KR101482935B1 - Feed Through Film Capacity For High Frequency Filter - Google Patents

Abstract

The present invention relates to improvement of a fastening portion of a through-film capacitor for a high-frequency filter. The composition is; Element body 1; An electrode rod 5; A cylindrical casing (3) having a bottom plate (33) provided with an electrode through hole (31) through which the electrode rod (5) passes, and the other side is open; And a filler (41) filled in an empty space between the casing (3) and the element body (1), the through film capacitor comprising: A cylindrical connector 37 'installed at the center of the bottom plate 33 of the casing and provided with threads on the outer circumferential surface and provided with a first concavo-convex portion 49 on the upper surface thereof; A bushing head 51 seated on the upper surface of the connector 37 'and a fitting tube 53 sandwiched between the connector 37' and the electrode rod 5, And a second concavo-convex portion 55 which is concavo-convex coupled with the bushing head 51 is provided on the bottom surface of the bushing head 51.

Description

[0001] The present invention relates to a feed through film capacitor for a high frequency filter,

The present invention relates to a through-hole film capacitor for a high-frequency filter, and more particularly, to a through-hole film capacitor for a high-frequency filter, which improves the electrode connection portion so that the characteristics of the product are not changed by external factors such as moisture, To a through-film capacitor for a high-frequency filter.

It is very important to avoid receiving the influence of noise as much as possible because a large amount of information is loaded on a high communication frequency signal with a large number of channels in accordance with the remarkable development of communication technology. The present invention relates to such a technology. The present invention relates to a through-hole film capacitor for a high-frequency filter, which functions to cut noise and pass only a desired frequency region. Conventionally, It is difficult to increase the amount of electric current and it is technically problematic to overcome the problem that heat is generated at the soldering part when an overcurrent close to a predetermined standard flows, thereby causing a trouble. To this problem, a through-film capacitor for a high-frequency filter as shown in Figs. 1 to 4 has been proposed. Hereinafter, the prior art will be described with reference to Figs.

(Hereinafter simply referred to as a capacitor) includes a device body 1, a cylindrical casing 3 fitted to the outside of the device body 1, and an electrode rod 5 provided at the center of the device body 1 .

The element body 1 has first and second electrode plates 11 and 13 wound around the insulated bobbin 7 in a cylindrical shape with a dielectric film 9 sandwiched therebetween. The dielectric film and the first and second electrode plates 11 and 13 are film-shaped. The first electrode plate 11 is protruded to one side and the second electrode plate 13 is wound to protrude to the other side. The dielectric film 9 is located at the center of the two electrode plates, and a portion of the element body 1 having only one electrode is referred to as a margin portion M (see Fig. 4).

Each of the margin portions M of the first and second electrode plates 11 and 13 is fixed by a metal spraying method. The first sprayed layer 15 can be energized simultaneously with the entire first electrode plate 11 protruded by the metal spray and the second sprayed layer 17 can be energized simultaneously with the entire projected second electrode plate 13, .

The electrode rod 5 is fitted in the insulating bobbin 7 inside the element body 1 so that both ends of the electrode rod 5 protrude. The electrode bar 5 is inserted into the insulating bobbin 7 and thus insulated from the first and second electrode plates 11 and 13 constituting the element body 1. [ Both ends of the electrode rod 5 are threaded.

The first lead plate 19 is inserted into the electrode rod 5 while being insulated from the electrode rod 5 and electrically connected to the first welding surface 15a provided on one side of the element body 1. [ An electrode rod fitting hole 21 is provided at the center of the first lead plate 19 and a plurality of pressing projections 23 protrude from the bottom surface of the first lead plate 19.

The second lead plate 25 is fitted to the electrode rod 5 so as to be electrically connected to the second welding surface 17a provided on the other side of the element body 1 by the metal spraying. The second lead plate 25 is fixed to the outer periphery of the electrode rod 5 so as to be energizable with the electrode rod 5. An electrode rod fitting hole 21 'is provided at the center of the second lead plate 25 and a plurality of pressing projections 23' are protruded from the bottom surface of the second lead plate 25. A protruding tube 27 is integrally provided at the center of the second lead plate 25 so as to be closely fitted to the electrode rod 5. Thus, the second electrode plate 13, the second lead plate 25, and the electrode rod 5 are energized with each other. An element support 29 made of a hexagonal nut is fitted to the outside of the projecting tube 27 of the second lead plate 25.

The cylindrical casing 3 is fitted to the outside of the element body 1 in a state in which it is insulated from the electrode rod 5 and the second lead plate 25. [ One side of the casing (3) is closed with a bottom plate (33) provided with an electrode through hole (31) through which the electrode rod (5) passes, and the other side is open. The casing 3 and the electrode rod 5 are kept in an insulated state by the insulating bushing 35 fitted in the electrode through hole 31 of the bottom plate 33. The electrode terminal through hole 31 of the casing 3 is provided with a connector 37 having a screw on the outer circumferential surface thereof.

On the other hand, the casing 3 is electrically connected to the first lead plate 19. To this end, legs 39 protrude from both ends of the first lead plate 19 and extend in the direction in which the element body 1 is located. The end portion 39a of the leg 39 is joined to the casing 3 by spot welding as shown in Fig. An epoxy filled filler 41 is filled and cured in an empty space between the casing 3 and the element body 1.

As a result, one side of the first electrode (anode or cathode) is electrically connected to the casing 3, and one side of the second electrode (cathode or anode) is electrically connected to the electrode 5, And can be connected to the first and second electrode plates 11 and 13, thereby securing the electrostatic capacity.

An elastic support plate 43 is provided between the first lead plate 19 and the bottom plate 33 of the casing 3. The elastic support plate 43 is for maintaining a more stable energized state. Nuts 45 and 45 'are coupled to both ends of the electrode rod 5, and the nuts 45 and 45' are means for fastening an electric wire connected to the film capacitor.

The problems of the above-described through-film capacitors for a high-frequency filter are as follows. When the terminal-attached cable is tightly fastened using a nut, the rotation strength is low, and the internal components including the electrode rod 5 are rotated together by the torque. This may deteriorate the electrical connection stability and reduce the reliability of the product.

In addition, there is also a risk that the moisture permeates into the inside of the casing 3 to form an oxide film on the electrode rod 5, thereby changing the capacitance. That is, the airtightness of the inside of the casing 3 is weak, so that it is vulnerable to moisture and weathering, and the quality is unstable.

Korean Utility Model Registration Application No. 20-2001-0000418 Korean Patent Application Publication No. 10-2008-0108617 Korean Patent Application Publication No. 10-2011-0101392

It is an object of the present invention to solve the above problems and to provide a bonding method between a capacitor element and an inner bottom of an outer case, and to improve the structure of a film capacitor and its fastening part. Another purpose is to improve the reliability of products by increasing the confidentiality, such that there is no change in capacitance due to external factors such as moisture.

The above object is achieved by a device body 1; An electrode rod 5; A cylindrical casing (3) having a bottom plate (33) provided with an electrode through hole (31) through which the electrode rod (5) passes, and the other side is open; And a filler (41) filled in an empty space between the casing (3) and the element body (1), the through film capacitor comprising:

A cylindrical connector 37 'installed at the center of the bottom plate 33 of the casing and provided with threads on the outer circumferential surface and provided with a first concavo-convex portion 49 on the upper surface thereof; A bushing head 51 seated on the upper surface of the connector 37 'and a fitting tube 53 sandwiched between the connector 37' and the electrode rod 5, And an insulating bushing 35 'provided on the bottom surface of the bushing head 51. The bushing head 51 has a second concavo-convex portion 55 which is concavo-convexly coupled to the bushing head 51. As shown in FIG.

According to an aspect of the present invention,

The first concave-convex portion 49 may be formed by repeating grooves and projections along the circumferential direction.

According to another aspect of the present invention,

A nut groove (57) is formed on the upper surface of the bushing head (51) so that a nut can be seated thereon; And a sealing groove receiving groove 59 may be formed on the bottom surface of the nut groove.

According to another aspect of the present invention, the fitting tube 53 may have a length that partially fits into the element body 1.

According to still another aspect of the present invention,

The nut includes a first nut 45b seated in the nut groove and a second nut 45a fastened to the upper surface of the first nut 45b with a terminal therebetween. The side wall of the first nut 45b may be provided with a sealant input hole 61 which extends to the inside of the first nut 45b.

According to the above configuration, since the rotational strength of the product is increased, even when the terminal of the power source is connected with a strong torque, the internal components can be stably fixed and there is no risk of short circuit. A through-hole film capacitor for a high-frequency filter is provided which is improved in airtightness or hermeticity to thoroughly prevent penetration of air and moisture, thereby improving weather resistance or moisture resistance.

FIG. 1 is a perspective view of a conventional film capacitor for a high-frequency filter, and FIG. 2 is a cross-sectional view taken along line AA of FIG.
3 is an exploded perspective view of a conventional film capacitor for a high-frequency filter.
FIG. 5 is a perspective view of a film capacitor for a high-frequency filter according to an embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along line BB in FIG.
7 is an exploded perspective view of a film capacitor for a high-frequency filter according to an embodiment of the present invention.
8 is an exploded cross-sectional view of a film capacitor for a high-frequency filter according to an embodiment of the present invention.
9 is an attempt to lower the insulating bushing according to the embodiment of the present invention.
10 is a cross-sectional view of a film capacitor for a high-frequency filter according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the attached FIGS. 5 to 10. FIG.

In Figs. 5 to 10, reference numerals are given only to parts necessary for the description of the present invention. A clear understanding of the components may be had by reference to the drawings (in particular Figs. 1 to 4) and the description of the background art. The same components as those in Figs. 1 to 4 are denoted by the same names and reference numerals.

A through-hole film capacitor (hereinafter, simply referred to as a capacitor) for a high-frequency filter of the present invention comprises a device body 1, a cylindrical casing 3 fitted to the outside of the device body 1, and an electrode rod 5 ). The element body 1 has two electrode plates 11 and 13 wound in a cylindrical shape with a dielectric film 9 as a dielectric sandwiched around the insulating bobbin 7 as a center. As shown in FIG. 10, the capacitor is fixedly installed inside the apparatus by fixing the casing 3 to the fixed plate body W such as a chassis. The cable through which the main current flows is connected to the electrode rod 5 via the terminal T. [

The connector 37 'provided in the electrode through hole 31 of the casing 3 is formed integrally with the bottom plate 33 as a tubular body having a screw on the outer peripheral surface thereof. A flange nut 47 for fixing the casing 3 to a fixed plate member W such as a chassis is fitted to the outer periphery of the connector 37 '.

The first concavo-convex portion 49 is provided on the upper end of the connector 37 '. The first concavo-convex portion 49 has a shape in which the grooves and the protrusions are repeated at intervals of 90 degrees along the circumferential direction and have a planar shape of ten (ten).

The insulating bushing 35 'basically has a hollow 35a for fitting the electrode rod 5 and is composed of a bushing head 51 and a fitting pipe 53 like the head and stem in the bolt. The bushing head 51 is provided at its bottom surface with a second concavo-convex portion 55 which is concavo-convexly coupled to the first concavo-convex portion 49. The second irregular portion 55 should have a shape corresponding to the first irregular portion 49.

The fitting pipe 53 has a configuration in which the large-diameter portion 53a and the small-diameter portion 53b are linearly connected. The large-diameter portion 53a is a portion that contacts the casing 3 and the small-diameter portion 53b is a portion that extends further from the end of the large-diameter portion 53a and fits to the element body 1. That is, the fitting tube 53 has a length in which the element body 1 is partially fitted.

The small-diameter portion 53b allows a predetermined gap to be maintained between the electrode rod 5 and the element body 1. When a high current flows, a considerable high temperature is generated in the electrode rod 5, to prevent the element body 1 from being damaged by this heat.

The upper surface of the bushing head of the insulating bushing 35 'is provided with a nut groove 57 for receiving the first nut 45b. On the bottom surface of the nut groove 57, a sealing groove receiving groove 59 is provided in a ten-sided shape. The sealing rim groove 59 is for filling the hollow 35a of the insulating bushing 35 'with a sealing agent from the outside even when the nut is fastened to the electrode rod 5.

As mentioned, a nut 45 is used for connecting the terminal to the electrode rod 5, and the nut 45 is composed of two unit nuts 45a and 45b. The first nut 45b is seated in the nut groove 57 and the second nut 45a is fastened on the first nut 45b with the terminal T interposed therebetween. On the other hand, the diameter of the electrode rod 5 is proportional to the used current, and the tightening torque of the second nut 45a is also proportional to the diameter of the electrode rod 5. Therefore, when the diameter of the electrode rod 5 is large, the second nut 45a should be tightened with a strong torque. The above-mentioned first and second concave and convex portions 49 and 55 prevent the insulation bushing 35 'and the electrode rod 5 from rotating together due to the torque applied when the second nut 45a is strongly tightened . The insulating bushing 35 'is firmly coupled to the electrode rod 5 through the sealing agent S and the insulating bushing 35' is fixed to the casing 3 by the first and second convex and concave portions 49 and 55. [ It is because it is. For reference, the casing 3 is fixed to the fixed plate W more strongly by the flange nut 47, so that the casing 3 is not rotated by the second nut 45a.

According to another embodiment of the present invention, the first nut 45b is provided with a sealant injection hole 61 at the side. The sealing agent S is injected into the sealing agent input hole 61 as shown in FIG. 9 for the purpose of more complete sealing, and furthermore, the fixing force of the first nut 45b and the insulating bushing 35 ' .

According to the present invention, the inner space of the element body (1) and the casing (3) is thoroughly blocked by the sealing agent from the outside. This is because when the electrode rod 5 is corroded by the air introduced into the fine gap and the water contained therein, the capacitance of the electrode rod 5 may slightly change but the capacity of the capacitor may be changed. For example, when an oxide film is formed on the outer circumference of the electrode 5, the capacity of the capacitor may be changed due to the insulating component.

The configuration shown and described above is merely a preferred embodiment based on the technical idea of the present invention. It will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention.

1: element body 3: casing
5: Electrode 7: Insulated bobbin
9: dielectric film 11, 13: first and second electrode plates
15, 17: first sprayed layer 19, 25: first and second lead plates
23,23 ': pressing projection 27: projecting tube
29: Element support 31: Electrode through hole
33: bottom plate 35, 35 ': insulated bushing
37, 37 ': Connector 39: Leg
41: Filler 43: Elastic support plate
45, 45 ': Nuts 49, 55: First and second concave-
51: Bushing head 53: Fitting pipe
57: Nut groove 59: Sealing groove groove
W: Fixing plate T: Terminal
S: Sealing agent

Claims (5)

Element body 1; An electrode rod 5; A cylindrical casing (3) having a bottom plate (33) provided with an electrode through hole (31) through which the electrode rod (5) passes, and the other side is open; And a filler (41) filled in an empty space between the casing (3) and the element body (1), the through film capacitor comprising:
A cylindrical connector 37 'installed at the center of the bottom plate 33 of the casing and provided with threads on the outer circumferential surface and provided with a first concavo-convex portion 49 on the upper surface thereof;
A bushing head 51 seated on the upper surface of the connector 37 'and a fitting tube 53 sandwiched between the connector 37' and the electrode rod 5, And a second concavo-convex portion 55 which is concavo-convex coupled to the bushing head 51 is provided on the bottom surface of the bushing head 51;
A nut groove (57) is formed on the upper surface of the bushing head (51) so that a nut can be seated thereon; And a sealing rim groove (59) is formed on the bottom surface of the nut groove (57).
The method according to claim 1,
Wherein the first concave-convex part (49) is formed by repeating grooves and projections along the circumferential direction.
delete The film capacitor for a high-frequency filter according to claim 1, wherein the fitting tube (53) has a length that partially fits into the element body (1).
The method according to claim 1,
The nut includes a first nut 45b seated in the nut groove and a second nut 45a fastened to the upper surface of the first nut 45b with a terminal therebetween. And a sealing agent introducing hole (61) communicating with the inside of the first nut (45b) is provided on the side wall of the first nut (45b).

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