KR101165328B1 - High voltage fuse - Google Patents

Abstract

PURPOSE: A high-voltage fuse is provided to minimize the leakage of an arc-extinguishing material during assembly by longitudinally moving an insulating housing filled with the arc-extinguishing material to block the internal space of the insulating housing from outside. CONSTITUTION: An insulating housing(10), which forms the outer shape of a high-voltage fuse, comprises first and second insulating housings(20,30) each composed of a body part(11) and an end cap(14). A fuse terminal(50) is made of a conductive metal material and provided with first and second connecting parts(54,56) on both ends thereof. The first and second connecting parts have respective through holes(54',56').

Description

High voltage fuse

The present invention relates to a high voltage fuse, and more particularly, to a high voltage fuse that is filled with an arc extinguishing material to prevent the generation of secondary arcs at the time of cutting the melt.

The fuse is to supply power to the electronic components from a power source such as a battery, and to cut off the power supply quickly when the electronic components are overloaded. Some of these fuses are used in electrical components where high voltage is used. In fuses with a high voltage, the arc is generated when the fuse melts and is blown by an overload, so that the power can be delivered to the electronic parts, thereby secondarily impacting the electric parts.

In order to solve such a problem, it is necessary for the fuse used at high voltage to cut off the arc generated when the blown part is broken. To this end, a small material such as sand is filled in the space in which the melted portion is accommodated to surround the melted portion.

However, the work of filling the arc extinguishing material in the space in which the melted part is accommodated is very troublesome. In particular, there is a problem that the assembly of the fuse is very difficult to accommodate both the fuse terminal and the extinguishing material having a blown portion inside the fuse.

SUMMARY OF THE INVENTION An object of the present invention is to solve the conventional problems as described above, so that the fuse material is introduced into the insulating housing in a state where the fuse terminals are installed inside the insulating housing in which the first and second housings are assembled. It is to improve the workability of the high voltage fuse.

Another object of the present invention is to move the first and second housings constituting the insulating housing in the longitudinal direction in the state in which the anti-fogging material is filled in the interior of the insulating housing to shield the internal space from the outside so that the anti-fogging material to the outside during the assembly process Minimize leakage.

According to a feature of the present invention for achieving the above object, the present invention is a first insulating housing having a first end cap formed on both ends of the first body portion formed with an inner space, the longitudinal direction of the first insulating housing Second insulating housings having second end caps formed at both ends of the second body portion, the inner body of which is coupled to the first insulating housing by a concave-convex coupling portion to allow relative movement thereof, and the first insulating housing and the second insulating housing; A fuse terminal is provided in the inner space where the insulating housing is coupled and formed therein, and the fuse terminal includes first and second connection parts to protrude to both ends in the longitudinal direction of the first and second insulating housings. The extinguishing material is filled in a state in which the first and second insulating housings are longitudinally displaced in the inner spaces of the first and second insulating housings provided with the melted ends of the first and second insulating housings.

The first and second end caps of the insulating housings each include a radially cut ring-shaped end side wall integrally formed in the body portions and a semicircular cut plate in the radial direction provided at the end of the end side wall. It consists of.

Inside the blocking wall provided in the second end cap of the second insulating housing, an inner blocking plate is provided at a predetermined interval.

One end of the blocking plate provided on the end side walls of the first and second end caps is outside the end of the end side wall and the other end is located inside the end side wall.

In the second insulating housing, a part of the end side plate is removed to the end of the end side wall in one side second end cap in which the end of the blocking plate is located inside the end side wall.

The first and second insulating housings are coupled to each other in the longitudinal direction, and a locking ring surrounding the outer surfaces of the first and second end caps is further installed when the first and second end caps are coupled to each other.

The width of the locking ring is formed narrower than the width of the end side wall of the first and second end caps.

The uneven coupling portion is a coupling channel and a coupling rib which are formed in the longitudinal direction of the insulating hanger so as to correspond to each other at the front end of both sides of the first insulating housing in the width direction and the opposite end of the second insulating housing in the width direction thereof.

Terminal grooves are formed at one end of the blocking plate of the first and second end caps so that both ends of the fuse terminal protrude from both ends of the insulating housing.

In the high voltage fuse according to the present invention, the following effects can be obtained.

First, in the present invention, the first insulating housing and the second insulating housing can be filled with the extinguishing material into the inner space of the insulating housing in a state in which the first insulating housing and the second insulating housing are temporarily coupled with each other by a predetermined length so that they can move relative to each other in the longitudinal direction. There is an effect that becomes possible.

In addition, in the present invention, the first insulating housing and the second insulating housing may be coupled by relatively moving the first insulating housing and the second insulating housing so as to coincide with each other in the longitudinal direction. There is an effect that it can be more surely prevented from leaking, and is made easier in the work process.

1 is a perspective view showing the configuration of a preferred embodiment of a high voltage fuse according to the present invention.
Figure 2 is an exploded perspective view showing the main configuration of the high voltage fuse of the embodiment of the present invention.
Figure 3 is a perspective view showing the internal configuration of the first insulating housing constituting the embodiment of the present invention.
Figure 4 is a perspective view showing the internal configuration of a second insulating housing constituting an embodiment of the present invention.
5 is a perspective view showing a state in which the first insulating housing and the second housing are temporarily coupled in the longitudinal direction in the high voltage fuse of the embodiment of the present invention.
Figure 6 is a perspective view showing a state in which the first insulating housing and the second insulating housing are consistently coupled in the longitudinal direction after filling the extinguishing material in the insulating housing in the embodiment of the present invention.

Hereinafter, a preferred embodiment of the high voltage fuse according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in the drawings, the insulating housing 10 forms the appearance of the high voltage fuse of the present invention. The insulating housing 10 is made of an insulating synthetic resin. The insulating housing 10 is largely composed of a body portion 11 and end caps 14 provided at both ends of the body portion 11. In the present embodiment, the trunk portion 11 has a hollow rectangular shape. However, the shape of the body portion 11 may be a variety of shapes, such as cylindrical. The end cap 14 is made into a short cylinder or disc shape. However, the end cap 14 may also be made in various forms such as a square pillar or a flat hexahedron. But best of all, it is made in the shape of a disc.

A locking ring 16 surrounding the outer surface of the end cap 14 at both ends of the insulating housing 10 is installed. The locking ring 16 serves to fix the coupling between the first insulating housing 20 and the second insulating housing 30 to be described below.

Cylindrical sleeves 18 are installed in the inner spaces 21 ′ and 31 ′ formed by the first insulating housing 20 and the second insulating housing 30. The sleeve 18 is made of a metal material, and the insulating material filled in the internal spaces 21 'and 31' is chemically reacted with the first and second insulating housings 20 and 30 to insulate the housings 20 and 30. Prevents changing the characteristics of

The insulating housing 10 includes a first insulating housing 20 and a second insulating housing 30. The first insulating housing 20 and the second insulating housing 30 are formed by dividing the insulating housing 10 in the longitudinal direction. That is, the first insulating housing 20 and the second insulating housing 30 are divided into both sides based on the longitudinal center axis of the insulating housing 10 to form the insulating housing 10.

The first insulating housing 20 is provided with a first body portion 21. The first body portion 21 forms the body portion 11 so that a first inner space 21 ′ is formed therein. The first inner space 21 ′ forms the inner spaces 21 ′ and 31 ′ of the body portion 11 together with the second inner space 31 ′ of the second insulating housing 30 to be described below. do. The internal spaces 21 'and 31' are filled with extinguishing material (not shown) in a state where the fuse terminal 50 to be described below is located.

Coupling channels 22 are formed to extend in the longitudinal direction at front ends of both sides of the first body portion 21 in the width direction. The coupling channel 22 is formed to concave along the entire front end of the first body portion 21 in the width direction. The coupling rib 32 of the second insulating housing 30 to be described below is inserted therein.

First end caps 24 are formed at both ends of the first insulating housing 20, respectively. The first end cap 24 forms the end cap 14. The first end cap 24 cooperates with the second end cap 34 of the second insulating housing 30 to be described below to form the end cap 14. The first end cap 24 forms approximately half of the end cap 14.

The first end cap 24 is composed of an end side wall 26 and a blocking plate 28. The end side wall 26 is formed integrally with the first body portion 21 and has a ring shape cut in the radial direction. The blocking plate 28 is integrally provided at the end of the end side wall 26, and the blocking plate 28 has a semicircular plate shape in which the disc is cut in the radial direction. One end of the blocking plate 28 is formed to a position beyond the end side wall 26, and the other end is inside the end side wall 26.

Such a configuration allows longitudinal relative movement with the second insulating housing 30 to be described below while being assembled to each other. The first end cap 24 at both ends of the first insulating housing 20 has the same configuration.

The second insulating housing 30 is provided with a second body part 31 that forms the body part 11 in cooperation with the first body part 21. A second inner space 31 ′ is formed in the second body part 31. The second inner space 31 ′ forms the inner spaces 21 ′ and 31 ′ of the body portion 11.

Coupling ribs 32 are formed at the front ends of both sides of the second body part 31 in the longitudinal direction, respectively. The coupling rib 32 is formed to protrude along the entire front end of the second body portion 31 in the width direction. The coupling rib 32 is inserted into the coupling channel 22 of the first insulating housing 20 to move in the longitudinal direction of the insulating housing 10.

Second end caps 34 are formed at both ends of the second insulating housing 30, respectively. The second end cap 34 cooperates with the first end cap 24 to form the end cap 14. The second end cap 34 forms approximately half of the end cap 14.

The second end cap 34 also includes an end side wall 36 and blocking plates 38 and 40. The end side wall 36 is formed integrally with the second body portion 31 and has a ring shape cut in the radial direction. The blocking plate 38 and the inner blocking plate 40 are integrally provided on the inner surface of the end side wall 36 at predetermined intervals, and the blocking plate 38 and the inner blocking plate 40 are in the radial direction. It is cut semi-circle shape. The blocking plate 38 and the inner blocking plate 40 are arranged side by side in the same shape, one end portion thereof is formed to a position beyond the end side wall 36. The other end of the inner blocking plate 40 is inside the end side wall 36 and the other end of the blocking plate 38 is at the end of the end side wall 36, which is the end of the end side wall 36. Because I cut some. As shown in FIG. 1, a portion of the end side wall 36 is partially cut off to block the first insulating housing 20 when the first insulating housing 20 and the second insulating housing 30 are coupled to each other. A portion of the plate 28 is positioned so that the second insulating housing 30 can no longer be moved.

A portion of the first end cap 24 of the first insulating housing 20 where the blocking plate 28 deviates from the end side wall 26 is blocked inside the end side wall 36 of the second end cap 34. It is assembled so as to be covered by the end side wall 36 of the part with plate 38. The opposite is also true.

The blocking plate 38 and the inner blocking plate 40 are formed to have a predetermined gap. The blocking plate 38 forms both outer surfaces of the end cap 14 when the first and second insulating housings 20 and 30 are matched to each other. One of the inner blocking plates 40 has an inner space 21 'and 31' together with one side blocking plate 28 when the first and second insulating housings 20 and 30 are shifted by a predetermined distance in the longitudinal direction. It serves to shield one end of the). At this time, the inner side blocking plate 40 on the other side is in a state of being shifted from the blocking plate 28 of the corresponding first insulating housing 20.

Here, the inner blocking plate 40 may actually be formed only on the second end cap 34 on any one side. However, in order to allow the first insulating housing 20 and the second insulating housing 30 to be moved relative to each other in the longitudinal direction, one side of the inner space 21 ′ 31 ′ is opened. It should be formed on both sides of the second end cap 34.

Terminal grooves 38 'and 40' are formed in the blocking plate 38 and the inner blocking plate 40 of the second insulating housing 30, respectively. The terminal grooves 38 'and 40' are portions through which the fuse terminal 50 to be described below passes. The terminal grooves 38 ′ and 40 ′ may be formed in the blocking plate 28 of the first insulating housing 20.

A hanger 42 is formed on an inner surface of the inner space 31 ′ of the second insulating housing 30. The hook jaw 42 is a portion at which both ends of the sleeve 18 are hooked, and serves to prevent the sleeve 18 from being randomly moved.

The fuse terminal 50 is formed of a conductive material. Specifically, the fuse terminal 50 is made of a conductive metal material. The skeleton of the fuse terminal 50 is formed of a plate-shaped body portion 52 having a long length compared to the width.

Both ends of the body part 52 are provided with first and second connection parts 54 and 56 respectively connected to a terminal of a wire or another connector. Through-holes 54 'and 56' are formed in the connecting portions 54 and 56, respectively.

In the middle portion of the body portion 52 is formed a melted portion (58). The melted portion 58 is formed to have a narrower width than other portions of the body portion 52, and a through hole 58 'is formed if necessary. The melted portion 58 is a portion that melts and breaks when excessive current flows. The more specific configuration of the blown portion 58 will be omitted for convenience.

It will be described below to assemble the high voltage fuse according to the present invention having the configuration as described above.

The fuse terminal 50 is disposed between the first insulating housing 20 and the second insulating housing 30, and the second insulating housing is disposed at one end of the coupling channel 22 of the first insulating housing 20. One end of the coupling rib 32 of 30 is positioned.

The first insulating housing 20 and the second insulating housing 30 are relatively moved in their longitudinal direction so that the coupling ribs 32 are guided inside the coupling channel 22. The relative movement between the insulating housings 20 and 30 is performed until the state shown in FIG.

In FIG. 5, the blocking plate 28 at one end of the first insulating housing 20 is in a position corresponding to the inner blocking plate 40 at the corresponding end of the second insulating housing 30. Accordingly, the blocking plate 28 of the first insulating housing 20 is outside the blocking plate 38 of the second insulating housing 30 at the opposite end and the left end of the drawing.

In this state, the inner spaces 21 ′ and 31 ′ of the insulating housing 10 are closed by the blocking plate 28 of the first insulating housing 20 and the inner blocking plate 40 of the second insulating housing 30. At one end in a position corresponding to each other, it is isolated from the outside and opened at the opposite end.

Accordingly, the blocking plate 28 of the first insulating housing 20 passes through the end portion outside the blocking plate 38 of the second insulating housing 20 to the inner spaces 21 ′ and 31 ′. Soho may be put in. The arc extinguishing material is filled in the internal spaces 21 ′ and 31 ′ so as to completely surround the blown portion 58 of the fuse terminal 50. Of course, the interior material (21 ', 31') is preferably filled with the arc extinguishing material.

When the arc extinguishing material is completely filled in the internal spaces 21 ′ and 31 ′, the first insulating housing 20 and the second insulating housing 30 are relatively moved in the longitudinal direction. In this case, the first insulating housing 20 and the second insulation are provided until the blocking plates 28 of the first insulating housing 20 correspond to the blocking plates 38 of the second insulating housing 30, respectively. The housing 30 is moved relatively. The state in which the blocking plates 28 and 38 are positioned to correspond to each other is shown in FIG. 6.

For reference, the blocking portion of the first insulating housing 20 may be blocked at a portion where the blocking plate 28 of the first insulating housing 20 and the inner blocking plate 40 of the second insulating housing 30 correspond to each other. The plate 28 moves to a position corresponding to the blocking plate 38 of the second insulating housing 30, and there is a certain amount of extinguishing material in the space between the blocking plate 38 and the inner blocking plate 40 in advance. It is good to be filled. The entire inner space (21 ', 31) by the arcing material pushed toward the inner space (21', 31 ') by the blocking plate (28) of the first insulating housing 20 on the opposite side, even if the extinguishing material is not completely filled. ') May be filled with Sohojae.

Meanwhile, in the state of FIG. 6, since the coupling rib 32 is inserted into the coupling channel 22, the coupling between the first insulating housing 20 and the second insulating housing 30 is not arbitrarily separated. . Thus, the high voltage fuse in the state of FIG. 6 can be easily moved or handled without any tools or devices.

Next, the locking ring 16 is mounted on the outer surface of the end cap 14 to lock the coupled state of the first insulating housing 20 and the second insulating housing 30. When the locking ring 16 is pressed into the outer surface of the end cap 14, the coupling state between the insulating housings 20 and 30 is locked. The locking ring 16 is shorter than the length of the end cap 14 in the longitudinal direction so as to surround only a portion of the end side walls 26 and 36 of the end cap 14. This state is well illustrated in FIG. 1.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

For example, the coupling channel 22 of the first insulating housing 20 and the coupling rib 32 of the second insulating housing 30 may be formed at opposite positions. These coupling channels 22 and coupling ribs 32 may be defined as uneven coupling portions formed in the longitudinal direction of the insulating housings 20 and 30.

In addition, although the locking ring 16 is used to lock the coupling state of the first and second insulating housings 20 and 30 in the illustrated embodiment, the insulating housings 20 and 30 are coupled to the coupling channel 22. The locking ring 16 may not be used as long as it can be engaged by only the coupling rib 32 and the coupling rib 32.

In the illustrated embodiment, terminal grooves 38 'and 40' having the same depth as the thickness of the fuse terminal 50 are formed in the blocking plate 38 and the inner blocking plate 40 of the second end cap 34. Although formed, it may be formed on the blocking plate 28 of the first end cap 24. In this way, the terminal grooves are formed in the side blocking plates 28 and 38 so that the fuse terminals 50 may be temporarily assembled into the one side insulating housings 20 and 30 during assembly.

10: insulation housing 11: body part
14: end cap 16: locking ring
18: sleeve 20: first insulating housing
21: first body portion 21 '; Interior space
22: coupling channel 24: first end cap
26: end side wall 28: blocking plate
30: second insulating housing 31: second body
31 ': Internal space 32: Combined rib
34: second end cap 36: end side wall
38: Block 38 ': Terminal groove
40: inner blocking plate 40 ': terminal groove
42: hanger jaw 50: fuse terminal
52: body portion 54: first connection portion
56: second connection portion 58: melt end
58 ': through hole

Claims (9)

A first insulating housing having first end caps formed at both ends of the first body portion in which the inner space is formed;
A second insulating housing having second end caps formed at both end portions of the second body portion coupled to the first insulating housing and having an inner space formed by an uneven coupling portion to allow relative movement in the longitudinal direction of the first insulating housing;
A fuse having a melting end in the inner space formed by combining the first insulating housing and the second insulating housing and protruding from both ends of the first and second insulating housings in the longitudinal direction. Including a terminal,
A high voltage fuse in which an arc extinguishing material is filled in a state in which the first and second insulating housings are longitudinally displaced in an inner space of the first and second insulating housings provided with a blow-out portion of the fuse terminal.
According to claim 1, wherein the first and second end caps of the insulating housing is cut in the radial direction provided on the end portion of the ring-shaped end side wall and the end side wall formed in the radial direction integrally formed in the body portion, respectively High voltage fuse, characterized in that consisting of a blocking plate on the semi-circular plate.
The high voltage fuse according to claim 2, wherein an inner blocking plate is provided at a predetermined interval inside the blocking wall provided in the second end cap of the second insulating housing.
4. The high voltage fuse according to claim 3, wherein one end of the blocking plate provided on the end side walls of the first and second end caps is out of the end of the end side wall and the other end is located inside the end side wall.
5. The high voltage fuse according to claim 4, wherein in the second insulating housing, a portion of the end side plate is removed from the second end cap on which the end of the blocking plate is located inside the end side wall to the end of the end side wall. .
The method according to any one of claims 1 to 5, wherein the first and second insulating housings are longitudinally matched to each other so that the first and second end caps are coupled to each other. High voltage fuse, characterized in that the locking ring surrounding the outer surface of the end cap is further installed.
7. The high voltage fuse of claim 6, wherein a width of the locking ring is smaller than a width of end side walls of the first and second end caps.
10. The method of claim 7, wherein the uneven coupling portion is coupled to the coupling channel formed in the longitudinal direction of the insulating hanger corresponding to each other in the front end of the both sides in the width direction of the first insulating housing and the corresponding both ends of the width direction of the second insulating housing corresponding to each other. A high voltage fuse characterized by a rib.
10. The high voltage fuse of claim 8, wherein a terminal groove is formed at one end of the blocking plate of the first and second end caps so that both ends of the fuse terminal protrude from both ends of the insulating housing.

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