JP5365919B2 - Capacitor - Google Patents

Description

This invention relates to a capacitor.

  When connecting a capacitor, it is common to use a copper foil or an annealed copper wire. Copper foils and annealed copper wires have the advantage that they can be easily connected regardless of the arrangement and shape of the capacitors because they are easy to perform processing operations such as bending and cutting and are flexible.

Japanese Patent Laid-Open No. 10-133505

  However, since copper foil and annealed copper wire have a small cross-sectional area, their electrical resistance tends to increase and current resistance performance is poor. In addition, when connecting a plurality of capacitors connected in parallel, connecting each capacitor element with a copper foil or an annealed copper wire has a problem in that the connection work becomes complicated.

Accordingly, the present invention is to solve the above problems, with improved withstand current property, in which connection workability provides good capacitor.

To solve the above problems, capacitor of the present invention, together with one end face each other of the plurality of capacitor elements 1 ... constituting the first capacitor 3 is connected in common by the first electrode plate 5, a first The other end faces of the plurality of capacitor elements 1... Constituting the capacitor 3 are commonly connected by the third electrode plate 13, whereby the first capacitor 3 formed by connecting the plurality of capacitor elements 1. configured, with commonly connecting one end surface each other of the plurality of capacitor elements 1 ... constituting the second capacitor 4 to the second electrode plate 9, a plurality of capacitor elements that constitute the second capacitor 4 1 - The other end faces of the second capacitor 4 are commonly connected by the fourth electrode plate 16 to form a second capacitor 4 in which a plurality of capacitor elements 1... Are connected in parallel. The capacitor 4 is disposed so that the first electrode plate 5 and the second electrode plate 9 face each other, and is provided on the outer peripheral portion of the first electrode plate 5 on the side facing the second electrode plate 9. By fitting and soldering the plurality of convex portions 8 to the plurality of concave portions 12 provided on the outer peripheral portion of the second electrode plate 9, the first capacitor 3 and the second capacitor 4 The first capacitor 3 and the second capacitor 4 are connected in series so that there is a gap between them, and the capacitor element 1... And the first, second, third, and fourth electrode plates 5, 9, 13 and 16 are drawn out of the case from the first external connection 15 provided on the third electrode plate 13 and the second external connection 18 provided on the fourth electrode plate 16. In this way, the capacitor is stored in a case and filled with resin, and the capacitor element 1 is formed by winding. Each of the plurality of convex portions 8 and the plurality of concave portions 12 are adjacent to each other. The axial end surfaces and the electrode plates 5, 9, 13, and 16 are arranged side by side. It is characterized in that it is extended and connected between the capacitor elements 1 and 1 .

In addition, a rising portion 7 that restricts the movement of the second electrode plate 9 toward the first electrode plate 5 in a state where the convex portion 8 and the concave portion 12 are fitted is provided.

Oite the capacitor of the present invention, because they commonly connecting a plurality of capacitor elements by first and second electrode plates, as compared with the case of commonly connecting the capacitor element by copper foil or copper wire, conductor The cross-sectional area increases, and the current resistance performance can be improved. Also, since the first capacitor and the second capacitor are connected in series by connecting the first and second connection portions formed on the first and second electrode plates, respectively, the connection work And the voltage performance of the capacitor can be improved.

  The first connecting portion is a convex portion formed on the outer peripheral portion of the first electrode plate, and the second connecting portion is a concave portion formed on the outer peripheral portion of the second electrode plate. Since the first capacitor and the second capacitor can be connected in series by fitting and soldering the convex portion and the concave portion, the efficiency of the connection work can be improved.

  Further, in a state where the convex portion and the concave portion are connected, a configuration is provided so as to have a gap between the first capacitor and the second capacitor, that is, between the first electrode plate and the second electrode plate. By configuring so as to have a gap, heat generated from the first and second capacitors and each electrode plate can be efficiently dissipated outward.

In addition, since a plurality of capacitor elements are connected by each electrode plate, the cross-sectional area of the conductor is increased and the current resistance performance is improved compared to the case where the capacitor elements are connected by copper foil or annealed copper wire. it can. Further, the first and second external connection portions provided on the third and fourth electrode plates can stably connect the outside (circuit, etc.) and the capacitor and improve the efficiency of the connection work. Can do.

Is a side view showing a capacitor according to a first embodiment of the present invention. It is the perspective view which showed the connection state of the 1st electrode plate and capacitor | condenser element similarly. It is the perspective view which similarly showed the connection state of the 2nd electrode plate and a capacitor | condenser element. It is the perspective view which similarly showed the connection part of the 1st electrode plate and the 2nd electrode plate. It is the perspective view which showed the 1st connection part and 2nd connection part of another embodiment.

  Hereinafter, a first embodiment of the present invention will be described in detail with reference to the drawings. As shown in FIG. 1, the capacitor according to the first embodiment of the present invention includes a first capacitor 3 composed of a plurality of capacitor elements 1..., A first electrode plate 5 and a third electrode plate. 13 and a second capacitor 4 composed of a plurality of capacitor elements 1... Are connected in parallel by a second electrode plate 9 and a fourth electrode plate 16, and are connected to the first electrode plate 5. The first connection portion 8 formed and the second connection portion 12 formed on the second electrode plate 9 are connected in series to each other, housed in a case (not shown), and resin-molded. This is a capacitor.

  The capacitor element 1 is formed by, for example, winding a vapor-deposited electrode film. Metallicon electrode portions 2 and 2 formed by spraying solder or the like are formed at both ends in the axial direction.

  The first capacitor 3 is composed of a plurality of capacitor elements 1... And the metallicon electrode portions 2... Formed at both ends in the axial direction are positioned on the same plane, for example, in 5 rows in the vertical direction. Two rows are arranged in the horizontal direction.

  Similarly to the first capacitor 3, the second capacitor 4 is composed of a plurality of capacitor elements 1..., And the metallicon electrode portions 2... Formed at both axial ends are located on the same plane. Thus, for example, five rows in the vertical direction and two rows in the horizontal direction are arranged. Note that the number and arrangement of the capacitor elements 1 of the first and second capacitors 3 and 4 can be changed as appropriate according to the required capacitor capacity and the shape of the case housing the capacitors.

  As shown in FIG. 2, the first electrode plate 5 is made of, for example, a tough pitch copper having a substantially rectangular shape in a plan view with a thickness of about 1 mm, and a first capacitor connecting portion 6 connected to the capacitor element 1 from the outer periphery. The 1st connection part (convex part) 8 connected with the 2nd connection part 12 of the 2nd electrode plate 9 is each extended. Specifically, the first capacitor connecting portion 6 is extended from both sides of the long side of the first electrode plate 5 at five locations on one side in accordance with the number of metallicon electrode portions 2 of the first capacitor 3. One connecting portion 8 extends from a substantially central portion of the leading end of a rising portion 7 having a substantially L-shaped cross section formed between the first capacitor connecting portions 6 and 6, and its width is larger than the width of the rising portion 7. It is formed with a narrow width.

  As shown in FIG. 3, the second electrode plate 9 is made of, for example, a tough pitch copper having a substantially rectangular shape in a plan view with a thickness of about 1 mm, and a second capacitor connecting portion 10 connected to the capacitor element 1 from the outer periphery. A second connection portion (concave portion) 12 connected to the first connection portion 8 of the first electrode plate 5 is formed. Specifically, the second capacitor connecting portion 10 is extended from each of the long sides of the second electrode plate 9 at five locations on one side according to the number of metallicon electrode portions 2 of the second capacitor 4. The second connecting portion 12 is formed by cutting out the substantially central portion of the tip of the receiving portion 11 extending from between the second capacitor connecting portions 10 and 10. The receiving portion 11 and the second connecting portion 12 are provided at positions facing the first connecting portion 8 of the first electrode plate 5, and the groove width of the second connecting portion 12 is the first width. The electrode plate 5 is formed to have substantially the same width as the first connection portion 8 of the electrode plate 5.

  As shown in FIGS. 1 and 2, the third electrode plate 13 is connected to the metallicon electrode portion 2 on the opposite side of the first capacitor 3 to which the first electrode plate 5 is connected. For example, the first capacitor 3 is made of tough pitch copper having a substantially rectangular shape in a plan view having a thickness of about 1 mm. 5 points on each side. In addition, a first external connection portion 15 for connecting to the outside (circuit or the like) extends from one end portion in the longitudinal direction. As shown in FIGS. 1 and 2, the first external connection portion 15 is bent approximately 90 degrees in the direction of the first electrode plate 5, and the tip portion thereof is substantially parallel to the first electrode plate 5. It is bent about 90 degrees.

  As shown in FIGS. 1 and 3, the fourth electrode plate 16 is connected to the metallicon electrode portion 2 on the opposite side of the second capacitor 4 to which the second electrode plate 9 is connected. The fourth capacitor connecting portion 17 connected to the capacitor element 1 from both long sides is formed of, for example, a substantially rectangular tough pitch copper having a thickness of about 1 mm in plan view. 5 points on each side. In addition, a second external connection portion 18 for connecting to the outside extends from one end portion in the longitudinal direction. As shown in FIGS. 1 and 3, the second external connection portion 18 is bent by about 90 degrees in the direction opposite to the second electrode plate 9, and the distal end portion thereof is the second electrode plate 9. It is bent about 90 degrees so that it is almost parallel to.

  Next, the assembly of the capacitor will be described in detail. First, the first capacitor connecting portion 6... Of the first electrode plate 5 is brought into contact with one metallicon electrode portion 2... Of the first capacitor 3 and commonly connected by soldering or the like. Next, the third capacitor connecting portions 14 of the third electrode plate 13 are brought into contact with the other metallicon electrode portions 2 of the first capacitor 3 and commonly connected by soldering or the like. In this state, as shown in FIG. 2, the first capacitor 3 composed of the plurality of capacitor elements 1... Is connected in parallel by the first and third electrode plates 5 and 13.

  Similarly, the second capacitor connection portion 10... Of the second electrode plate 9 is brought into contact with one metallicon electrode portion 2... Of the second capacitor 4 and is commonly connected by soldering or the like. To do. Next, the fourth capacitor connecting portions 17 of the fourth electrode plate 16 are brought into contact with the other metallicon electrode portions 2 of the second capacitor 4 and commonly connected by soldering or the like. In this state, as shown in FIG. 3, the second capacitor 4 composed of the plurality of capacitor elements 1... Is connected in parallel by the second and fourth electrode plates 9 and 16.

  Next, the first electrode plate 5 and the second electrode plate 9 are made to face each other, and as shown in FIG. 4, the first connection portion (convex portion) 8 of the first electrode plate 5 and the second electrode plate 5 The second connecting portions (concave portions) 12 of the electrode plates 9 are respectively fitted and connected in series by soldering or the like. At this time, the width of the first connection portion 8 of the first electrode plate 5 is formed to be substantially the same as the width of the recess 12 of the second electrode plate 9, and the rising portion 7 is formed to be wider than that. Therefore, when the convex portion 8 of the first electrode plate 5 is fitted into the concave portion 12 of the second electrode plate 9, the concave portion 12 of the second electrode plate 9 is caught by the rising portion 7. The movement of the second electrode plate 9 in the downward direction shown in FIG. 1 is restricted, and the first electrode plate 5 and the second electrode plate 9 are connected with a gap between them.

  In the above process, the integrated capacitor element 1 and the electrode plates 5, 9, 13, 16 are connected to the first external connection portion 15 of the third electrode plate 13 and the fourth electrode plate 16. In the state where the two external connection portions 18 are pulled out of the case, they are housed in the case from the opening of the case. At this time, the resin insulating plates 19 for preventing the filling resin from cracking are respectively attached to the portions of the first and second external connection portions 15 and 18 that are in contact with the filling resin surface with screws or the like. Then, filling resin is filled from the case opening, and resin molding is performed to complete the assembly of the capacitor. In addition, since the resin insulation board 19 attached to the 1st and 2nd external connection parts 15 and 18 of the 3rd and 4th electrode plates 13 and 16 prevents a crack of filling resin, it is not necessarily attached. There is no need.

Oite the capacitor of the first embodiment, in order to connect the capacitor element 1, rather than the copper foil or copper wire, from the fact that using the electrode plate 5,9,13,16 such tough pitch copper, The cross-sectional area is increased, and the current resistance performance can be improved. Further, by fitting the first connection part (convex part) 8 formed on the first electrode plate 5 and the second connection part (concave part) 12 formed on the second electrode plate 9, Since the first electrode plate 5 and the second electrode plate 9 can be connected in series, the connection work is easy, and the second electrode plate 9 is connected to the first electrode plate 5 by the rising portion 7 of the first electrode plate 5. The electrode plate 5 can be connected with a gap between them, so that heat generated from the capacitor element 1... And each electrode plate 5, 9, 13, 16 can be dissipated well to the outside. .

It will now be described in detail with the capacitor of another embodiment. Capacitor according to the second embodiment, as shown in FIG. 5 (a), directly from the outer periphery of the first electrode plate 5, in a direction perpendicular to substantially the first electrode plate 5 surface, substantially cylindrical The first connection part (convex part) 8 of the second electrode plate 9 is extended, and directly opposed to the first connection part 8 extended from the first electrode plate 5 on the outer peripheral portion of the second electrode plate 9. The second connecting portion (recessed portion) 12 is formed at the position where the first electrode plate 5 is fitted, and the first connecting portion 8 is fitted into the second connecting portion 12 so as to be inserted. When a second electrode plate 9 is a capacitor connected in series. The extension length of the first connection portion 8 is longer than the concave depth of the second connection portion 12, and when the first connection portion 8 and the second connection portion 12 are fitted, A gap is formed between the first electrode plate 5 and the second electrode plate 9. The other forms except for the first connection part 8 and the second connection part 12 are the same as those in the first embodiment, and the description thereof is omitted.

According to capacitor having the above structure, and the rise portion 7 of the first electrode plate 5, it eliminates the need for the receiving portion 11 of the second electrode plate 9, thereby facilitating the manufacture of the electrode plates 5,9. The second connecting portion 12 may be formed as a through-hole through which the second electrode plate 9 is inserted. In that case, the second connecting portion 12 is interposed between the first electrode plate 5 and the second electrode plate 9. A gap may be formed between the electrode plates 5 and 9 by interposing an insulator.

Next, further with the capacitor of another embodiment will be described in detail. Capacitor according to the third embodiment, as shown in FIG. 5 (b), directly from the outer periphery of the first electrode plate 5, in a direction perpendicular to substantially the first electrode plate 5 surface, substantially cylindrical The first connection portion (convex portion) 8 of the second electrode plate 9 extends and directly faces the first connection portion 8 extended from the first electrode plate 5 directly from the outer peripheral portion of the second electrode plate 9. The cylindrical body is extended in a direction substantially perpendicular to the surface of the second electrode plate 9 at the position where the first connecting portion 8 is the second connecting portion (recessed portion) 12 as the hollow portion. This is a capacitor for connecting the first electrode plate 5 and the second electrode plate 9 in series by being inserted into the connecting portion 12 and fitted. The other forms except for the first connection part 8 and the second connection part 12 are the same as those in the first embodiment, and the description thereof is omitted.

According to capacitor having the above structure, the first connection portion 8 is connected to the second connecting portion 12 become made firm, it is possible to stable connection. Further, even if the second connection portion 12 is formed so as to penetrate the second electrode plate 9, the distal end portion of the cylindrical body extending from the second electrode plate 9 is the first electrode. By contacting the surface of the plate 5, a gap can be formed between the first electrode plate 5 and the second electrode plate 9 without interposing an insulator or the like.

  Although specific embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the present invention. For example, as each electrode plate 5, 9, 13, 16 other than tough pitch copper, various materials such as an aluminum plate can be used, and the thickness does not need to be 1 mm, which is sufficient for the current used. The thickness may be any cross-sectional area. Further, as the shape of the first connection portion 8 of the first electrode plate 5, in addition to the shape having a uniform width, the width in the vicinity of the tip portion of the convex portion 8 is slightly widened, and the second electrode When the concave portion 12 of the plate 9 and the convex portion 8 of the first electrode plate 5 are fitted, the wide width portion is caught by the concave portion 12 and functions as a retaining (regulation of upward movement). Good.

  DESCRIPTION OF SYMBOLS 1 ... Capacitor element, 3 ... First capacitor, 4 ... Second capacitor, 5 ... First electrode plate, 8 ... First connection part, 9 ... Second electrode plate, 12 .. Second connection part, 13. Third electrode plate, 15. First external connection part, 16. Fourth electrode plate, 18. Second external connection part

Claims (2)

One end surfaces of a plurality of capacitor elements (1)... Constituting the first capacitor (3) are connected in common by the first electrode plate (5), and the plurality constituting the first capacitor (3). The other end surfaces of the capacitor elements (1) are connected in common by the third electrode plate (13), so that a plurality of capacitor elements (1),. ), And one end surfaces of the plurality of capacitor elements (1),... Constituting the second capacitor (4) are commonly connected to the second electrode plate (9), and the second capacitor (4 Are connected in parallel by the fourth electrode plate (16), thereby connecting the plurality of capacitor elements (1),... In parallel. 2 capacitors (4), the first The capacitor (3) and the second capacitor (4) are arranged so that the first electrode plate (5) and the second electrode plate (9) face each other, and the first electrode plate (5) The plurality of convex portions (8) provided on the side of the outer peripheral portion facing the second electrode plate (9) are replaced with the plurality of concave portions (12) provided on the outer peripheral portion of the second electrode plate (9). Are respectively fitted and soldered so that there is a gap between the first capacitor (3) and the second capacitor (4), so that the first capacitor (3) and the second capacitor ( 4) are connected in series, and the capacitor element (1), and the first, second, third, and fourth electrode plates (5), (9), (13), and (16) The first external connection portion (15) provided on the electrode plate (13) and the second external connection portion (18) provided on the fourth electrode plate (16) are placed outside the case. A capacitor that is housed in a case and filled with resin in a protruding manner. The capacitor element (1) has a curved surface formed by winding, and has an axial end surface and electrode plates (5), (9), and (13). (16) are arranged in parallel so as to face each other, and each of the plurality of convex portions (8) and the plurality of concave portions (12) extends from between adjacent capacitor elements (1) (1). Capacitor characterized by being connected . A rising portion (7) is provided for restricting the movement of the second electrode plate (9) toward the first electrode plate (5) in a state where the convex portion (8) and the concave portion (12) are fitted. The capacitor according to claim 1.