount of heat generated, thereby causing fuming ignition by thermal runaway. In order to prevent this, it is proposed to have a temperature fuse function as a protection to prevent fuming ignition by thermal runaway of a zinc oxide type varistor.

However, a varistor having a conventional temperature fuse function is advantageous in preventing thermal runaway when the temperature fuse and the varistor are integrally formed, but the overheated temperature of the varistor is not properly transmitted to the temperature fuse so that the varistor in the form of zinc oxide is properly protected. There was a problem that can not.

In addition, the conventional surge protection device has a high possibility of spontaneous ignition because it does not easily dissipate heat generated by the varistor to the outside, and there is a problem that the surge protection device may explode secondarily by spontaneously igniting and scattering when the varistor is overheated. .

The related art "explosion-proof surge protection device with a thermal runaway prevention element" associated with the present invention has been filed in the Republic of Korea Patent Office and registered with the registration number: 10-0992426.

In the prior art, a varistor that is connected to a power line and absorbs power when a predetermined level or more is applied and is connected to ground, and an input power absorbed by the power line when the internal temperature of the varistor rises above a predetermined value when connected to the front end of the varistor. Consists of a temperature fuse that can block the, the varistor is provided with a plurality is connected in series, parallel or in series and parallel to each other, the temperature fuse is located between the plurality of varistors are in contact with each other, the plurality of varistors The outer surface is wound with a heat shrink tape so as to be compressed with the temperature fuse.

However, the prior art has a problem that the device is complicated because the temperature fuse is mounted between the plurality of varistors, and the problem of the varistor exploding still remains when the temperature fuse fails.

An object of the present invention is a surge having a thermal runaway prevention function that can block the power line in the state that the abnormal current is input to prevent the varistor which conducts a predetermined level or more of the input current to the ground to be damaged by the heat generated during the conduction process In providing a protector.

A surge protector having a thermal runaway prevention function according to the present invention includes: a varistor 10 connected to a power line to absorb and conduct to ground when a predetermined level or more of power is applied; A heat deformation member 30 which is covered by the varistor 10 so as to be in close contact with the outer surface of the varistor 10 and is thermally deformed by heat generated by the varistor 10; A blocking signal transmitter 50 which is operated by the thermal deformation of the thermal deformation member 30 to transmit a blocking signal; And a switch 70 that switches off the power line by being switched by a cutoff signal transmitted from the cutoff signal transmitting unit 50, wherein the cutoff signal transmitting unit 50 is outside the varistor 10. Fixed terminal 51 fixed to the side; A mobile terminal 53 fixed to an inner surface of the heat deformation member 30 to be in contact with or spaced apart from the fixed terminal 51; And a signal transmitting member 55 which detects that the mobile terminal 53 contacts or is spaced apart from the fixed terminal 51 and transmits a blocking signal.

Preferably, the heat deformation member 30 is formed in a tube form or a case form so as to be covered with the varistor 10, characterized in that composed of a heat-shrinkable resin that is contracted by heat or a thermal expansion resin to expand by heat.

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The present invention can block a power line in a state in which an abnormal current is input to prevent the varistor which conducts a predetermined level or more of the current input to the ground from being burned out by heat generated during the conduction process.

1 is a block diagram of a surge protector having a thermal runaway prevention function according to an embodiment of the present invention.
Figure 2 shows the main part of the present invention.
3 is a block diagram of a surge protector having a thermal runaway prevention function according to another embodiment of the present invention.

Hereinafter, a surge protector having a thermal runaway prevention function according to the present invention according to the accompanying drawings in detail as follows.

As shown in FIG. 1, a surge protector having a thermal runaway prevention function according to the present invention includes a varistor 10; Thermal deformation member 30; Blocking signal transmitting unit 50; And a switch 70.

The varistor 10 is connected to a power line and absorbed when a predetermined level or more of power is applied to the ground. Here, the power of a predetermined level means a threshold voltage determined as a surge in the varistor 10. When the varistor 10 is applied with a predetermined voltage or more from the power line, the internal resistance decreases and the overcurrent is absorbed and induced to ground, thereby preventing the overload of the load 100 from being damaged. In addition, the varistor 10 may adopt a suppression element according to a design change by those skilled in the art.

As shown in FIG. 2, the heat deformation member 30 is covered by the varistor 10 to be in close contact with the outer surface of the varistor 10, and is thermally deformed by heat generated by the varistor 10. Such a heat deformation member 30 is preferably formed of a tube or case shape so as to be in surface contact with the varistor 10 and made of a thermal contraction resin contracted by heat or a thermal expansion resin expanded by heat. Here, the heat deformation member 30 is preferably a wrinkle 31 is formed on the outer surface so that the deformation is quickly made by the heat generated from the varistor 10 and the shape is quickly restored after the heat deformation. . In addition, the heat deformation member 30 is preferably configured to a thickness of about 0.2 ~ 0.6mm so that heat deformation can be made quickly.

As shown in FIG. 2, the blocking signal transmitting unit 50 is operated by thermal deformation of the thermal deformation member 30 to transmit a blocking signal. This, the cutoff signal transmitting unit 50 may be connected to the switch 70 through a wire so as to directly transfer the cutoff signal roll to the switch 70 to be described later.

In addition, the blocking signal transmitting unit 50 may include, for example, a fixed terminal 51; Mobile terminal 53; And a signal transmitting member 55.

The fixed terminal 51 is fixed to the outer surface of the varistor 10.

The mobile terminal 53 is fixed to the inner surface of the heat deformation member 30 to be in contact with or spaced apart from the fixed terminal 51.

The signal transmitting member 55 detects that the mobile terminal 53 contacts or is spaced apart from the fixed terminal 51 and transmits a blocking signal. The signal transmitting member 55 may include a programmable IC chip and a PCB on which electronic components are mounted. The signal transmitting member 55 may transmit a signal by detecting a contact or spaced state between the fixed terminal 51 and the mobile terminal 53. .

The switch 70 is switched by a cutoff signal transmitted from the cutoff signal transmitter 50 to cut off a power line flowing into the varistor 10. At this time, it is preferable that the switch 70 directly connects the power line to the ground line while cutting off the power line by the blocking signal.

In addition, the present invention is, for example, as shown in FIG. 3, for example, a transmitter 61; And a receiver (63).

The transmitter 61 is connected to the cutoff signal transmitter 50 to convert the cutoff signal of the cutoff signal transmitter 50 into a wired / wireless signal and transmit the wired or wireless signal.

The receiver 63 is connected to the switch 70 to receive the blocking signal from the transmitter 61 and to operate the switch 70 by the received blocking signal.

Here, the transmitter 61 and the receiver 63 include a PCB including a programmable IC chip and electronic components, and convert the cutoff signal into a wired / wireless signal and transmit the received wired / wireless signal. Can be converted to a blocking signal. In particular, when the transmitter 61 and the receiver 63 transmit and receive a radio signal, not only can operate the switch 70 at a long distance, but can also take out the wire and can easily use space.

As described above, in the present invention, the varistor 10 receives the input brain current when the brain current is input in a state in which the current of the rated voltage is input through the power line and is input to the load 100 as shown in FIGS. Conduct the brain current to ground. Here, the varistor 10 is raised in temperature in the process of conducting the brain current to the ground. At this time, the thermal deformation member 30 is thermally contracted or thermally expanded by the temperature of the varistor 10. In addition, the mobile terminal 53 is moved together with the thermally deformable member 30 which is thermally deformed to be in contact with or spaced apart from the fixed terminal 51. Subsequently, the signal transmitting member 55 detects that the mobile terminal 53 contacts or is spaced apart from the fixed terminal 51 and transmits a blocking signal. Therefore, the switch 70 may be switched according to the blocking signal to block the power line to block the input of the brain current. That is, the varistor 10 is stopped by the power supply line is blocked by the switch 70, the brain current is no longer input, so that the operation is stopped, further rise in temperature is stopped and does not burn out.

As described above, the present invention can cut off the power line to which the current is input so as to prevent the varistor which conducts a current of a predetermined level or more into the ground from being damaged by heat generated during the conduction process. Therefore, the varistor can be used for a long period of time since the brain current input through the power line is cut off at the source. have.

Since the above-described embodiments are merely illustrative of the preferred embodiments of the present invention, the scope of application of the present invention is not limited to the above, and appropriate modifications are possible within the scope of the same idea. Therefore, since the shape and structure of each component shown in the embodiment of the present invention can be carried out by deformation, it is natural that the modification of the shape and structure belong to the appended claims of the present invention.

10: varistor 30: heat deformation member
50: cutoff signal transmitter 70: switch

Claims (3)

A varistor 10 connected to the power line to absorb and conduct to ground when a predetermined level or more of power is applied; A heat deformation member 30 which is covered with the varistor 10 so as to be in close contact with the outer surface of the varistor 10 and is thermally deformed by the heat generated by the varistor 10; A blocking signal transmitter 50 which is operated by the thermal deformation of the thermal deformation member 30 to transmit a blocking signal; And a switch 70 which is switched by a cutoff signal transmitted from the cutoff signal transmitter 50 to cut off the power line.
The blocking signal transmitter 50
A fixed terminal 51 fixed to an outer surface of the varistor 10;
A mobile terminal 53 fixed to an inner surface of the heat deformation member 30 to be in contact with or spaced apart from the fixed terminal 51; And
Surge protector having a thermal runaway prevention function comprising a ;; The method of claim 1, wherein the heat deformation member 30
The surge protector having a thermal runaway prevention function, characterized in that the varistor (10) is made of a tube or case form and made of a heat-shrinkable resin or a heat-expandable resin that expands by heat. delete

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