JP2019102603A - Surface mounting capacitor and seat plate for use therein - Google Patents

Abstract

To provide a surface mounting capacitor in which the capacitor body can be held more stably by the sidewall, and to provide a seat plate for use therein.SOLUTION: A surface mounting capacitor includes a capacitor body 10 for housing a capacitor element, and a seat plate 20 for holding the capacitor body 10. The seat plate 20 has a bottom wall 22 where the capacitor body 10 is placed, and multiple sidewalls 30 extending from the bottom wall 22 in the axial direction of the capacitor body 10 and pressing the capacitor body 10. Outer surfaces 32, 33 of the sidewall 30 are formed to incline inward from the bottom wall 22 side toward the tip, and the wall thickness of the sidewalls 32, 33 becomes thicker from the tip toward the bottom wall 22 side.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a surface mount capacitor and a seat plate used therefor.

  The seat plate used in the surface mount type capacitor described in Patent Document 1 extends vertically from the bottom wall on which the cylindrical capacitor body is disposed and from the bottom wall, and is disposed so as to surround the outer peripheral surface of the capacitor body And four side walls. A contact portion in contact with the outer peripheral surface of the capacitor body is formed on the inner side surface of each side wall. Two contact portions are formed on each side wall and extend from the bottom wall parallel to the axial direction of the capacitor body. By mounting the capacitor body on the seat plate, a surface mount type (chip type) capacitor is configured.

  Further, in addition to the invention described in Patent Document 1, as a seat plate used for a surface mount type capacitor, those shown in FIGS. 7 and 8 are known. The seat plate 101, like the one described in Patent Document 1, extends vertically from the bottom wall 102 on which a cylindrical capacitor body (not shown) is disposed, and the side wall having a constant thickness. And four side walls 103 arranged to surround the outer peripheral surface of the capacitor body. The four side walls 103 have an arc-shaped inner peripheral surface along the outer peripheral surface of the capacitor main body, and the inner peripheral surface is in surface contact with the outer peripheral surface of the capacitor main body. However, when a surface mount type capacitor is actually mounted on a substrate and vibration is applied, the vibration becomes larger toward the upper side of the capacitor main body. Therefore, as shown in FIG. And the tip of the side wall 103. On the other hand, in the state where the root side (bottom wall 102 side) of the side wall 103 functions as a fulcrum and the capacitor body is inserted between the plurality of side walls 103, the holding force F11 of the side wall 103 and the tip of the side wall 103 in contact with the capacitor body are The force relationship with the force F12 that opens outward is important for suppressing the vibration of the capacitor body.

JP, 2016-76600, A

  However, in the seat plate 101 of FIG. 8, since the thickness of the side wall 103 is constant, the strength on the root side which is the fulcrum of the side wall 103 can not be sufficiently secured. The force to suppress F12 is weakened. Further, since the seat plate 101 is made of resin, elasticity can be expected to some extent when inserted into the side wall 103 of the capacitor body, but with the passage of time the elasticity of the resin itself deteriorates and the side wall 103 holds the capacitor body become unable. From the above, in the conventional seat plate, there is a problem that the side wall can not hold the capacitor body stably.

  Therefore, the present invention has been made to solve the above problems, and a seat plate capable of stably holding a capacitor main body by a side wall disposed on the outer peripheral surface thereof and a surface mount type provided with the seat plate It is to provide a capacitor.

  A surface mount capacitor according to the present invention comprises a capacitor body for housing a capacitor element, and a seat plate for holding the capacitor body, wherein the seat plate is a bottom wall on which the capacitor body is disposed, and the bottom wall And a plurality of side walls extending in the axial direction of the capacitor body and pressing the capacitor body, the outer side surface of the side wall is formed to be inclined inward from the bottom wall side toward the tip, The wall thickness increases from the tip to the bottom wall side.

  In the present invention, the outer side surface of the side wall is formed to be inclined inward from the bottom wall side toward the tip, and the thickness of the side wall is increased from the tip to the bottom wall side. Thereby, the strength on the root side (bottom wall side) of the side wall functioning as a fulcrum can be increased, and the holding power of the capacitor body by the side wall is improved. Also, by forming the outer side surface of the side wall to be inclined inwardly toward the end from the bottom wall side, the force at which the end of the side wall opens outward is suppressed, and the holding power of the capacitor body at the end of the side wall is strengthened. . Furthermore, by making the thickness on the bottom wall side thicker than the tip of the side wall, warpage and distortion of the side wall can be suppressed, the center of gravity of the side wall can be lowered, and the vibration resistance can be improved. From the above, the side walls of the seat plate disposed on the outer peripheral surface of the capacitor body can hold the capacitor body stably.

  Preferably, in the surface mount type capacitor according to the present invention, the inner side surface of the side wall extends in parallel with the axial direction of the capacitor body.

  In the present invention, the inner surface of the side wall extends parallel to the axial direction of the capacitor body. Thus, the capacitor body can be held by the entire inner side surface of the side wall.

  In the surface mount capacitor according to the present invention, preferably, the bottom wall is a rectangular plate, and the side walls are formed at corners of the bottom wall, and the inclination angles of the outer surfaces of the opposing side walls are different from each other.

  In the present invention, the inclination angles of the outer side surfaces of the opposing side walls are different from each other. Thereby, the distance from the central axis of the outer surface upper edge of the plurality of side walls can be made the same.

  The seat plate according to the present invention is a seat plate for holding a capacitor main body for housing a capacitor element, and extends from the bottom wall on which the capacitor main body is disposed and the axial direction of the capacitor main body from the bottom wall And a plurality of side walls for pressing the main body, the plurality of side walls being elastically deformable in a direction coming in contact with the central axis of the bottom wall, the outer surface of the side wall being from the bottom wall side to the tip The sidewall is formed to be inclined inward, and the thickness of the side wall is increased from the tip to the bottom wall side.

  In the present invention, the outer side surface of the side wall is formed to be inclined inward from the bottom wall side toward the tip, and the thickness of the side wall is increased from the tip to the bottom wall side. Thereby, the strength on the root side (bottom wall side) of the side wall functioning as a fulcrum can be increased, and the holding power of the capacitor body by the side wall is improved. Also, by forming the outer side surface of the side wall to be inclined inwardly toward the end from the bottom wall side, the force at which the end of the side wall opens outward is suppressed, and the holding power of the capacitor body at the end of the side wall is strengthened. . Furthermore, by making the thickness on the bottom wall side thicker than the tip of the side wall, warpage and distortion of the side wall can be suppressed, the center of gravity of the side wall can be lowered, and the vibration resistance can be improved. From the above, the side walls of the seat plate disposed on the outer peripheral surface of the capacitor body can hold the capacitor body stably.

  In the surface mount capacitor and the seat plate of the present invention, the outer side surface of the side wall is formed to be inclined inward from the bottom wall side toward the tip, and the thickness of the side wall becomes thicker from the tip to the bottom wall side ing. As a result, the thickness on the bottom wall side with respect to the tip of the side wall is increased, the strength on the root side (bottom wall side) of the side wall functioning as a fulcrum can be increased, and the retention strength of the capacitor body by the side wall is improved. Also, by forming the outer side surface of the side wall to be inclined inwardly toward the end from the bottom wall side, the force at which the end of the side wall opens outward is suppressed, and the holding power of the capacitor body at the end of the side wall is strengthened. . Furthermore, by making the thickness on the bottom wall side thicker than the tip of the side wall, warpage and distortion of the side wall can be suppressed, the center of gravity of the side wall can be lowered, and the vibration resistance can be improved. From the above, the side walls of the seat plate disposed on the outer peripheral surface of the capacitor body can hold the capacitor body stably.

It is a top perspective view which shows the capacitor | condenser main body and seat plate which concern on embodiment of this invention. It is a lower perspective view which shows the capacitor | condenser main body and seat plate which concern on embodiment of this invention. It is the upper perspective view which looked at the seat plate of FIG. 1 from a different direction. It is the downward perspective view which looked at the seat plate of FIG. 1 from a different direction. It is a top view which shows the seat plate of FIG. FIG. 6 is a cross-sectional view taken along line VI-VI of FIG. 5; It is a top perspective view which shows the conventional seat plate. It is sectional drawing of the seat plate of FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the attached drawings.

  As shown in FIGS. 1 and 2, the surface mount type capacitor 1 according to the present embodiment has a capacitor body 10 having a substantially cylindrical shape and a seat plate 20 for holding the capacitor body 10. The capacitor main body 10 includes a wound capacitor element (not shown), a bottomed cylindrical container 11 for housing the capacitor element therein, and a sealing material 12 for sealing the open end of the container 11. ing. Further, along the center axis C of the capacitor body 10, the seat plate 20 is formed with the two insertion holes 21 and the bottom wall 22 with which the bottom surface of the capacitor body 10 abuts and the outer peripheral surface of the capacitor body 10. It comprises four side walls 30 which extend vertically.

  In the capacitor body 10 having a cylindrical shape, the capacitor element is housed inside the substantially cylindrical housing container 11, and the plugging material 12 is inserted into the open end portion thereof, and then the groove portion 13 is formed near the lower portion of the outer peripheral side surface The container 11 is sealed by the sealing material 12 by caulking in the same manner. The capacitor body 10 is provided with two lead terminals 14 so as to penetrate the sealing material 12. Each lead terminal 14 is connected, for example, by welding to a tab (not shown) derived from the capacitor element.

  In addition, as a capacitor element, a separator is interposed between an anode foil and a cathode foil made of a valve metal such as aluminum, and formed by winding and impregnated with an electrolytic solution, and solid conductivity as an electrolyte. It is possible to use a solid electrolytic capacitor element or the like in which a polymer is formed between an anode foil and a cathode foil made of a valve metal such as aluminum.

  The seat plate 20 is made of an electrically insulating material and manufactured by injection molding. In the present embodiment, the material of the seat plate 20 is a resin. As described above, the seat plate 20 is composed of the bottom wall 22 on which the capacitor body 10 is disposed and the four side walls 30 (see FIGS. 3 and 4).

  The bottom wall 22 has a predetermined thickness and, as shown in FIG. 5, has a substantially square shape as viewed from above. On the side of the bottom wall 22 facing the sealing material 12 of the capacitor body 10, a recess 24 is formed in which the contact surface 22a with the capacitor body 10 is recessed about the central axis C. In the state where the condenser body 10 is held by the seat plate 20, the central axis C of the capacitor body 10 and the central axis C of the bottom wall 22 (recess 24) coincide with each other.

  The two insertion holes 21 formed on the bottom surface 25 of the recess 24 penetrate from the contact surface 22a to the back surface 22b. The two insertion holes 21 are formed in the vicinity of the central portion of the bottom wall 22 as viewed from above. The two lead terminals 14 provided in the capacitor main body 10 are inserted into the two insertion holes 21. Two grooves 29 having a depth substantially equal to the thickness of the lead terminal 14 are formed on the back surface 22b of the bottom wall 22 so as to be able to accommodate the lead terminal 14 from the two insertion holes 21 to the outer end. ing. The two grooves 29 extend radially outward from the central axis C.

  As described above, the two lead terminals 14 drawn out from the sealing material 12 of the capacitor main body 10 are inserted into the two insertion holes 21 and bent outward along the grooves 29. Thus, the bottom wall 22 is sandwiched between the capacitor body 10 and the bent lead terminal 14 so as to be integrated with the capacitor body 10. At this time, a portion of the two lead terminals 14 exposed to the back surface 22 b of the bottom wall 22 is accommodated in the groove 29 and does not protrude. Therefore, the surface mount capacitor 1 can stand on its own.

  Returning to FIG. 5, the side walls 30 (30 a, 30 b) are respectively formed at the corners of the bottom wall 22. The four side walls 30 are arranged such that the distances from the central axis C of the capacitor body 10 are equal to one another. Further, four side walls 30 are arranged at equal angular intervals in the circumferential direction with respect to the central axis C. The four side walls 30 include two side walls 30 a formed at the corners of the flat bottom wall 22 and two side walls 30 b formed at the corners of the rounded bottom wall 22.

  The two side walls 30a have the same shape as each other. Each of the two side walls 30a has an inner surface 31 having an arc shape in top view, and an outer surface 32 including a surface curved and extended around the central axis C. The inner side surface 31 is formed as a first circular arc surface that is centered on the central axis C of the capacitor body 10 and is a part of a first circumference larger in radius than the capacitor body 10. As shown in FIG. 6, the inner side surface 31 extends from the bottom wall 22 parallel to the central axis C toward the capacitor body 10 (upper side). In a state in which the capacitor main body 10 is held by the seat plate 20, the entire inner side surface 31 of each side wall 30a presses the outer peripheral surface of the capacitor main body 10.

  When the outer side surface 32 is viewed from above, the lower edge 32 a of the outer side surface 32 is formed in a straight line by the corners of the bottom wall 22 being planarized. The upper edge 32 b of the outer side surface 32 is formed as a part of a second circumference which is concentric with the first circumference and whose radius is larger than the first circumference. The outer surface 32 is inclined from its lower edge 32a to its upper edge 32b. When viewed from the side, the outer side surface 32 extends radially inward of the bottom wall 22 from the bottom wall 22 toward the capacitor body 10 (above) at an angle θ1. In other words, the outer side surface 32 is formed as an inclined surface which is inclined inward from the root (lower edge 32a) of the side wall 30a to the tip (upper edge 32b), whereby the thickness of the side wall 30a is from the tip to the root It is getting thicker.

  The two side walls 30b have the same shape as each other. Each of the two side walls 30 b has an inner side surface 31 having an arc shape in top view, and an outer side surface 33 curved and extended around the central axis C. Since the inner side surface 31 has the same shape as the inner side surface 31 of the side wall 30a, the same reference numerals are given and the description is omitted.

  When the outer side surface 33 is viewed from above, the lower edge 33a of the outer side surface 33 is formed in a curved shape by round chamfering of the corner of the bottom wall 22. The distance L2 between the central point B of the lower edge 33a and the central axis C is longer than the distance L1 between the central point A of the lower edge 32a of the outer surface 32 and the central axis C. The upper edge 33 b of the outer side surface 33 is formed as a part of a second circumference which is concentric with the first circumference and whose radius is larger than the first circumference, similarly to the upper edge 32 b of the outer side surface 32. The outer surface 33 is inclined from its lower edge 33a to its upper edge 33b. When viewed from the side, the outer side surface 33 extends radially inward of the bottom wall 22 from the bottom wall 22 toward the capacitor body 10 (above) at an angle θ 2. In other words, the outer side surface 33 is formed as an inclined surface which inclines inward from the root (lower edge 33a) of the side wall 30b to the tip (upper edge 33b), whereby the thickness of the side wall 30b is from the tip to the bottom wall 22 side It is getting thicker towards The inclination angles of the outer side surface 32 of the side wall 30a and the outer side surface 33 of the side wall 30b opposite to the side wall 30a are different from each other. That is, the inclination angle θ2 is larger than the inclination angle θ1. Further, since the distance L2 from the central axis C is longer than L1, the thickness of the side wall 30b is formed thicker than the thickness of the side wall 30a.

  In order to hold the capacitor body 10 on the seat plate 20, the capacitor body 10 is further pushed downward from the state shown in FIG. At this time, the side wall 30 made of resin is elastically deformed radially outward along the outer peripheral surface of the capacitor body 10 by being pushed radially outward by the capacitor body 10.

  In a state where the capacitor main body 10 is held by the seat plate 20, the capacitor main body 10 is pressed by the inner side surfaces 31 of the four side walls 30 in the direction toward the central axis C thereof. Thus, the capacitor body 10 is firmly held by the seat plate 20.

  Further, since the side wall 30 made of resin can be elastically deformed in the direction of coming into and coming out of contact with the capacitor body 10, even if the outer shape of the capacitor body 10 and / or the side wall 30 is distorted etc. Even in the case of deformation, the side wall 30 elastically deforms in either the radial or the radial direction following the deformation. Therefore, in the present embodiment, it is ensured that the inner side surface 31 of each side wall 30 contacts the outer peripheral surface of the capacitor body 10.

[Features of surface mount capacitor 1 of this embodiment]
The surface mount capacitor 1 of the present embodiment has the following features.

  In the surface mount type capacitor 1 and the seat plate 20 of the present embodiment, the outer side surfaces 32, 33 of the side wall 30 are formed to be inclined inward from the root side (bottom wall 22 side) of the side wall 30 toward the tip, The thickness of 30 becomes thicker from the tip to the bottom wall 22 side. As a result, the strength of the root side (bottom wall 22 side) serving as the fulcrum of the side wall 30 for pressing the capacitor body 10 can be increased, and the holding power of the capacitor body 10 by the side wall 30 can be improved. Further, by forming the outer side surfaces 32 and 33 of the side wall 30 inward from the bottom wall 22 side toward the end toward the end, a force at which the end of the side wall 30 opens outward is suppressed. The ten holding power is strengthened. Furthermore, by making the thickness on the side of the bottom wall 22 thicker than the tip of the side wall 30, warpage and distortion of the side wall 30 can be suppressed, the center of gravity of the side wall 30 can be lowered, and vibration resistance can be improved. From the above, the side wall 30 of the seat plate 20 can hold the capacitor body 10 stably.

  In the surface mount type capacitor 1 of the present embodiment, the inner side surface 31 of the side wall 30 extends in parallel with the axial direction of the capacitor body 10. Thereby, the capacitor main body 10 can be held by the entire inner side surface 31 of the side wall 30.

  In the surface mount type capacitor 1 of this embodiment, the inclination angles of the inclined surfaces (outside surfaces 32, 33) of the opposing side walls 30a, 30b are different from each other. Thereby, the distance from the central axis of the outer surface upper edge of the plurality of side walls 30 can be made the same.

  As mentioned above, although embodiment of this invention was described based on drawing, it should be thought that a specific structure is not limited to these embodiment. The scope of the present invention is indicated not only by the description of the embodiments described above but also by the claims, and further includes all modifications within the meaning and scope equivalent to the claims.

  In the embodiment, the position in the height direction (width direction) of the lower edges 32a and 33a of the side walls 30a and 30b is the contact surface 22a of the bottom wall 22. However, the present invention is not limited thereto. It may be a high position or a low position. The position in the height direction of the lower edges 32a and 33a can be changed as long as the effects of the present invention are achieved on the root side (bottom wall 22 side) of the side walls 30a and 30b.

  In the embodiment, the inner side surface 31 of the side wall 30 extends in parallel with the central axis C of the capacitor body 10. However, as long as the inner side surface 31 presses and holds the outer peripheral surface of the capacitor main body 10, it is not limited to this.

  In the embodiment, the inclination angle with respect to the bottom wall 22 of the outer side surface 32 of the side wall 30a and the outer side surface 33 of the side wall 30b opposite to the side wall 30a is different. However, the present invention is not limited thereto, and the same effect can be obtained even if the inclination angles of the outer side surface 32 and the outer side surface 33 are the same.

  Although four side walls 30 are provided in the above embodiment, the number of side walls 30 is not particularly limited.

Reference Signs List 1 surface mount type capacitor 10 capacitor body 20 seat plate 22 bottom wall 30 (30a, 30b) side wall 31 inner side surface 32 outer side surface 33 outer side surface C central axis

Claims (4)

A capacitor body for housing a capacitor element, and a seat plate for holding the capacitor body,
The seat plate has a bottom wall on which the capacitor body is disposed, and a plurality of side walls extending from the bottom wall in the axial direction of the capacitor body and pressing the capacitor body.
The outer side surface of the side wall is formed to be inclined inward from the bottom wall side toward the tip,
A surface mount type capacitor characterized in that the thickness of the side wall increases from the tip toward the bottom wall side.   The surface mount type capacitor according to claim 1, wherein the inner surface of the side wall extends in parallel with the axial direction of the capacitor body. The bottom wall is a rectangular plate, and the side wall is formed at a corner of the bottom wall,
The surface mount type capacitor according to claim 1 or 2, wherein the inclination angles of the outer surfaces of the opposite side walls are different from each other. A seat plate for holding a capacitor body for housing a capacitor element, wherein
A bottom wall on which the capacitor body is disposed, and a plurality of side walls extending from the bottom wall in the axial direction of the capacitor body and pressing the capacitor body,
The plurality of side walls are elastically deformable in a direction away from and in contact with the central axis of the bottom wall,
The outer side surface of the side wall is formed to be inclined inward from the bottom wall side toward the tip,
A seat plate characterized in that a thickness of the side wall is increased from a tip toward a bottom wall side.

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