KR101383011B1 - Varistor module for preventing thermal runway - Google Patents

Abstract

The present invention relates to a varistor module for preventing thermal runaway capable of preventing damage to a varistor by separating the module from an input terminal of the varistor by elasticity of an elastic member when a low temperature soldering is melted by an abnormal current such as a surge current while connecting the module with the input terminal through the low temperature soldering. The present invention includes a predetermined case (10), a first placing groove (20) placed in the case (10), a second placing groove (30) placed in a side of the first placing groove (20) in parallel to the first placing groove (20), a third placing groove (40) extended to the second placing groove (30) while being placed in the top of the first placing groove in parallel to the first placing groove (20), a varistor (50) placed in the first placing groove (20) and having a side terminal (52) extended to the third placing groove (40), a power connecting plate (60) placed in the second placing (30), having its side soldered at the terminal of the varistor (50), and having the other side connected to external power, and an elastic member (70) placed in the third placing groove (40) and having its end attached to the power connecting plate (60). The power connecting plate (60) is rectangular in shape. The power connecting plate (60) moves forward and backward from the varistor (50) by having its width narrower than the second placing groove (30).

Description

Varistor module for preventing thermal runway

The present invention is connected to the input terminal of the varistor to the low temperature soldering varistor module to prevent the varistor from being broken by elastically separating the elastic member when the low temperature solder is melted by an abnormal current such as surge current. It is about.

Surge protection devices are applications for the protection of devices from surge voltages and are designed to cut off or connect to earth ground voltages above the safe range supplied to electrical devices.

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 the element for the surge protection device, a zinc oxide type varistor is generally used.

Such a varistor has a problem in that the varistor needs to be replaced every time it is overheated because surge current, overcurrent, or the like is damaged due to overheating.

Registered Patent 10-1243241 (Registration Date: 2013.03.07)

The problem to be solved by the present invention is to connect the input terminal of the varistor with low-temperature soldering, when the low-temperature solder is melted by an abnormal current such as surge current to be separated by the elasticity of the elastic member to prevent the varistor from breaking The present invention provides a varistor module for preventing runaway.

Varistor module for preventing thermal runaway according to the present invention, the case 10 of the predetermined shape; A first seating groove 20 positioned inside the case 10; A second seating groove 30 positioned in parallel with the first seating groove 20 at a side of the first seating groove 20; A third seating groove 40 positioned in parallel with the first seating groove 20 at an upper portion of the first seating groove 20 and extending to the second seating groove 30; A varistor 50 placed in the first seating groove 20 and having a side terminal 52 extending outwardly in a direction of the third seating groove 40; A power connecting plate 60 placed in the second seating groove 30 and having one side soldered at a low temperature to the terminal of the varistor 50 and the other side connected to an external power source; An end of which is placed in the third seating groove 40 includes an elastic member 70 in close contact with the power connecting plate 60, the power connecting plate 60 is formed in the shape of a rectangular parallelepiped, the power connecting plate 60 ) Is characterized in that it is formed narrower than the width of the second seating groove 30 to move in the front and rear direction with respect to the varistor (50).

Preferably, the lower surface of the case 10 is formed with a lower through hole 13 through which the lower terminal 51 of the varistor 50 passes, and the side surface of the varistor 50 on the side of the first seating groove 20. The side through hole 14 penetrating through the terminal 52 is characterized in that it is formed.

Preferably, the lower portion of the case 10 is characterized in that the fixing member for mounting the case 10 on the substrate is formed.

Preferably, the side terminals 52 of the varistor 50 extend in the direction of the second seating groove 30 and are connected to the power connection plate 60 by low temperature soldering.

Preferably, the first mounting groove 20 corresponding to the lower terminal 51 of the varistor 50 is characterized in that the connection terminal for discharging the current is formed.

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Preferably, the elastic member 70 is characterized in that the spring.

Preferably, a fourth seating groove 90 is formed in the upper portion of the third seating groove 40 and extends to the second seating groove 30 while being located in parallel with the third seating groove 40. The upper portion of the power connecting plate 60 placed in the 30 is bent in a '┍' shape is characterized in that it extends to the fourth seating groove (90).

Preferably, a switch contact 80 is connected to the other side of the second seating groove 30 by being disconnected from the varistor 50 and connected to the control center by wire or wirelessly. do.

According to the varistor module for preventing thermal runaway of the present invention, when a predetermined or more overcurrent flows into the varistor, the varistor is prevented from being burned out by the abnormal current input by physically separating the input terminal by the heat generated when the overcurrent flows.

In addition, if the input terminal of the varistor is separated, there is an advantage that the varistor can be reused only by connecting the terminals.

1 is a perspective view showing a thermal runaway varistor module according to a first embodiment of the present invention.
2 is a cross-sectional view of a steady state in which the varistor does not generate heat in FIG.
3 is a cross-sectional view of a state in which the varistor is heated in FIG.
Figure 4 is a perspective view showing a varistor module for preventing thermal runaway according to a second embodiment of the present invention.
5 is a cross-sectional view of a steady state in which the varistor does not generate heat in FIG.
6 is a cross-sectional view of a state in which the varistor is heated in FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

As shown in FIG. 1, the varistor module for preventing thermal runaway according to the first embodiment of the present invention includes a case 10 having a predetermined shape, a first seating groove 20 positioned inside the case 10, and The second seating groove 30 positioned in parallel with the first seating groove 20 at the side of the first seating groove 20, and in parallel with the first seating groove 20 at the top of the first seating groove 20. A third seating groove 40 which extends into the second seating groove 30 while being positioned, is placed in the first seating groove 20, and the side terminals 52 extend outwardly in the direction of the third seating groove 40. A power connection plate 60 placed in the varistor 50 and the second seating groove 30 and one side thereof is low temperature soldered to the side terminals 52 of the varistor 50 and the other side is connected to an external power source; The end is made of an elastic member 70 in close contact with the power connecting plate 60 while being placed in the third seating groove 40.

Looking at this in more detail, the case 10 is formed in a tetrahedral shape that is easy to be mounted on the substrate and consists of a body 11 having an upper portion and a cover 12 covering the body 11. The lower surface of the case 10 is formed with a lower through-hole 13 through which the lower terminal 51 of the varistor 50 penetrates, and on one side of the first seating groove 20 is located inside the case 10. A side through hole 14 penetrates the side terminal 52 of the varistor 50 so as to be exposed. In addition, a fixing member (not shown) for mounting the case 10 to the substrate may be formed below the case 10. Since the case 10 has the varistor 50 located therein, it is preferable that the case 10 is made of synthetic resin or metal having good thermal conductivity in order to easily discharge the heat generated from the varistor 50 to the outside of the case 10.

The first seating groove 20 is positioned inside the case 10 and is equipped with a varistor 50. A lower terminal 51 is formed below the varistor 50, and a side terminal 52 to which an external power source is connected protrudes from the side of the varistor 50. In this case, the side terminal 52 may extend in the direction of the second seating groove 30, and the lower terminal 51 may protrude to be mounted directly on the substrate. The varistor 50 flows into the first seating groove 20 while the current flows in through the side terminal 52 and the current flowing through the lower terminal 51 is discharged. On the other hand, the first mounting groove 20 corresponding to the lower terminal 51 of the varistor 50 is integrally formed with a connection terminal (not shown) through which current is discharged so that current is transmitted without a separate soldering process. desirable.

The second seating groove 30 is positioned in parallel with the first seating groove 20 at the side of the first seating groove 20, and the second seating groove 30 in which the side terminals 52 of the varistors 50 are positioned. ) And the first seating groove 20 penetrate each other. The second seating groove 30 is equipped with a power connecting plate 60 having one side soldered to the side terminals 52 of the varistor 50 and the other side connected to an external power source. At this time, the power connecting plate 60 is formed in the shape of a rectangular parallelepiped, the second seating groove 30 is the power connecting plate 60 so that the power connecting plate 60 can move from side to side based on the varistor 50. It is formed wider than the width of. Accordingly, when the power connecting plate 60 is fixed to the side terminals 52 of the varistors 50 by low temperature soldering, the power connection plate 60 is positioned at a position close to the varistors 50 in the second seating grooves 30, and inflow of overcurrent occurs. When the low temperature solder melts and the power connection plate 60 is separated from the side terminal 52 of the varistor 50, the power connecting plate 60 is separated from the varistor 50 by the elastic member 70 in the second seating groove 30. Will be located.

The third seating groove 40 extends from the upper part of the first seating groove 20 to the second seating groove 30 while being positioned in parallel with the first seating groove 20. The third seating groove 40 is mounted in a state in which an elastic member 70 is pressed against the power connection plate 60 placed in the second seating groove 30. The elastic member 70 is preferably a spring having elasticity. In addition, the close contact portion 71 is formed at the end of the elastic member (70). The close contact portion 71 is positioned in the third seating groove 40 to be in close contact with the elastic member 70 and the power connecting plate 60 to push the power connecting plate 60 by the pressure of the elastic member 70. do.

In this way, the elastic member 70 placed in the third seating groove pushes the power connection plate 60 to the other end while one end thereof is supported by the side of the second seating groove 30. Accordingly, in the state where the power connecting plate 60 is fixed to the varistor 50 by low temperature soldering, the compressed elastic member 70 does not move even when the power connecting plate 60 is pushed, but low temperature soldering occurs due to the inflow of overcurrent. When the power connection plate 60 is melted and separated from the side terminal 52 of the varistor 50, the power connection plate 60 is pushed by the elastic member 70 so that the power connection plate 60 is the varistor 50. Will be separated from.

In the present invention, as shown in FIG. 2 in the normal state in which the varistor 50 does not normally generate heat, even when the power connection plate 60 is pushed by the elastic member 70, the power connection plate 60 and the varistor ( Since the 50 is connected by low temperature soldering, the varistor 50 is capable of supplying stable power. As time elapses in such a state, the varistor 50 deteriorates its characteristics and increases the leakage current, resulting in overheating. In this state, the power connection plate 60 and the varistor ( The low temperature solder connected to 50) melts to separate the power connecting plate 60 from the varistor 50 and at the same time, physically spaced apart from the varistor 50 by elasticity of the elastic member 70 to block the current flowing into the varistor 50. do.

This state is confirmed by the administrator to recognize the inflow of over-current or surge current and can be used by replacing the varistor 50 or by low temperature soldering again.

In addition, in the present invention, by detecting that the power connection plate 60 is separated from the varistor 50 can be transmitted to the external control center to enable a quick maintenance work. To this end, it is provided with a switch contact point 80 connected to the control center by wire or wirelessly connected to the other side of the second seating groove 30 while the power connection plate 60 is separated from the varistor 50.

The switch contact point 80 is connected to a modem, a server, a mobile communication base station that can directly communicate with a terminal possessed by a remote administrator through a wired or wireless communication network, and provides the administrator with a surge protection device through a notification sound, a text message, an email, and the like. Can inform off state.

On the other hand, the thermal runaway varistor module according to another embodiment of the present invention, as shown in Figure 4 to 6, the second seating groove 40 is located in parallel with the third seating groove 40, the second A fourth seating groove 90 extending to the seating groove 30 is formed, and an upper portion of the power connection plate 60 placed in the second seating groove 30 is bent into a '┍' shape to form a fourth seating groove ( 90).

As described above, when the upper portion of the power connection plate 60 extends to the fourth seating groove 90, as shown in FIG. 9, the low temperature solder connected to the power connection plate 60 and the varistor 50 melts to the power connection plate 60. ) Is separated from the varistor 50 and the rear of the power connecting plate 60 moves along the fourth seating groove 90 when the elastic member 70 is pushed backwards. ) Can be moved stably.

Embodiment of the thermal runaway varistor module of the present invention described above is merely exemplary, and those skilled in the art to which the present invention pertains that various modifications and equivalent other embodiments are possible. You can see well. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

10: case 20: first seating groove
30: second seating groove 40: third seating groove
50: varistor 60: power connection plate
70: elastic member

Claims (10)

A case 10 of a predetermined shape;
A first seating groove 20 positioned inside the case 10;
A second seating groove 30 positioned in parallel with the first seating groove 20 at a side of the first seating groove 20;
A third seating groove 40 positioned in parallel with the first seating groove 20 at an upper portion of the first seating groove 20 and extending to the second seating groove 30;
A varistor 50 placed in the first seating groove 20 and having a side terminal 52 extending outwardly in a direction of the third seating groove 40;
A power connection plate 60 placed in the second seating groove 30 and having one side soldered at low temperature to the terminal of the varistor 50 and the other side connected to an external power source;
It includes; an elastic member 70 is placed in the third seating groove 40, the end is in close contact with the power connecting plate 60,
The power connection plate 60 is formed in the shape of a rectangular parallelepiped, and the power connection plate 60 is formed to be narrower than the width of the second seating groove 30 so as to be able to move in the front-rear direction based on the varistor 50. Varistor module for preventing thermal runaway. The thermal runaway according to claim 1, wherein the side terminals 52 of the varistor 50 extend in the direction of the second seating groove 30 and are connected to the power connection plate 60 by low temperature soldering. Varistor module for prevention. The lower surface of the case 10 is formed with a lower through hole 13 through which the lower terminal 51 of the varistor 50 passes, and a varistor 50 on the side of the first seating groove 20. Varistor module for thermal runaway, characterized in that the side through-hole 14 is formed penetrating through the side terminal 52 of the. The varistor module for thermal runaway prevention according to claim 1, wherein a fixing member for mounting the case 10 to the substrate is formed at the lower portion of the case 10. The varistor module for thermal runaway prevention according to claim 1, wherein the first seating groove (20) corresponding to the lower terminal (51) of the varistor (50) has a connection terminal through which current is discharged. delete The varistor module for thermal runaway prevention of claim 1, wherein the elastic member is a spring. The method of claim 1, wherein the end of the elastic member 70 is located in the third seating groove 40 while being in close contact with the elastic member 70 and the power connecting plate 60 to connect power to the pressure of the elastic member 70 Varistor module for thermal runaway prevention, characterized in that the contact portion 71 for pushing the plate 60 is located. The method of claim 1, wherein the fourth seating groove 90 is formed in the upper portion of the third seating groove 40 extending in parallel to the third seating groove 40 to the second seating groove 30, the second The upper portion of the power connecting plate 60 placed in the seating groove 30 is bent in a '┍' shape and extended to the fourth seating groove (90) varistor module for thermal runaway. According to claim 1, On the other side of the second seating groove 30 is connected to the power connection plate 60 is separated from the varistor 50 is pushed when the switch contact 80 is formed to be connected to the control center by wire or wireless Varistor module for preventing thermal runaway.

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