JPH03261123A - Electrolytic capacitor device - Google Patents

Abstract

PURPOSE:To lower the height by juxtaposing a plurality of electrolytic capacitors horizontally inside the case, and connecting them in series by a terminal metal fitting. CONSTITUTION:A plurality of electrolytic capacitors 3 and 4 are stored side by side in the case 2 consisting of insulating material, and those are connected in series by a terminal metal fitting 5, and also the external lead legs 18 and 19 of the terminal metal fitting 5 and led out of the case 2. That is, by storing a plurality of electrolytic capacitors 3 and 4 for low voltage in one case 2, and connecting the electrolytic capacitors 3 and 4 in series inside the case 2, it is so arranged as to get high voltage. Hereby, an electrolytic capacitor device with low height can be gotten.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application 1] The present invention relates to an electrolytic capacitor device, and particularly to an electrolytic capacitor device in which a plurality of electrolytic capacitors are connected in series and housed in one case to form a unit.

[Prior Art] For example, an electrolytic capacitor with a high rated voltage such as 200 V or 400 V is designed to withstand that voltage or higher, and uses electrolyte, electrode foil, separator, etc. that can withstand that voltage.

[Problems to be Solved by the Invention] However, such electrolytes, electrode foils, and separators are naturally required to have paper-like performance, making them expensive in terms of cost. Furthermore, the electrolytic capacitor itself is large and occupies a large volume when mounted on a circuit board, and its height and dimensions also increase, making it inconvenient to mount it on a circuit board.

An object of the present invention is to provide an electrolytic capacitor device that is low in cost and has a low height so that it can be conveniently mounted on a circuit board.

[Means for Solving the Problems 1] In order to achieve this object, the present invention stores a plurality of low voltage electrolytic capacitors in one case, and connects the electrolytic capacitors in series within the case. It is now possible to obtain an electrolytic capacitor device for voltage.

In other words, the electrolytic capacitor device of the present invention includes a case having a plurality of electrolytic capacitors having leads in the same direction, a case body for storing these electrolytic capacitors side by side, a cover to be placed over the case body, and a case having a cover that is placed over the case body. In order to connect the electrolytic capacitors in series, the internal lead legs connecting the different polarity terminals of the electrolytic capacitors and the lead terminals not connected to the internal lead legs of the electrolytic capacitors mentioned above are connected. A terminal fitting having a pair of external lead legs that can be pulled out of the case.

The terminal fitting may be arranged in a space secured by a rib arranged at a distance from the front wall of the case body, and the terminal fitting may be arranged in a space secured by a rib arranged at a distance from the front wall of the case body. the raised portion of one external lead leg is longer than the raised portion of the other external lead leg, the internal lead legs are arranged diagonally, or the raised portions are the same length and the internal lead leg is longer than the raised portion of the other external lead leg. It may also be arranged horizontally between or above the raised parts of the lead legs. Furthermore, the internal lead leg may be constituted by a lead terminal of an electrolytic capacitor.

Preferably, the rear wall of the case is provided with a gas vent hole located corresponding to the explosion-proof valve of the electrolytic capacitor, and the external lead leg is pulled out of the case from the joint between the case body and the cover. It is bent along the surface from the outer surface of the front wall to the bottom of the case body,
An electrically neutral dummy terminal is provided on the bottom of the case body on the side opposite to the external lead legs.

[Function] Since the electrolytic capacitors are arranged side by side in the case and connected in series by terminal fittings, the height can be reduced and the necessary high voltage can be secured.

[Embodiments] Hereinafter, embodiments of the electrolytic capacitor device of the present invention will be described in detail with reference to FIGS. 1 to 8.

<Embodiment 1> FIGS. 1 to 4 show a first embodiment of an electrolytic capacitor device according to the present invention.

The electrolytic capacitor device 1 includes a case 2, two aluminum electrolytic capacitors 3.4 (FIG. 2) with leads in the same direction housed in the case 2, and a terminal fitting 5 that connects both electrolytic capacitors in series. has.

The case 2 is made of electrically insulating synthetic resin and includes a case body 6 and a cover 7 that is placed over the case body 6. The case body 6 has a storage recess 8.9 curved in the shape of a gutter for storing the electrolytic capacitors 3.4 side by side.
are provided with the partition plate 10 in between, and the bottom surface of the case body 6 is also curved in accordance with the shape of the storage recess 8.9 (Fig. 3).
This reduces the contact area of the bottom of the case body 6 with the circuit board (not shown) on which the electrolytic capacitor device 1 is to be mounted. It becomes difficult to be influenced.

Notches 12 are provided at locations corresponding to the storage recesses 8 and 9 on the rear wall 11 of the case body 6, and when the case 7 is placed on the case body 6, the notches 12 are formed in the rear wall of the case 7. Together with the notch 13, a circular vent hole 14 is located corresponding to a known explosion-proof valve (not shown) provided in each head of the outer case of the electrolytic capacitor 3.4.
(Figures 3 and 4).

A rib 16 is provided in the storage recess 8.9 on the front wall 15 side facing the rear M11 of the case body 6 at a slight distance from the front wall 15, and the rib 16 allows the housing to be placed in the storage recess 8.9. Sealing part 3 of the exterior case of each electrolytic capacitor 3.4
A terminal fitting 5 for connecting both electrolytic capacitors in series is arranged in a space 17 between the front wall 15 and the rib 16 where capacitors a and 4a are positioned and fitted.

The terminal fitting 5 has two external lead legs 18 and 19 that are pulled out to the outside of the case, and one internal lead leg 20.
Each external lead leg 18.19 has a rising portion 18a, 1 connected to a lead terminal of an electrolytic capacitor 3.4.
9a, and engaging portions 18b and 19b bent into a substantially inverted U shape so as to engage with the upper edge of the front wall 15, and the front! ! It has leg portions 18c and 19c that are bent into a substantially L-shape so as to descend along the outer surface of the case body 6 and wrap around the bottom surface of the case body 6.

of the case body 6 that engages with the engaging portions 18b, 1.9b,
An engagement groove 15a is formed at the upper edge of the front wall 15 where it meets the cover 7, and the outer surface of the front wall 15 and the bottom surface of the case body 6 are formed along the L-shaped bent legs 18c and 19C. Although the grooves 15b are formed throughout, if the outer lead leg portions 18 and 19 are thin, the engagement grooves 15a and 15b may not be provided.

The rising portion 19a is longer than the rising portion 18a, and lead insertion holes 18d and 19d into which one lead terminal of the electrolytic capacitor 3.4 is inserted are provided near the tips of both rising portions 18a and 19a. . Electrolytic capacitors 3 are also connected near both ends of the internal lead legs 20 arranged diagonally.
．． Lead insertion hole 20 into which the other lead terminal of No. 4 is inserted.
a and 20b are provided.

The lead terminals of each electrolytic capacitor 3.4 are cut short and
The negative lead terminal 3C of the electrolytic capacitor 3 is inserted into the lead insertion hole 18d of the external lead leg 18, and the positive lead terminal 3b of the electrolytic capacitor 3 is inserted into the internal lead leg 20.
is inserted into one lead insertion hole 20a. The negative lead terminal 4c of the electrolytic capacitor 4 is inserted into the other lead insertion hole 20b of the internal lead leg 20, and the positive lead terminal 4b of the electrolytic capacitor 4 is connected to the external lead leg 1.
The lead insertion hole 19d of No. 9 is inserted through the lead insertion hole 19d. Both electrolytic capacitors 3.4 are thus connected in series. Connection between each insertion hole and the lead terminal inserted therein is performed, for example, by laser, resistance welding, soldering, etc., and the connection is electrically made.

Note that by rotating both electrolytic capacitors 3.4 and changing the positions of the lead terminals, insert the positive lead terminal 3b of the electrolytic capacitor 3 into the glued insertion hole 18d of the external lead leg 18, and Side lead terminal 4c
may be inserted into the lead insertion hole 19d of the external lead leg 19, and the internal lead leg 20 may be used to connect the negative lead terminal 3c of the electrolytic capacitor 3 and the positive lead terminal 4b of the electrolytic capacitor 4. .

Further, the rising portion 18a of the external lead leg portion 18 may be made long, and the rising portion 19a of the external lead leg portion 19 may be shortened.

The material of the external lead legs 18, 19 and the internal lead legs 20 that constitute the terminal fitting 5 is 5LIS.
-Ni-solder plating, phosphor bronze-solder plating, nickel silver-solder plating, iron-copper base plating-solder, etc. are used.

The upper surface of the cover 7 is made flat, and this flat surface 7a is used, for example, as a suction surface when being handled by a negative pressure suction nozzle of an automatic machine, and also as a display surface for displaying rated voltage values, capacitance values, etc. Ru.

When assembling, attach the external lead leg 18 of the terminal fitting 5.
19 may be set in advance in the space 17 inside the case body 6, and then the electrolytic capacitor 3.4 is housed, the lead terminals 3c and 4b are attached, and the internal lead legs 20 are further attached. Depending on the case, the terminal fittings 5 may be attached to the electrolytic capacitor 3.4 so as to be connected in series, and then housed in the case 2. In any case, since the case body 6 has a space 17 secured by the rib 16 to accommodate the terminal fitting 5,
This is convenient for assembly work.

Electrolytic capacitors 3 and 4 and terminal fittings 5 are connected to case body 6
After being stored in the case body 6, the cover 7 placed over the case body 6 is fixed by, for example, ultrasonic welding or adhesive.

<Example 2> FIG. 5 shows a second embodiment of the invention.

In this embodiment, each lead terminal 3c, 3b, 4C14b
The electrolytic capacitor 3.4 is arranged so that the outer lead legs 18.19 forming the terminal fitting 5 have the same length, and the rising parts 18a and 19a of the outer lead legs 18.19 forming the terminal fitting 5 have the same length, and the inner lead legs 20 have the same length. , 19a.

<Example 3> FIG. 6 shows a third embodiment of the present invention.

In this embodiment, each lead terminal 3C13b, 4C14b
Electrolytic capacitors 3.4 are located above and below, respectively.
External lead legs 1 on which terminals are arranged and which constitute the terminal fitting 5
The raised parts 18a, 19a of 8.19 have the same length, and the internal lead leg 20 is arranged horizontally above the raised parts 18a, 19a.

<Example 4> FIG. 7 shows a fourth embodiment of the present invention.

In this embodiment, each lead terminal 3C13b, 4C14b
The terminals of the electrolytic capacitor 3 and 4 are arranged horizontally, and the external lead legs 18 and 19 forming the terminal fitting 5 are arranged horizontally.
The rising portions 18a and 19a have the same length.

In this embodiment, the internal lead leg 20 is not provided as a separate member, but the positive lead terminal 3b of the electrolytic capacitor 3.
The internal lead leg 20 is not cut, and extends to the negative lead terminal 4C of the electrolytic capacitor 4, where it is welded. Of course, contrary to this, the negative lead terminal 4C of the electrolytic capacitor 4 may be extended.

<Example 5> FIG. 8 shows a fifth embodiment of the present invention.

In this embodiment, a flat portion 21 is provided on the bottom surface of the case body 6, and a dummy terminal 22 is attached to the flat portion 21. By providing the flat portion 21 on the bottom surface of the case body 6, surface mounting on the circuit board can be performed with better stability. Furthermore, although the dummy terminal 22 is electrically neutral, especially in the case of acoustic use, the sound quality can be improved by connecting the dummy terminal 22 to the outer case of each electrolytic capacitor 3.4 with an appropriate lead wire. I can figure it out.

Note that the electrolytic capacitor device of this invention can be used at 200 V or 4
It can be applied not only to high voltages such as 00V, but also to cases where, for example, two 5cm electrolytic capacitors are housed in a case to obtain a 10V electrolytic capacitor.

Further, in the embodiment, two electrolytic capacitors are housed in the case, but three or more electrolytic capacitors may be housed therein.

[Effects of the Invention] As explained above, according to the present invention, a plurality of electrolytic capacitors are housed side by side in a case made of an insulating material, and they are connected in series using terminal fittings. By leading the external lead legs out of the case, it is possible to obtain an electrolytic capacitor device for higher voltage using an inexpensive electrolytic capacitor for lower voltage. Furthermore, since they are housed in one case and are connected in series within the case, they can be mounted as is without forming a pattern for serial connection on the circuit board side. Furthermore, since a plurality of electrolytic capacitors are housed side by side, the height dimension is low and the height can be reduced.

[Brief explanation of drawings]

FIG. 1 is an electrolytic condenser diagram according to an embodiment of the present invention;
The figure is a perspective view of the device seen from the bottom side, Figure 4 is a partial sectional view taken along the -TV line in Figure 1, and Figures 5.6 and 7 are perspective views showing examples of other terminal fittings. , FIG. 8 is a perspective view showing an embodiment having dummy terminals. In the figure, 1 is an electrolytic capacitor device, 2 is a case, 3.4 is an electrolytic capacitor, 5 is a terminal fitting, 6 is a case body, 7 is a cover, 14 is a gas vent hole, 16 is a rib, F is a space, 18. 19 is an external lead leg, 18a and 19a are rising portions of the external lead leg, and 20 is an internal lead leg.

Claims (9)

[Claims] (1) A case that has a plurality of electrolytic capacitors with leads in the same direction, a case body that houses these electrolytic capacitors side by side, and a cover that is placed over the case body, and each of the electrolytic capacitors that are inside this case. an internal lead leg that connects the lead terminals of different polarities of each of the electrolytic capacitors to each other in series, and a pair of external leads that are drawn out of the case from the lead terminals that are not connected to the internal lead legs of each of the electrolytic capacitors. An electrolytic capacitor device comprising a terminal fitting having legs. (2) The electrolytic capacitor device according to claim 1, wherein the terminal fitting is arranged in a space secured by a rib arranged at a distance from the front wall of the case body. (3) The external lead legs have a rising part connected to the lead terminal of the electrolytic capacitor, and the rising part of one external lead leg is longer than the rising part of the other external lead leg,
2. The electrolytic capacitor device according to claim 1, wherein the internal lead legs are arranged diagonally. (4) A claim in which the external lead leg has a rising part connected to the lead terminal of an electrolytic capacitor, both rising parts have the same length, and the internal lead leg is arranged horizontally between the rising parts of the external lead leg. Item 1. The electrolytic capacitor device according to item 1. (5) The external lead leg has a rising part connected to the lead terminal of the electrolytic capacitor, both rising parts have the same length, and the internal lead leg is arranged horizontally above the rising part of the external lead leg. The electrolytic capacitor device according to claim 1. (6) The electrolytic capacitor device according to claim 1, wherein the internal lead leg is constituted by a lead terminal of an electrolytic capacitor. (7) The electrolytic capacitor device according to claim 1, wherein the rear wall of the case is provided with a gas vent hole located corresponding to the explosion-proof valve of the electrolytic capacitor. (8) The electrolyzer according to claim 1, wherein the external lead leg is pulled out of the case from the joint between the case body and the cover, and is bent along the surface from the outer surface of the front wall of the case body to the bottom surface of the case body. capacitor device. (9) On the bottom of the case body, on the opposite side from the external lead legs,
The electrolytic capacitor device according to claim 1, further comprising an electrically neutral dummy terminal.